Wednesday, November 26, 2008

Prospectus

EXPLORING AMERICAN INDIAN STUDENTS’ ATTITUDES, PERCEPTIONS, AND MISCONCEPTIONS OF SCIENTISTS AND THE NATURE OF SCIENCE




ABSTRACT
The purpose of this study is to describe and analyze the attitudes, perceptions, and misconceptions that middle and high school American Indian students possess with regard to scientists and the nature of science. American Indians are the least represented group in Science, Technology, Engineering, and Mathematics (STEM) majors and careers, both proportionally and in total numbers. The results of this study may be used as a baseline or “snap shot” to gauge the effectiveness of the current and future variety of initiatives addressing the under-representation of American Indians and other minorities in science, mathematics, engineering, and health care. VOSTS, VNOS, and DAST-C instruments will be used to characterize the attitudes and perceptions of approximately 100 students in one or more tribal schools in Oklahoma. Data is to be gathered in winter and spring 2009, with analysis to follow.



CHAPTER 1: INTRODUCTION
The director of the education department of a large American Indian tribe in northeastern Oklahoma recently related an informal and unpublished study carried out by a former superintendent of Bell School in Adair County in Oklahoma. The school is small, rural, comprises prekindergarten through eighth-grade levels, and is a dependent district with a student population that is almost 100% American Indian. Over several years the superintendent surveyed fourth graders as to what they wanted to be when they grew up. Their answers ranged across the spectrum of vocations, from teachers and professional athletes to firefighters and cowboys. When the students were asked the same question 4 years later as eighth-graders, their responses were mostly limited to one of two; chicken pullers at the nearby Tyson Foods facility or line workers at the Mrs. Smith’s pie and cake factory in Stilwell.
This revelation was startling and disconcerting, and coupled with the fact that American Indian student drop-out rates and tendencies to not attend or complete college (especially in Science, Technology, Engineering, and Mathematics [STEM] majors) are high (Demmert, 2001), propelled this investigation of the role of science education in addressing this dilemma. In fact, American Indian students are the least represented group in STEM majors and careers, both in sheer numbers as well as proportionally (Demmert).
Strong science education for students before entering higher education is a critical foundation of America’s technological and intellectual strength, which arises from its talented workforce trained in STEM majors (Babco, 2003). According to Babco, for Science and Engineering (S&E) degrees in the year 2000, only 2,782 (0.7% of S&E degrees) of American Indians earned S&E bachelor’s degrees, 340 (0.4%) earned S&E master’s degrees, and 88 (0.3%) earned doctoral degrees. Moreover, most of these majors are concentrated in the social sciences and psychology, as opposed to the hard sciences encompassed under the STEM umbrella. In addition, Babco noted that American Indian STEM degree attainment has not kept pace with the growth of the American Indian population in the past 30 years.
My personal experience after attending the Summer Science Institute at Sam Noble Oklahoma Museum of Natural History at the University of Oklahoma in Norman 2 years ago was that my students (mostly American Indian) responded very well to inquiry-based science instruction in the form of learning cycles. Inquiry-based science instruction refers to science instruction that is focused on critical thinking and problem solving while emphasizing the need to evaluate teacher strategies to ensure that they align with the particular learning styles of particular students (Tomlinson, 2004). I witnessed greater student enthusiasm and achievement in science in my third through eighth grade classes, and many more moments of student comprehension, especially during the concept development and expansion/application phases of the learning cycle. This was especially true when we could relate a concept to something from the students’ real-world environment and interests, including sports, cars, or music, and organize the concept amongst their prior knowledge. This partially led to the school adopting the Carolina Biological Company’s Science and Technology for Children (STC) program, which I helped to implement as the school’s unofficial science coordinator. More science instruction, and specifically more inquiry-based science instruction followed, and the faculty had a degree of latitude to modify the kits to more of a true learning cycle teaching approach.
In fact, it was this anecdotal success and progress in my own classroom that prompted me to apply to the PhD program at the University of Oklahoma in Instructional Leadership and Academic Curriculum (ILAC) with an emphasis in Science Education. I wanted to learn more about this teaching approach, help communicate this information, develop programs, and train other teachers. Although existing research indicates that all students tend to learn better with an inquiry-based approach to science education (Lee, Greene, Odom, Schechter, & Slatta, 2004; Marzano, 2003), this study was prompted at least partially by the question of whether American Indian students are somehow uniquely suited for this teaching approach. This study takes into account many sources of research concerning science education, indigenous or Native science educational perspectives, perceptions and misconceptions of science and scientists, socioeconomic status, opportunities for informal learning, and cross-cultural evaluation instruments.
Several years ago, the Cherokee Nation (CN) government recognized the deficit in CN students undertaking STEM majors and careers, and took steps in initiating programs to address the problem (Lemont, 2001). Among these are the CN science fair, STEM camps, robotics workshops, scholarships, and an emphasis on science and mathematics in schools with large American Indian populations. There is growing emphasis nationwide on similar programs. Examples include the SOARS Program at the National Center for Atmospheric Research and the South Dakota Space Grant Consortium. Professional organizations such as the National Indian Education Association (NIEA) and the American Indian Science and Engineering Society (AISES) are currently initiating several STEM programs as well. Quantitative studies such as this one that attempt to describe how American Indian students feel about science, science instruction, and scientists are important components in addressing these deficits. The research will take place at Sequoyah Schools. According to the Cherokee Nation official web site, it is an Indian boarding school, and originated in 1871 when the Cherokee National Council passed an act setting up an orphan asylum to take care of the many orphans of the Civil War. In 1914 the Cherokee National Council authorized Chief Rogers to sell and convey the property of the Cherokee Orphan Training School, including 40 acres of land and all the buildings, to the United States Department of Interior for $5,000. In 1925 the name of the institution was changed to Sequoyah Orphan Training School in honor of Sequoyah, a Cherokee who developed the Cherokee syllabary. After being known as Sequoyah Vocational School for a time, it was renamed Sequoyah School. From a school with one building and 40 acres of land, it has grown into a modern institution covering more than 90 acres and a dozen major buildings situated on a beautiful campus five miles southwest of Tahlequah, Oklahoma. In November 1985 the Cherokee Nation resumed the operation of Sequoyah School from the Bureau of Indian Affairs. It is now operated through a grant and is regionally and state accredited for grades 7-12.

Problem Statement
The problem motivating this study is that American Indian attainment of STEM degrees in higher education is not keeping pace with the growth of the American Indian population (Babco, 2003). In addition, this problem is compounded by a lack of research on the perceptions, attitudes, and misconceptions of American Indian middle and high school students. Without understanding how American Indian middle and high schools students feel about science and science education, teachers cannot instruct these students to their optimal ability. Because America relies on a strong and highly educated technical workforce, the attainment of STEM degrees within the American Indian population is ultimately important to the progress of the American economy in general and American Indians in particular.

Research Question
My experiences in the field and a recognition of the problem of low rates of American Indian attainment of STEM degrees in higher education led to the development of the following central research question: What attitudes, perceptions, and misconceptions do American Indian middle and high school students possess with regard to scientists and the nature of science? Similar studies have been performed previously with other ethnic nationalities (Dogan & Abd-El-Khalick, 2008; Ebenezer & Zoller, 1993, Seiler, 2001); however, to the author’s knowledge no research has ever been done specifically on American Indian students’ perceptions of scientists and the nature of science. This research question will guide the study’s exploration of American Indian students’ perceptions of science, and with the aid of statistical analysis of student responses to selected components of three chosen survey instruments, will measure a wide range of the students’ beliefs, knowledge, and perceptions of science, scientists, and science education.
Research Approach
This study will attempt to answer the central research question using a quantitative comparative approach. Three survey instruments have been chosen for this study to measure American Indian students’ perceptions, attitudes, and misconceptions of scientists and the nature of science. The three survey instruments are (a) the Views on Science-Technology-Society (VOSTS) (Aikenhead & Ryan, 1992), (b) the Draw-A-Scientist Test (DAST-C) (Chambers, 1983), and (c) the Views of Nature of Science Questionnaire (VNOS) (Lederman, Abd-El-Khalick, Bell, & Schwartz, 2002). All three survey instruments have undergone extensive testing and have been deemed to be both valid and reliable research instruments for measuring student perceptions of science.
An anticipated group of approximately 100 American Indian middle and high school students will complete the surveys. The results of the seventh grade surveys will be compared with those of the twelfth grade surveys (as will all the grades/ages involved), and statistical analyses will be employed to determine if any significant patterns emerge between the datasets. An attempt at an overall characterization of the data will be made, and the results may be broken down by gender and other factors. The results will also be analyzed overall within the context of the existing research on inquiry-based education and the education and achievement levels of American Indian students to determine whether and in what meaningful ways student perceptions, attitudes, and misconceptions of science education might exist and compare to other populations. Ultimately this data may serve as a baseline for comparison as more STEM and inquiry-based science initiatives are implemented throughout Oklahoma and the rest of the country. The results may also yield clues as to help guide and define such programs in order to heighten their effectiveness concerning American Indian students in particular. It also may lead to more qualitative, quantitative, and mixed-method studies involving informal learning, knowledge of science content, and other related areas in science education for American Indian students.
Importance of the Study
This study is important to further research on the educational trends of American Indian students. There is a large gap in the literature with regard to this subject, particularly concerning the science education of American Indian students and its connections to achievement in higher education and STEM majors. The results of this study will be important to middle and high school educators, leaders of institutions of higher education, governmental policy makers, and leaders of the American Indian community because they will provide a foundation for tailoring science education to American Indian students. Further, such a foundation may provide the basis for improved science education for American Indian students, and, in turn, greater achievement levels in higher education, particularly in STEM majors. All resulting data and analysis will be shared with the Cherokee Nation through the Education Department and Sequoyah Schools.

CHAPTER 2: LITERATURE REVIEW
The former superintendent at my previous school in northeast Oklahoma believed for years that American Indian students tended to be active, right-brained learners who responded well to learning through tactile, kinesthetic, auditory, and visual experiences. He developed a “psychomotor” approach to learning for younger students that coupled activity with concepts, such as counting in both English and Cherokee while jumping rope. Partially because of this, his school was designated by the U. S. Department of Education as a National School of Excellence, and also received the James Madison Elementary School Award for Outstanding Curriculum in 1988 (Southwest Educational Development Laboratory, 1995).
I attempted to connect my own classroom experiences with other observations from the literature to link Native culture and learning styles to the utilization of learning cycles in the classroom, as in the “border crossings” of the literature (Aikenhead & Jegede, 1999). For instance, traditional American Indian viewpoints of the world and environment are mutualistic and holistic, emphasizing the interconnectedness of the universe and all its living and non-living components (Cajete, 1999). Furthermore, Cajete noted, “Presenting educational material from a holistic perspective is an essential and natural strategy for teaching Indian people” (p. 142).
This literature review provides a summation of existing research that is relevant to the topics of this study. Inquiry-based education and its utility in science education are discussed, followed by an overview of American Indian learning trends and styles. Next, there is an investigation of American Indians in higher education, as well as an exploration of American Indian trends in STEM education and degree attainment. The literature review concludes with a summary.
Inquiry-Based Education
There are a variety of viewpoints concerning what constitutes inquiry-based education. Lee et al. (2001) defined inquiry-based education as “learning in terms of the four student commitments-critical thinking, independent inquiry, responsibility for one’s own learning, and intellectual growth and maturity” (p. 63). Marzano (2003) believed that science education for middle and high school students is better when using inquiry-based techniques. The National Science Education Standards (NRC, NSES p. 23) defines and recommends scientific inquiry as "the diverse ways in which scientists study the natural world and propose explanations based on the evidence derived from their work. Scientific inquiry also refers to the activities through which students develop knowledge and understanding of scientific ideas, as well as an understanding of how scientists study the natural world." The Oklahoma Priority Academic Student Skills (PASS) are process-oriented and inquiry-based standards which provide the foundation for all elementary and secondary instruction in the state. Inquiry requires critical thinking skills and problem solving, and may contribute to the implementation of a program of instruction that ensures that “what a student learns, how he/she learns it, and how the student demonstrates what he/she has learned is a match for that student’s readiness level, interests, and preferred mode of learning” (Tomlinson, 2004, p. 188). The central purpose of American education, as stated in 1961 by the Educational Policies Commission (EPC), is for students to be able to think critically and utilize the rational powers. Furthermore, from their website, The National Science Teachers Association (NSTA) recommends that “all K–16 teachers embrace scientific inquiry and NSTA is committed to helping educators make it the centerpiece of the science classroom. The use of scientific inquiry will help ensure that students develop a deep understanding of science and scientific inquiry”.
Existing research indicates a growing belief in the superiority of inquiry-based techniques over more traditional, memorization-based learning. Steinberg (2007) stated,
Too much of today’s science education focuses on making students memorize bits of information that will be outdated within a few years. There is too little emphasis on how to think like a scientist. And there is no substitute for hands-on (inquiry) research experience. (p. 13)
Marzano (2003) agreed that teachers need to “provide students with tasks and activities that are inherently engaging” (p. 149). Inquiry-based education targets the specific learning styles of students to provide engaging and educational activities that integrate with students’ unique educational perspectives.
Educators should be aware of the fact that students have different backgrounds and life circumstances, and that these differences can be profound from the circumstances of mainstream students with regard to minorities, such as American Indians. Differentiation is an important concept in inquiry-based pedagogy, and refers to the tailoring of teaching techniques to the educational needs of students. A program of differentiation is a systematic way of meeting the needs of all students (Tomlinson, 2004). The learning community is not only concerned with meeting needs of learners at different levels but also different learning styles. Willis and Mann (2000) stated differentiated instruction is intended “to deliver instruction in ways that meet the needs of auditory, visual, and kinesthetic learners. And they, (teachers), are trying to tap into students’ personal interests. In short, these teachers are differentiating instruction” (pp. 1-2).
Through the use of programs of differentiated instruction and inquiry-based instructional approaches, teachers can be better prepared to meet the needs of the learners in a diverse learning community. “Educators commonly see one of their major roles as helping students to acquire broader and deeper understandings of the physical and social world around them” (Kuhn, 2005), which describes inquiry instruction. Kuhn also stated that, “Becoming educated, then, means achieving the skills and values that confer an unlimited capacity and inclination to learn and to know” (p. 109), giving strength to the effectiveness and purpose of inquiry instruction and learning. In fact, subject areas other than science may be more effectively taught through inquiry. O’Brien (2006) stated,
Inquiry is given even more credibility by supporting the standards and being part of those published by The National Center for History in the Schools. The standards were published in 1994 and revised in 1996. The first five standards, deal with historical thinking and required students to develop inquiry skills such as the ability to engage in chronological thinking, to interpret primary source material, to pose historical questions within the appropriated context, and to construct historical narrative-all hallmarks of inquiry learning. (pp. 11-12)
Research by the above mentioned authors has confirmed that inquiry-based education is an effective mode of teaching science, particular to groups of students with learning techniques and perspectives of science that may differ from those of the mainstream, which are typically forwarded in science education in the United States though the Western modern tradition.
American Indian Learning
Although students tend to learn better using an inquiry-based teaching approach, it is important for research to determine if American Indian students are particularly suited for socially based, constructivist/transactional teaching and learning (Lee, 2004; Marzano, 2003). Traditionally, American Indian children learned about the world around them by actively exploring it on their own, as well as through the passing down of knowledge by oral story-telling and hands-on instruction (Cajete, 1999). Traditional Ecological Knowledge (TEK) has been recognized as a sub-culture within the larger culture of science itself, and its intersection with classic Western science can be used to promote American Indian learning instead of hindering it (Snively & Corsiglia, 2000). The Cherokee Nation’s Long Man Project is an example of Western modern science being taught concurrently with traditional Native science to enhance students’ interest and understanding.
Snively and Corsiglia (2000) forwarded a notion of indigenous science, which refers to “both the science knowledge of long-resident, usually oral culture peoples, as well as the science knowledge of all peoples who as participants in culture are affected by the worldview and relativist interests of their home communities” (p. 6). The term “Native science” is more of an American term, while “indigenous science” is its global and mostly synonymous counterpart. This concept is useful when thinking about American Indian learning. Although there is a growing body of literature surrounding TEK, a review of the research by Snively and Corsiglia suggested that Western modern science has been taught at the expense of indigenous science. The researchers also observed that the “universalist gatekeeper” of Western modern science “can be seen as increasingly problematic and even counter productive” (p. 6). Therefore, teaching of American Indian students that does not acknowledge their particular learning styles, culture, and language may be a detriment to their science education. Cajete (2000) defines Native science in a way that is reasonable to most American Indians, "Native science is a metaphor for a wide range of tribal processes of perceiving, thinking, acting, and 'coming to know' that have evolved through human experience with the natural world. Native science is born of a lived and storied participation with the natural landscape. To gain a sense of Native science one must participate with the natural world. To understand the foundations of Native science one must become open to the roles of sensation, perception, imagination, emotion, symbols, and spirit as well as that of concept, logic, and rational empiricism."
A complement to this point of view is that indigenous science knowledge, instead of being consumed by the standard account of Western modern science, is better off as a different kind of knowledge that can be valued for its own merits and can play a vital role in the science education of American Indian students (Cobern & Loving, 2001). One possible goal would be to work towards instituting and developing inquiry-based instructional programs, especially in science, in the educational departments of schools within American Indian tribal boundaries. Research has shown that inquiry-based professional development may enhance teachers’ understanding of Piagetian models of intelligence and increase their use of appropriate constructivist approaches in the classroom (Marek, Cowan, & Cavallo, 1994; Marek, Eubanks, & Gallaher, 1990).
Gerber, Marek, and Cavallo (2001) believed that encouraging more informal learning opportunities, including visits to museums and other field trips, chess, speech, and science fairs, is important for all students’ achievement. Likewise, emphasizing American Indian culture and language both at home and in school should be priorities for the teacher of such children (Matthew & Smith, 1994). Students need to actively construct their own knowledge with the teacher’s guidance, engage in varied activities both in and out of school, and maintain their Native identity (Gilliland, 1995). That is, they need to realize that they can “be Cherokee,” for instance, and yet also be successful in school and professionally in the larger world outside their usually rural home environments (Nelson-Barber & Estrin, 1995). Establishing an idea of how American Indian students currently feel about STEM classes and professions could be beneficial in knowing how to most effectively teach and encourage participation and success in these areas. There is a small but growing body of literature that supports the notion that incorporating and maintaining Native culture and language greatly enhances students’ overall academic performance and likelihood to seek and complete post-secondary work (Cajete, 2000; Deloria, Jr., 2000; & Gilliland, 1995).
American Indians and Higher Education
According to the National Center for Education Statistics (2002), there is a significant gap in the academic achievement levels of American Indian students. As of 1997, American Indian attrition rates in institutions of higher education range between 75% and 93% (Brown and Kurpius, 1997). According to Larimore and McClellan (2005), in secondary education, 40% of American Indian students drop out before attaining their high school diploma. Minorities overall suffer from lower rates of academic achievement than Caucasians, and American Indians have particularly high rates of student attrition.
Larimore and McClellan (2005) suggested using multiple theoretical lenses or perspectives in evaluating American Indian students and their learning experiences in order to enhance a small, but growing body of knowledge about effective teaching strategies for American Indians. Issues of financial means to higher education also present barriers to American Indian students, who are often at the bottom of the socio-economic ladder (Brown & Kurpius, 1997). Research has suggested that increases in the availability and accessibility of higher education opportunities for American Indians is critical for improving American Indian academic achievement and retention rates.
Pavel (1992) identified American Indians as among the groups least likely to enroll in a public 4-year institution, and the least likely to graduate from those institutions. In addition, Larimore and McClellan noted that the post-secondary retention rate may be as low as 15%. These researchers highlighted the need for research to focus on pre-higher education levels of American Indian academic achievement. It was found that levels of academic achievement were typically lower for American Indian students than their peers, and researchers have postulated that conflicts in learning and teaching styles may be partly responsible for this disparity of academic achievement (Brown & Kurpius, 1997). Clearly, these studies suggest a significant problem of American Indian education that needs to be addressed immediately.
American Indians and STEM Education
Babco (2003) stated that American Indian students must have a strong science education before entering higher education, as STEM knowledge is a pillar of America’s intellectual and economic dominance. As stated before, American Indians are earning degrees in Science and Engineering (S&E) at startling low rates; for the year 2000, only 2,782 (0.7% of S&E degrees) of American Indians earned S&E bachelor’s degrees, 340 (0.4%) earned S&E master’s degrees, and 88 (0.3%) earned doctoral degrees. In addition, the American Indians that are attaining degrees in S&E majors tend to graduate in the social sciences and psychology, as opposed to the hard sciences encompassed under the STEM umbrella. In addition, Babco noted that American Indian STEM degree attainment has not kept pace with the growth of the American Indian population in the past 30 years.
In a qualitative study of American Indian college student perceptions of higher education, Hoover and Jacobs (1992) observed that American Indian students reported on the significance of counseling and guidance in the high school in order to prepare them for the transition to higher education. On the other hand, students noted that academic resources and instruction was adequate in college (Hoover & Jacobs). This suggests that problems of low rates of attainment of STEM degrees by American Indian students may have more to do with preparation before entering college that with the resources available to American Indian students once they are enrolled in college.
However, Wright (1990) suggested that guidance and counseling for American Indian students in college is just as important as it is for American Indian students in high school. Wright reported that American Indian students desired counseling in college to help them develop their confidence and steer them into specializations and career fields. Last, May and Chubin noted that in America, the job sectors that are growing fastest are based in science, engineering, and technology, and in order for American Indian students to keep pace in the economy, they will need to attain more STEM degrees. May and Chubin highlighted the need for financial assistance, academic intervention programs, and pre-college preparation to increase undergraduate STEM education among American Indians. Researchers in the field of STEM education who have addressed an American Indian population have routinely found that additional strategies are necessary to improve STEM education both in high school and in college.
Summary
A review of the literature has suggested that American Indian students are suffering from low levels of academic achievement and graduation from high school and institutions of higher education. Furthermore, it was noted that within American Indian education, STEM majors are disproportionately low as compared to other minorities and Caucasians. Inquiry-based education has been forwarded as a theoretical perspective that seeks to align the teaching styles of instructors with the learning styles of students.
In particular, it was suggested that inquiry-based science education may serve American Indian students better than science education based exclusively in a Western modern perspective. Because American Indians often come from life circumstances that are significantly different from those of most students in mainstream education, particular interventions, such as inquiry-based activities, may be required to ensure that American Indian students are learning science education at a rate that is comparable to their peers.

CHAPTER 3: RESEARCH METHODS
The purpose of this study is to describe and analyze the attitudes, perceptions, and misconceptions that middle and high school American Indian students possess with regard to scientists and the nature of science. In order to gauge the effectiveness of any type of STEM initiative over time, one would need a baseline of data that would indicate where students in the affected schools stood prior to implementation of more inquiry and informal learning. To measure the attitudes, perceptions, and misconceptions of middle and high school American Indian students components of three survey instruments will be used (a) the Views on Science-Technology-Society (VOSTS), (b) the Draw-A-Scientist Test (DAST-C), and (c) the Views of Nature of Science Questionnaire (VNOS). An anticipated group of approximately 100 American Indian middle and high school students will complete the surveys. It is expected that more of the older students will have experienced some of the STEM initiatives currently underway, and data will be compared by grade or age of students. To compare the attitudes, perceptions, and misconceptions of the students Pearson’s correlation analysis and an independent samples t-test will be used. There will also be an attempt to characterize overall the students’ attitudes about science and scientists, and compare responses by gender. The remainder of this chapter presents the research design that will be used, the population, sampling plan, sample size, instrumentation, data collection and then finally the methods of data analysis.
Research Design
This study will attempt to answer the central research question using a quantitative comparative approach. The research design will be a quantitative comparative design because it will provide the researcher with the ability to compare a group of participants with one another in order to determine if there will be difference in their responses on the VOSTS, VNOS, and DAST-C instruments (Cozby, 2001). The comparison that will be made in this study will be between the seventh grade survey results through the twelfth grade survey results to see if any significant patterns emerge between the datasets. There also is an attempt at characterizing as a whole the American Indian students’ attitudes toward science and scientists, and examining gender responses as well.
The students will be given selected components of each of the three instruments to complete. Hopefully in the future, after the implementation of more STEM and inquiry-based science programs, a similar group of students will be given each of the three instruments again and statistical analyses will be employed to determine if any significant patterns emerge between the datasets. Currently, to compare the middle school and high school scores with one another and males with females, an independent samples t-test will be used. This is because the purpose of the independent samples t-test is to determine whether there is a significant difference in measurements taken from two or more independent groups of students (Moore & McCabe, 2006). The results of all three instruments will also be analyzed and discussed in this study to attempt to gain some context of the current attitudes, misconceptions, and perceptions of American Indian students toward scientists and the nature of science.
Population
The target population for this study will be middle and high school American Indian students. More precisely, the target population will be American Indian students who are enrolled in science courses in the participating middle and high schools. Overall, it is expected that a sample of 100 students will complete the surveys. A non-probability sampling plan will be used for this study. This will be based on a purposeful sampling plan (Urdan, 2005). This is because the purpose of this study will be to sample only American Indian students, such that their attitudes, perceptions, and misconceptions can be measured.
For studies a power analysis and sample size estimator is conducted in order to make sure that the sample size that is collected for the study is able to make valid inferences towards the target population. Therefore, based on this information there are three items that contribute to calculating the required sample size for the study.
1. The first item that is important is the power of the study. The power refers to the probability of correctly rejecting a false null hypothesis (Keuhl, 2000).
2. The second item that is used to calculate the sample size of the study is the desired effect size the researcher is looking to obtain. The effect size is defined as being the strength of the relationship between the predictor and outcome variables (Cohen, 1988).
3. The third and final item is the level of significance. This is used to determine the level at which the null hypothesis is to be rejected. The level of significance is defined by alpha (α) and is usually set equal to 5%.
Assuming that an effect size of d = .60 will be used with a level of significance of 5%, and a power of 80% the minimum sample size that would be required for this study would be equal to 90. This calculation is also based on using an independent sample t-test. The sample size and power calculation for this study was produced in G*Power.
Instrumentation
For this proposed study there will possibly be three instruments used to collect data. These include: (a) the Views on Science-Technology-Society (VOSTS) (Aikenhead & Ryan, 1992), (b) the Draw-A-Scientist Test (DAST-C) (Chambers, 1983), and (c) the Views of Nature of Science Questionnaire (VNOS) (Lederman et al., 2002) in a quantitative paradigm. By assigning numerical or categorical values to the responses provided on the VOSTS, VNOS, and DAST-C instruments, it will be possible to assess the relationships and differences using quantitative methods (i.e., by comparing the different numerical responses with one another using several statistical techniques). The validity and reliability of these instruments have been established in the cited literature. Correlation and comparison among the selected instruments should facilitate the accuracy of conclusions drawn from them. The DAST-C (Appendix A) is easy to administer and will include a brief written response; it also may correlate to the other measures used. The DAST-C will be carried out in two parts. In the first stage each student will be given a piece of paper with the following instructions: “Draw a picture of a scientist at work”. Below the space for drawing, students will be asked to explain what the scientist is doing. They will also be asked how, when, and where they learn science. The VOSTS survey (Appendix B) is a tool that can help describe how students view the social nature of science and how science is conducted. For purposes of this study, the same fourteen items were chosen as by Dogan and Abd-El-Khalik in their 2008 study. The NOS aspects targeted by these 14 items include: the theory-driven nature of scientific observations; tentative nature of scientific knowledge; relationship between scientific constructs (models and classification schemes) and reality; the epistemological status of different types of scientific knowledge (hypotheses, theories, and laws) and their coherence across various scientific disciplines; nature of, and relationship between, scientific theories and laws; myth of a universal and/or stepwise ‘‘Scientific Method’’; the nonlinearity of scientific investigations; and the role of probabilistic reasoning in the development of scientific knowledge. These aspects of NOS, it should be noted, have been emphasized in national science education reform documents and are considered accessible by pre-college students according to Dogan and Abd-El-Khalik. Each VOSTS response was categorized as representing a ‘‘naive’’ position (N), an ‘‘informed’’ position (I), or a position that ‘‘has merit’’ (M). Overall, as per the National Institute for Science Education (n.d.), the more than one hundred questions on the original VOSTS instrument asks students about:
1. What science and technology are.
2. How society influences science and technology.
3. How science and technology influences society.
4. How science as taught in school influences society.
5. What characterizes scientists.
6. How scientific knowledge comes about.
7. The nature of scientific knowledge
The VNOS (Appendix C) is a conceptual diagnostic test and has three versions, all of which are open-ended. The most frequently used versions are the VNOS–B (7 items) and the VNOS–C (10 items). VNOS-B was chosen for this study, and the results are to be coded and quantified. Each instrument aims to elucidate students' views about several aspects of "nature of science" (NOS). These NOS aspects, according to the National Institute for Science Education (n.d.), include the:
1. Empirical NOS: Science is based, at least partially, on observations of the natural world.
2. Tentative NOS: Scientific knowledge is subject to change and never absolute or certain.
3. Inferential NOS: The crucial distinction between scientific claims (e.g., inferences) and evidence on which such claims are based (e.g., observations).
4. Creative NOS: The generation of scientific knowledge involves human imagination and creativity.
5. Theory-laden NOS: Scientific knowledge and investigation are influenced by scientists’ theoretical and disciplinary commitments, beliefs, prior knowledge, training, experiences, and expectations.
6. Social and cultural NOS: Science as a human enterprise is practiced within, affects, and is affected by, a lager social and cultural milieu.
7. Myth of the “Scientific Method”: The lack of a universal step-wise method that guarantees the generation of valid knowledge.
8. Nature of, and distinction between scientific theories and laws (e.g., lack of a hierarchical relationship between theories and laws).
The development and/or utilization of one or more instruments that consider cultural factors in these types of evaluations, as well as knowledge of scientific content, was also considered. Another possibility was working in conjunction with the Sam Noble Oklahoma Museum of Natural History’s education department and staging interventions in the after-school programs of selected districts involving informal learning opportunities. These interventions may consist of commercial curricula and could be evaluated with a pre- and post-test methodology in order to gauge their effectiveness in terms of student interest in science, scientific reasoning ability, and misconceptions and/or perceptions of science and scientists. This method may be particularly effective if actual scientists are participants and mentors in the programs.
Data Collection
Data will be collected in less than a week during winter and spring 2009, with analysis to follow. Once the study period is complete, the raw data from the three instruments will be imported into a computer spreadsheet for future analyses. Each participant in the study will receive a unique identification number. This identification number will be used to identify which responses correspond to the participants in the study, while maintaining confidentiality. The data will be saved on a separate flash drive and stored in a locked filing cabinet. Similarly, hard copies will also be locked in the filing cabinet. By doing this the confidentiality of each participant will be maintained so that no personal information will be accessible. The data is then kept on file for a period of 3 years where it will then be destroyed and deleted from the hard drive. There are absolutely no risks, discomfort, or inconvenience of any type for the study’s participants, and benefits include helping to understand and improve science education for American Indian students.
Data Analysis
Assessing the desired criteria would involve a population of approximately 100 middle and high school American Indian students drawn from throughout the country and centered at Sequoyah Schools in Tahlequah, Oklahoma. This sample size is based on the potential use of an independent samples t-test to analyze the grade/age and gender comparisons and to adequately characterize the students’ attitudes toward science. Sequoyah Middle and High Schools are near Tahlequah, Oklahoma, administered by the Cherokee Nation, and have agreed to participate and provide students for this study. The main goal is to attempt a characterization of a sample of American Indian students’ attitudes towards science and scientists. This may form a background and framework against which further and longer-term qualitative and quantitative studies may be carried out.
The independent samples t-test is used to determine whether there is a statistically significant difference between the two independent groups with respect to an average value for some dependent variable. By using the independent samples t-test the researcher will be able to determine whether students of different ages/grade levels and genders scored significantly higher than other students with respect to the average value of the VOSTS, DAST-C and the VNOS. If there is a significant positive test statistic then this would indicate that one group of students scored significantly higher than the other group of students, while if there was a significant negative statistic then this would indicate that one group of students scored significantly lower than the other group of students. This will be done for all three instruments, so that the researcher will be able to characterize the tested populations and determine whether the implementation of the inquiry-based programs and STEM initiatives resulted in a change in the American Indian students’ attitudes, perceptions, and misconceptions towards science and science education. Pearson’s correlation will allow the identification of any relationships between variables as well.
Summary
Chapter 3 discussed the research methods that will be employed in the proposed study, which was that of a comparative research design. Also included in Chapter 3 was information on the data collection process as well as proposed statistical analyses, which include an independent samples t-test. Also presented in this chapter were the research design, and the population and sample size. The following chapter then presents the results for this study.

REFERENCES
Aikenhead, G. S., & Jegede, O. J. (1999). Cross-cultural science education: a cognitive explanation of a cultural phenomenon. Journal of Research in Science Teaching, 36(3), 269-287.

Aikenhead, G., & Ryan, A. (1992). The development of a new instrument: 'Views on Science-Technology-Society' (VOSTS). Science Education, 76, 477-492.

Babco, E. L. (2003). Trends in African American and Native American participation in STEM higher education. Commission on Professionals in Science and Technology. Retrieved November 10, 2008, from http://www.cpst.org/STEM.pdf

Brown, L. L., & Kurpius, S. E. (1997). Psychosocial factors influencing academic persistence of American Indian College Students. Journal of College Student Development, 389(1), 3-12.

Cajete, G. A. (1999). Igniting the sparkle: an indigenous science education model (1st ed.). Asheville NC: Kivaki Press Inc.

Cajete, G. A. (2000). Native science: natural laws of interdependence (1st ed.). Asheville NC: Kivaki Press Inc.

Center for Science, Engineering, and Mathematics Education (1996). National Science Education Standards. Washington DC. National Academy Press.

Chambers, D. W. (1983). Stereotypic images of the scientist: the draw-a-scientist test
Science Education, 67(2), 255-265.

Cobern, W. J., & Loving, C. C. (2001). Defining "science" in a multicultural world: implications for science education. Science Education, 85(1), 50-67.

Cohen, J. (1988). Statistical power analysis for the behavioral sciences. Hillsdale, NJ: Erlbaum.
Cozby, P.C. (2001). Methods in behavioral research. New York, NY: McGraw Hill.
Deloria, Jr., V. (1999). Spirit and Reason: The Vine Deloria, Jr., Reader, Golden, Colorado: Fulcrum Publishing.

Demmert, W. G. (2001). Improving Academic Performance among Native American Students: A Review of the Research Literature. Charleston, WV: ERIC Clearinghouse on Rural Education and Small Schools.

Dogan, D., & Abd-El-Khalick, F. (2008). Turkish grade 10 students’ and science teachers’ conceptions of nature of science: A national study. Journal of Research in Science Teaching, 45(10), 1083-1112.

Ebenezer J. V., & Zoller, U. (1993). Grade 10 Students' perceptions of and attitudes toward science teaching and school science. Journal of Research in Science Teaching, 30(2).

Educational Policies Commission (1961). The Central Purpose of American Education. Washington, DC. National Education Association Press.

Gerber, B. L., Cavallo, A. M. L., & Marek, E. A. (2001). Relationships among informal learning environments, teaching procedures and scientific reasoning ability. International Journal of Science Education, 23(5), 535-549.

Gerber, B. L., Marek, E. A., & Cavallo, A. M. L. (2001). Development of an informal learning opportunities assay. International Journal of Science Education, 23(6), 569-583.

Gilliland, H. (1995). Teaching the Native American. Third Edition. (3rd ed.). Dubuque IA: Kendall/Hunt Publishing Co.

Halloun, I., & David, H. (1998). Interpreting VASS dimensions and profiles. Science & Education, 7(6), 553-577.

Hoover, J. J., & Jacobs, C. C. (1992). A Survey of American Indian College Students: Perceptions toward Their Study Skills/College Life. Journal of American Indian Education, 32(1), 21-29.

Keuhl, R.O. (2000). Design of experiments: Statistical principles of research design and analysis. Pacific Grove, CA: Duxbury Press.
Kuhn, D. (2005). Education for thinking. Cambridge, Massachusetts: Harvard University Press, 109.

Larimore, J. A., & McClellan, G. S. (2005). Native American student retention in U.S. postsecondary education. New Directions for Student Services, 109, 17-32.

Lederman, N. G., Abd-El-Khalick, F., Bell, R. L., & Schwartz, R. (2002). Views of nature of science questionnaire: Toward valid and meaningful assessment of learner’s conceptions of nature of science. Journal of Research in Science Teaching, 39(6), 497-521.

Lee, V. S., Greene, D. B., Odom, J., Schechter, E., & Slatta, R. W. (2004). Teaching and learning through inquiry (V. S. Lee, Ed.). Sterling, VA: Syllus Publishing.

Lemont, E. (2001). Developing effective processes of American Indian constitutional and government reform: Lessons from the Cherokee Nation of Oklahoma, Hualapai Nation, Navajo Nation, and Northern Cheyenne Tribe. American Indian Law Review, (26).

Marek, E. A., Cowan, C. C., & Cavallo, A. M. L. (1994). Students' misconceptions about diffusion: how can they be eliminated? The American Biology Teacher, 56(2), 74-77.

Marek, E. A., Eubanks, C., & Gallaher, T. H. (1990). Teachers' understanding and the use of the learning cycle. Journal of Research in Science Teaching, 27(9), 821-834.

Marek, E. A., Haack, C., & McWhirter, L. (1994). Long-term use of learning cycles following in-service institutes. Journal of Science Teacher Education, 5(2), 48-55.

Marek, E. A., & Laubach, T. (2007). Bridging the gap between theory and practice: A success story from science education. In M. Gordon & T. V. O'Brien (Eds.), Bridging Theory and Practice in Teacher Education. Netherlands: Sense Publishers.

Marzano, R. J. (2003). What works in schools: translating research into action. Alexandra, VA: Association for supervision and curriculum development. p. 37-39.

Matthew, C. E., & Smith, W. S. (1994) Native American related materials in elementary science instruction. Journal of Research in Science Teaching, 31(4), 363-380.

May, G. S., & Chubin, D. E. (2003). A Retrospective on Undergraduate Engineering Success for Underrepresented Minority Students. Journal of Engineering Education, 92(1), 27-40.

Moore D.S., & McCabe, G.P. (2006). Introduction to the practice of statistics. New York, NY: W.H. Freeman National Center for Education Statistics. (2002). The condition of education: 2002. Retrieved Nov 9, 2008, from http://nces.ed.gov/pubs2002/2002025.pdf

National Institute for Science Education. (n.d.).Field Tested Learning Assessment Guide. Accessed September 27, 2008, from http://www.flaguide.org/index.php

Nelson-Barber, S., & Estrin, E. T. (1995). Bringing Native American perspectives to mathematics and science teaching. Theory into Practice, 34(3), 174-184.

O'Brien, J. E. (2006). Recapturing the history standards: historical inquiry in the middle grades. Middle School Journal, 37(4), 11-15.

Pavel, D. M. (1992). American Indians and Alaskan Natives in higher education: Research on Participation and Graduation. ERIC Digest, (ED 348 197).

Seiler, G. (2001) Reversing the standard direction: Science emerging from the lives of African American students. Journal of Research in Science Teaching, (28)9. 1000-1024.

Snively, G., & Corsiglia, J. (2000). Discovering indigenous science: implications for science education. Science Education, 85(1), 6-34.

Southwest Educational Development Laboratory. (1995). Maryetta School: the center of a rural community and a case study of leadership and school improvement. Issues about Change, 5(1), 5-27.

Steinberg, L. (2007). Why I became a scientist. Education Leadership, 64(4), 13.

Tomlinson, C. A. (2004). Sharing responsibility for differentiating instruction. Roeper Review, 26(4), 188-189.

Urdan, T.C. (2005). Statistics in plain English. Mahwah, NJ: Lawrence Erlbaum Associates, Inc.
Willis, S., & Mann, L. (2000). Curriculum update-Differentiating instruction. Association for Supervision and Curriculum Development. Alexandria, VA.

Wright, B. (1990). American Indian Studies Programs: Surviving the '80's, Thriving in the '90's. Journal of American Indian Education, 30(l), 17-24.

Appendix A
DAST-C
Number________________Grade/Age_______________Gender___________________
Draw a scientist at work in the space below.

Explain what the scientist is doing.









List examples of where, when, and how you learn science.
Appendix B
Selected VOSTS Items
Number________________Grade/Age_______________Gender___________________

Please circle one choice per question.

90111—Scientific observations made by competent scientists will usually be different if the
scientists believe different theories.

Your position, basically:
(M) A. Yes, because scientists will experiment in different ways and will notice different things.
(I) B. Yes, because scientists will think differently and this will alter their observations.
(N) C. Scientific observations will not differ very much even though scientists believe different
theories. If the scientists are indeed competent their observations will be similar.
(N) D. No, because observations are as exact as possible. This is how science has been able to
advance.
(N) E. No, observations are exactly what we see and nothing more; they are the facts.





90211—Many scientific models used in research laboratories (such as the model of heat, the
neuron, DNA, or the atom) are copies of reality.

Your position, basically:
Scientific models ARE copies of reality:
(N) A. because scientists say they are true, so they must be true.
(N) B. because much scientific evidence has proven them true.
(N) C. because they are true to life. Their purpose is to show us reality or teach us something about it.
(N) D. Scientific models come close to being copies of reality, because they are based on scientific observations and research.

Scientific models are NOT copies of reality:
(I) E. because they are simply helpful for learning and explaining, within their limitations.
(I) F. because they change with time and with the state of our knowledge, like theories do.
(N) G. because these models must be ideas or educated guesses, since you can’t actually see the real thing.





90311—When scientists classify something (e.g., a plant according to its species, an element
according to the periodic table, energy according to its source, or a star according to its size), scientists are classifying nature according to the way nature really is; any other way would simply be wrong.

Your position, basically:
(N) A. Classifications match the way nature really is, because scientists have proven them over many years of work.
(N) B. Classifications match the way nature really is, because scientists use observable
characteristics when they classify.
(I) C. Scientists classify nature in the most simple and logical way, but their way is not necessarily the only way.
(I) D. There are many ways to classify nature, but agreeing on one universal system allows scientists
to avoid confusion in their work.
(I) E. There could be other correct ways to classify nature, because science is liable to change and new discoveries may lead to different classifications.
(I) F. Nobody knows the way nature really is. Scientists classify nature according to their perceptions or theories. Science is never exact, and nature is so diverse. Thus, scientists could correctly use more than one classification scheme.





90411—Even when scientific investigations are done correctly, the knowledge that scientists
discover from those investigations may change in the future.

Your position, basically:
Scientific knowledge changes:
(I) A. because new scientists disprove the theories or discoveries of old scientists. Scientists do this by using new techniques or improved instruments, by finding new factors overlooked before, or by detecting errors in the original ‘‘correct’’ investigation.
(I) B. because the old knowledge is reinterpreted in light of new discoveries. Scientific facts can
change.
(N) C. Scientific knowledge APPEARS to change because the interpretation or the application of
the old facts can change. Correctly done experiments yield unchangeable facts.
(N) D. Scientific knowledge APPEARS to change because new knowledge is added on to old
knowledge; the old knowledge doesn’t change.





90511—Scientific ideas develop from hypotheses to theories, and finally, if they are good enough, to being scientific laws.

Your position, basically:
Hypotheses can lead to theories, which can lead to laws:
(N) A. because a hypothesis is tested by experiments, if it proves correct, it becomes a theory. After a theory has been proven true many times by different people and has been around for a long time, it becomes a law.
(N) B. because a hypothesis is tested by experiments, if there is supporting evidence, it’s a theory. After a theory has been tested many times and seems to be essentially correct, it’s good enough to become a law.
(N) C. because it is a logical way for scientific ideas to develop.
(N) D. Theories cannot become laws because they both are different types of ideas. Theories are
based on scientific ideas, which are less than 100% certain, and so theories cannot be proven true. Laws, however, are based on facts only and are 100% sure.
(I) E. Theories cannot become laws because they both are different types of ideas. Laws describe
things in general. Theories explain these laws. However, with supporting evidence, hypotheses may become theories (explanations) or laws (descriptions).





90521—When developing new theories or laws, scientists need to make certain assumptions about nature (e.g., matter is made up of atoms). These assumptions must be true in order for science to progress properly.

Your position, basically:
Assumptions MUST be true in order for science to progress:
(N) A. because correct assumptions are needed for correct theories and laws. Otherwise, scientists would waste a lot of time and effort using wrong theories and laws.
(N) B. otherwise society would have serious problems, such as inadequate technology and
dangerous chemicals.
(N) C. because scientists do research to prove their assumptions true before going on with their
work.
(N) D. It depends. Sometimes science needs true assumptions in order to progress. But sometimes history has shown that great discoveries have been made by disproving a theory and learning from its false assumptions.
(I) E. It doesn’t matter. Scientists have to make assumptions, true or not, to get started on a project. History has shown that great discoveries have been made by disproving a theory and learning from its false assumptions.
(N) F. Scientists do not make assumptions. They research an idea to find out if the idea is true. They do not assume it is true.





90541—Good scientific theories explain observations well. But good theories are also simple
rather than complex.

Your position, basically:
(N) A. Good theories are simple. The best language to use in science is simple, short, direct
language.
(N) B. It depends on how deeply you want to get into the explanation. A good theory can explain
something either in a simple way or in a complex way.
(I) C. It depends on the theory. Some good theories are simple, some are complex.
(N) D. Good theories can be complex, but they must be able to be translated into simple language if they are going to be used.
(M) E. Theories are usually complex. Some things cannot be simplified if a lot of details are
involved.
(M) F. Most good theories are complex. If the world was simpler, theories could be simpler.





90621—The best scientists are those who follow the steps of the scientific method.

Your position, basically:
(N) A. The scientific method ensures valid, clear, logical, and accurate results. Thus, most scientists will follow the steps of the scientific method.
(N) B. The scientific method should work well for most scientists; based on what we learned in
school.
(M) C. The scientific method is useful in many instances, but it does not ensure results. Thus, the
best scientists will also use originality and creativity.
(I) D. The best scientists are those who use any method that might get favorable results (including
the method of imagination and creativity).
(M) E. Many scientific discoveries were made by accident, and not by sticking to the scientific
method.





90651—Scientists should NOT make errors in their work because these errors slow the advance of science.

Your position basically:
(N) A. Errors slow the advance of science. Misleading information can lead to false conclusions. If scientists do not immediately correct the errors in their results, then science is not advancing.
(M) B. Errors slow the advance of science. New technology and equipment reduce errors by
improving accuracy and so science will advance faster.

Errors CANNOT be avoided:
(I) C. so scientists reduce errors by checking each others’ results until agreement is reached.
(M) D. some errors can slow the advance of science, but other errors can lead to a new discovery or breakthrough. If scientists learn from their errors and correct them, science will advance.
(N) E. Errors most often help the advance of science. Science advances by detecting and correcting the errors of the past.





90711—Even when making predictions based on accurate knowledge, scientists and engineers can tell us only what probably might happen. They cannot tell what will happen for certain.

Your position basically:
Predictions are NEVER certain:
(I) A. because there is always room for error and unforeseen events that will affect a result. No one can predict the future for certain.
(I) B. because accurate knowledge changes as new discoveries are made, and therefore predictions will always change.
(N) C. because a prediction is not a statement of fact. It is an educated guess.
(M) D. because scientists never have all the facts. Some data are always missing.
(N) E. It depends. Predictions are certain, only as long as there is accurate knowledge and enough information.





91011—For this statement, assume that a gold miner ‘‘discovers’’ gold while an artist ‘‘invents’’ a sculpture. Some people think that scientists discover scientific LAWS. Others think that scientists invent them. What do you think?

Your position, basically:
Scientists discover scientific laws:
(N) A. because the laws are out there in nature and scientists just have to find them.
(N) B. because laws are based on experimental facts.
(N) C. but scientists invent the methods to find those laws.
(N) D. Some scientists may stumble onto a law by chance, thus discovering it. But other scientists may invent the law from facts they already know.
(I) E. Scientists invent laws, because scientists interpret the experimental facts that they discover.
Scientists do not invent what nature does, but they do invent the laws that describe what nature does.





91012—For this statement, assume that a gold miner ‘‘discovers gold’’ while an artist ‘‘invents’’ a sculpture. Some people think that scientists discover scientific HYPOTHESES. Others think that scientists invent them. What do you think?

Your position, basically:
Scientists discover a hypothesis:
(N) A. because the idea was there all the time to be uncovered.
(N) B. because it is based on experimental facts.
(N) C. but scientists invent the methods to find the hypothesis.
(N) D. Some scientists may stumble onto a hypothesis by chance, thus discovering it. But other
scientists may invent the hypothesis from facts they already know.

Scientists invent a hypothesis:
(I) F. because a hypothesis is an interpretation of experimental facts that scientists have discovered.
(M) F. because inventions (hypotheses) come from the mind—we create them.





91013—For this statement, assume that a gold miner ‘‘discovers’’ gold while an artist ‘‘invents’’ a sculpture. Some people think that scientists discover scientific THEORIES. Others think that scientists invent them. What do you think?

Your position, basically:
Scientists discover a theory:
(N) A. because the idea was there all the time to be uncovered.
(N) B. because it is based on experimental facts.
(N) C. but scientists invent the methods to find the theories.
(N) D. Some scientists may stumble onto a theory by chance, thus discovering it. But other scientists may invent the theory from facts they already know.

Scientists invent a theory:
(I) E. because a theory is an interpretation of experimental facts that scientists have discovered.
(M) F. because inventions (theories) come from the mind—we create them.





91111—Scientists in different fields look at the same thing from very different points of view (e.g.,Hþ causes chemists to think of acidity and physicists to think of protons). This makes it difficult for scientists in different fields to understand each others’ work.

Your position, basically:
It is difficult for scientists in different fields to understand each other:
(M) A. because scientific ideas depend on the scientist’s viewpoint or on what the scientist is used to.
(I) B. because scientists must make an effort to understand the language of other fields that overlap with their own field.
It is fairly easy for scientists in different fields to understand each other:
(N) C. because scientists are intelligent and so they can find ways to learn the different languages
and points of view of another field.
(N) D. because they have likely studied the various fields at one time.
(N) E. because scientific ideas overlap from field to field. Facts are facts no matter what the scientific field is.

Appendix C

Number________________Grade/Age_______________Gender___________________

Please write your responses in the space below.

VNOS - Form B
1. After scientists have developed a theory (e.g. atomic theory), does the theory ever change? If you believe that theories do change, explain why we bother to teach scientific theories. Defend your answer with examples.
2. What does an atom look like? How certain are scientists about the nature of the atom? What specific evidence do you think scientists use to determine what an atom looks like?
3. Is there a difference between a scientific theory and a scientific law? Give an example to illustrate your answer.
4. How are science and art similar? How are they different?
5. Scientists perform experiments/investigations when trying to solve problems. Other than the planning and design of these experiments/investigations, do scientists use their creativity and imagination during and after data collection? Please explain you answer and provide examples if appropriate.
6. Is there a difference between scientific knowledge and opinion? Give an example to illustrate your answer.
7. Some astronomers believe that the universe is expanding while others believe that it is shrinking; still others believe that the universe is in a static state without any expansion or shrinkage. How are these different conclusions possible if all of these scientists are looking at the same experiments and data?
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Friday, November 14, 2008

Grindstone Journal

This is an interesting Oklahoma-based blog.

http://www.grindstonejournal.com
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Minorities in Science and Science Education

Here are links to some web sites concerned with underrepresented groups in STEM majors and careers.

http://www.ncourages.org

http://coe.asu.edu/cie

http://vcc.asu.edu/stem.shtml

http://www.aises.org

http://www.niea.org

http://www.opcaises.org/Portals/22/2007_CNA_AISES_Status.pdf

http://www.sacnas.org/

http://www.dlisr.org/nativescience/processes.html
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Science Education Professional Organizations

Here are links to some of the professional organizations to which I belong. I am attending and presenting research at the spring conferences of each of them as well.


http://www.nsta.org

http://www.aera.net

http://www.narst.org

http://theaste.org

http://www.aacte.org

http://www.oascd.org/
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NCATE

In addition to my teaching and student teacher supervision responsibilities this semester, I have also been working on my dissertation and helping with the College of Education's preparation for a visit from the National Council for Accreditation of Teacher Education in 2011. Here is the NCATE web site.

http://www.ncate.org
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Sunday, October 12, 2008

APA Formatting and Style Guide

This is the format we use in science education most often, and this is the best online reference I have found.

http://owl.english.purdue.edu/owl/resource/560/01/
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Thursday, October 09, 2008

University of Oklahoma College of Education Collings Hall Renovation

Funds are being raised to renovate Collings Hall, including a new Science Education Center dedicated to Dr. Jack Renner. Please click below to see how to donate. Thanks!

https://www.oufoundation.org/onlinegiving/makegiftgen.aspx?club=0032608_Educ_Collings&fund=0032608_Educ_Collings

This is taken from the Oklahoma Science Teachers Association (OSTA) web site:

John W. “Jack” Renner Science Education Center

Issac Newton is credited with saying “If I have seen a little further it is by standing on the shoulders of Giants.” Time has passed and many current science teachers in Oklahoma are not of sufficient age to remember, but we have had a giant in our profession who’s influence is still felt in how quality science education is understood. Dr. John W. “Jack” Renner taught science education at OU from 1962-1988, and his students continue to make phenomenal impacts on science education in Oklahoma, throughout the country, and around the world. His work on the Learning Cycle in the 1970’s was a part of the development of the Science Curriculum Improvement Study (SCIS) program supported by the National Science Foundation. The success of the learning cycle lead to it’s use as the origin and foundation for the Biological Science Curriculum Study (BSCS) and the Full Option Science System (FOSS). The Learning Cycle approach and it’s underlying teaching philosophy of constructivism shows itself today in the inquiry approach defined by the National Science Education Standards (NSES) and the process skill development required by our own Priority Academic Student Skills (PASS). Jack was recognized for his contributions by NSTA with the Robert H. Carleton Award which annually recognizes one individual who has made outstanding contributions to, and provided leadership in, science education at the national level and to NSTA in particular. It is NSTA’s highest honor. In like manner, the Jack Renner Award is OSTA’s highest honor given each year to a person who has made a significant contribution to science education in Oklahoma.
Friends and colleagues are working on a special campaign to raise $50,000 that will allow for the dedication of a laboratory as a memorial to Jack in the new wing of the University of Oklahoma College of Education that will house a state-of-the-art facility for science education. This new science education laboratory will be named the John W. “Jack” Renner Science Education Center and will symbolize to future science educators his tradition of academic excellence, love of science and the learning cycle.
This is your invitation to contribute to this campaign. Please take time to pledge a contribution. The OU College of Education will keep you apprised of the status of this important effort. If you have questions about the campaign or wish to make or pledge a contribution, contact John Cougher, Director of Development for the College of Education (jcougher@ou.edu or 405.325.1266). John can explain the specifics of the larger capital campaign or details of this particular endeavor. Questions about the campaign may also be directed to Dr. Ed Marek, Presidential Professor, Director of the Science Education Center at OU, eamarek@ou.edu.
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Field Tested Learning Assessment Guide

Here is a link to a helpful web page with many valuable research tools.


http://www.flaguide.org/index.php
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Science Education Journals

Here is a link to a web site listing most of the relevant science education journals.

http://homepages.wmich.edu/~rudged/journals.html
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Puebla Blog Link

The link to our Mexico blog has been removed from the OU College of Education web site, but here is the link for those still wishing to view it.

http://education.ou.edu/puebla_blog
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Saturday, September 13, 2008

Rasmussen College Criminal Justice Web Site Review

http://www.rasmussen.edu/default.asp

http://www.rasmussen.edu/criminal-justice/default.asp

http://www.rasmussen.edu/criminal-justice/gallery/default.asp

Rasmussen College has an excellent web site overall, and specifically for its Criminal Justice programs. It is well-formatted, offers ease of use, pictorials, and plenty of information. Anyone interested in pursuing their education in these or related fields is advised to check it out. Visually, the site is interesting, and it is extremely easy to navigate and find the information you are seeking. Rasmussen College offers a wide range of programs, including within their Criminal Justice department. I was impressed with the layout as well as the content, and how efficiently all aspects of an education at Rasmussen is explained. In fact, a wide range of levels and types of programs are offered, including:


Bachelor's Degree in Criminal Justice
Client Services / Corrections
Criminal Offenders
Homeland Security
Investigation / Law Enforcement
Associate's Degree in Criminal Justice
Corrections
Crime Scene Evidence
Homeland Security
Law Enforcement
Associate's degree in Paralegal
Paralegal Certificate
Professional Peace Officer Education Certificate

Again, this is truly a well-organized and useful web site, easy to navigate and replete with visuals.
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VerveEarth

I found an interesting site that references blogs by geography and thought I would share it with the readers of this blog. The idea of charting blogs by location is unique and potentially very useful. Check it out!

http://www.verveearth.com/
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Sunday, August 17, 2008

Human Relations Paper-Mexico





Migrant Situation from a cross country view in Puebla, Mexico
Mary Crofford
University of Oklahoma


Abstract

This paper is an overview of my stay in Puebla, Mexico for five weeks this summer. The research topics are based on encounters from the people and experiences there. The focus is on migrant populations. The migrant families, their earnings as well as the situations they find themselves in away from home and the family they left in Mexico.


Paper:

The American Identity crisis as the right has often put it, leaves us with a sour taste of cultural integration in our mouth and mind. At the heart of the debate is migration primarily from our southern neighbor. Mexico has long since been at odds for various reasons. However, as they put it, “the border crossed us,” 150 years ago during the Mexican-American war. (Levine, 2007) With sentiments that compare the alienation of Mexico to the Berlin wall. (Pedersen, 2007) These dueling sociological groups have several contrasting factors while the border is loosened up buy travel, trade and mere location, regulations and rules are tightening for the movement of people.

The identity crisis that is at stake some would believe is America, as Patrick Buchanan said during his 1992 campaign, “there is war going on, it is a cultural war and critical to the nation that we will one day be”. He refers to this sentiment as a takeover or invasion by the third world. (Pedersen, 2007) Just as this movement is vying for a call of American/Western ideals another is in place based on integration and inclusiveness.

Mexican migrants come to America risking their lives to claim a better lot here, 575,000 a year since 2000. (Hendrix, 2007) The American anthem is sung in Spanish at protests against public policies that limit aid and make border crossing inhumanly dangerous. We now see ads in Spanish and more attention to diversifying the labor market.

However there rests one central idea for both groups that is to curb the movement of people. Mexico wishes to keep its young people there to grow the economy, while America wishes to limit the number of immigrants for job and capital.

My husband and I will be spending five weeks in the fourth largest city in Mexico, known as Puebla. Our main intent is to find out how to better serve the migrant population of students currently in the United States public school system. Another is to look at the panorama of the migrant situation.

We are coordinating our visit in conjunction with the OU College of Education immersion program. They send a group to Universidad Popular Autonoma del Estado de Puebla, (UPAEP) to immerse them in language and culture and look at the schools. We will be doing some activities (weekend trip; meetings) and working with the same office that coordinates the visits, however our research will be taking us out more to look at on the workings of individual schools and focusing on systems. We have scheduled visits to secondary and elementary schools as well as meetings with scholars and other authorities on migrants and educational systems for the first three weeks. However, for the last two weeks we will be visiting with locals, sightseeing, and delving into rural communities to look through a Human Relations lens. We will also be attending a conference on culture and systems of Mexico and Mexican people and taking Spanish classes.

I am here specifically to gather statistics as well as find out about the issues of migration from this perspective. To examine Human Relations issues that I see, and begin to understand them, I as find myself a part of them. To focus on those issues from a cultural understanding lens while inside Mexico. Families who have moved north to work or those who are planning on moving north to work will help to see what they have left behind. What are the driving forces and the situational problems? Within that aspect will be the effects on the children and family. This will be examined through an eyeball account of schools, both rural and urban as well talking to people we encounter.

Besides the basic learning process of cultural norms and language barriers while here, daily accounts and interactions with people in Puebla make-up the basic framework of this paper, and the research arose out questions from those encounters. Therefore several statistics on various topics are included.

Ciudad Puebla
As we arrive in Mexico City the streets are loud and highly over crowded. The cars are backed up like nothing I have ever seen, because I have never been out of America. Beggars fill the streets with wash buckets for car windows; Chiclets, candy or juice are for sell. The streets are marked clearly with lines but no one seems to care, they make four lanes out of two, or three where there should be one. Puebla sits about three hours south of Mexico City, and we are headed there and for UPAEP. We settle in our first night in our apartment it is little but very comfortable.

Puebla is located about eighty miles south of Mexico City and is in Puebla valley (see insert figure 1). The capital city of the state of Puebla, Mexico it sits 7,091 feet above sea level. Founded in 1851, it is one of the oldest cities in Mexico with a population of roughly 1.3 million in 2000. The climate ranges from 40 to 80 degrees Fahrenheit year round with heavy rains in the summer months; it is ideal for growing fruit and flowers (Mulhare,1998).
Figure 1

Dr Alfredo Toxqui Middle School
Today is our first full day in Puebla and as we arrive at the Alfred Toxqui Middle school we are greeted several teachers and administration.

The school is fully concrete in the middle of a bustling neighborhood, there is no playground there is only concrete. We are told by one of the administrators that we may go into the main office, the door closes and I notice that we are not in an office with the head director but we are in a small front room surrounded by what feel like the entire faculty of six or seven maestros (teachers) that do not any speak any English at all, and we don’t speak Spanish I notice this and can’t help but think that if it were in America we would not doubt be behind a closed door with one solitary person that was heading up the whole school. Here we all listen to each other they all spoke and everyone sat around.
As we enter our first class of fourth graders I see a room of about twenty kids they are in uniform and very quiet as we walk in, they stand. We are introduced to the class and proceed to the back. I see that the weather is so perfect the low breeze with smell of city provides for the thermostat, they leave the windows and doors open all time you can hear the loud noises of the street over all the voice of the teacher yet none of the children are raising their voices nor do they ask for something to be repeated they don’t need too, they are totally attentive.

As we enter the next classroom I notice that the first graders here have virtually no teaching tools there are no books in shelves and there are not cabinets filled with the regular stuff that I see in American schools there is only a concrete floor and old wooden mini picnic looking tables that are used as the desks. They are worn.

The next day we return to Toxqui to observe. The second grade classroom that we are visiting is gracious as always, they are working with numbers and boxes. Something that struck yesterday has stayed with us. A boy in one of the classrooms hits another, throws a hard punch right to his cheek, while we were waiting for the teacher to return. We were stunned. My husband and I started talking to each other about how we would not have put up with that, and in an American classroom someone would have said something they would have hit back or at the very least been angry. No one said anything when the teacher returned it was like it did not happen. None of the kids were angry and no one told on him. So I wondered if this was a regular occurrence of hitting. If they punch and do not get in trouble, or if it seen as young boys just playing? But I also had to add our thoughts into the equation of America being a supposed culture of violence. Maybe it is in Mexico that the exception is a hitter. Could our classrooms just have an abundance of children that hit because of our culture?

The director of Toxqui is Manuel Hernandez, an attorney and kind man who invited us to his home like family. He told us as we walked in to that his home was our home, and welcomed us warmly. One thing we were surprised to see was that he took us in to his son’s bedroom and opened up the closet to show his clothes, he then stated, “I work very hard to provide everything that my children need.” We had spent very little time with this man but it was important to him for us to see how he lived.

As we visited Dr. Toxqui Elementary School again as usual were greeted warmly and made to feel at home. We watched the students practice their dances for a festival, carry out presentations on geometry topics, and play related games. One of the teachers expressed her frustrations with the students’ economic situations and how it impacts their schooling and ambitions. She said almost all the children are from single parent families and struggle to get by. The older siblings are often impaired educationally because they must care for the younger siblings while their mother works. She stated that much of the money the state and federal Mexican governments claim to provide the schools never actually makes it to them. In fact, she said they are lucky if each teacher receives 60 pesos per month for 30 students or more. Please note, this is supposed to pay for food as well as school supplies. She also suggested bringing teachers like her to the US would be an effective approach for improving migrant education in the US.

Dr. Ricardo Flores Magon General Secondary School
The following day we travel to a remote school that sits out side of the city by thirty minutes or so, the reality of what an economically contrasting country Mexico is hits us: we are only thirty minutes outside a major metropolitan area and we begin to see burros hauling wood and oxen pulling plows.

The rural school makes us feel very welcome. They have a social worker and we set up times for me to meet with her. She says there are several issues that she has to deal with, some are typical and others such as separation of family because one parent has to another country to work.

The next day is our first classroom visit to the secondary school, Ricardo Flores Magon. It is outside of Puebla near a small town called Chalchinuapan. As we arrive at the school the students are all walking in a huge entourage from the nearby village. They start out their day and week with a flag assembly in which all students participate, at 7:30 in the morning. All the students wear uniforms and stand respectfully, sometimes saluting, throughout the entire ceremony. The assembly was rigid, all the students moved in sync and they saluted and waved their hands in the air as they marched, it looked very European they practice this from a very young age. After the presentation of the Mexican flag, the students sing the Mexican national anthem, and then sing one for the state of Puebla, as well as a song specific for secondary schools. The school’s director or professor introduced us as representatives of the University of Oklahoma.

The setting of this school is rural and there are fields of prickly pear, corn, and other crops around, being plowed by burros. Some houses are large and Spanish style, they are structurally very beautiful but here a large with running water and clean facilities means one thing: that the father or son has gone to American for work. Figure 2 shows remittance flow in 2006.

Total Remittances………23053.8 USD
Money Orders………5.9%
Personal Checks………0.0%
Electronic Transfers………92.6%
Cash and In Kind………1.5%
Figure 2


Other houses do not have a roof. In fact, many homes have rebar sticking from the top, as families hope to add additional levels as they can afford it in the future. There are also large black plastic containers on the roofs, into which water is pumped, which then flows into the house when needed due to gravity. There is a huge contrast in the houses that you see in this rural area; as you look out you can see very beautiful countryside, almost European-like, while huge churches over look everything.

The school day gets underway with a short first hour due to the weekly assembly. There are various areas of curriculum being taught; Natural Science, Math, Spanish, English, State History/Geography, Art, Technology/Computers, and Music/PE. We are told that the school year breaks down into two semesters like their American counterparts, a semester of August to December and the second of January through June.

The classes have a smart board and computer as well regular boards, and the class size averages around thirty. Magon School has a complete and modern computer lab. Today we visited science and math seventh grade classes.

We returned to Magon Secondary School early this cold, cloudy, and rainy morning. Fog and clouds obscure the mountains and volcanoes. The director was not here to greet us but we soon settled into a third year mathematics class for a geometry lesson and practice problems. After touring the campus some more and visiting with the staff we sat in on a third year science class. The maestra lectured on electromagnetism, and the students took notes and read aloud. After that class we sat down for an interview with the social worker and learned several interesting things. She starts her day at 8 am and ends at 3 pm, and she does not go year round, instead she goes the length of the school’s year. She serves as a counselor and nurse as well. One of her more difficult jobs is dealing with the parents. Very few parents are vested in their children’s education, many of them want their children working or they are very preoccupied with trying to get from one day to the next. Many of the parents work as cleaning help or they make sponges, clotheslines, and so on to sell on the street. She estimated three parents out of the school of 200 students she knew of had steady jobs at the local Volkswagen factory.

The United States federally mandated minimum wage of $5.15 an hour is approximately ten times greater than that of the Mexican minimum wage which is 47.05 pesos in 2006, around 4.20 a day. (Levine, 2007) The figure shows the breakdown of job configuration, conversely we will see it becomes very hard to discern what constitutes “employed”.



Mexico Occupational Structure 2006
Total Employed 41,909
Agricultural Activities…14.5%
Goods Production…16.6
Construction…8.2
Total Services…54.4
Figure 3

Students here generally have one of three options upon leaving Magon assuming they complete high school; they may marry, go to the US and work, or make crafts and trinkets to sell. Financially, it is very difficult for them to go to university.

The Mexican working population breaks down as 22 percent earn the minimum wage or less, two-thirds only earn three times that, combing to make a total of that 83% earn only up to five times the minimum wage (Levine, 2007). The unemployment numbers often register as very skewed due to lax definition of “employed population,” …all persons of working age (fourteen plus) during the reference week participated in economic activities for monetary wage, nonmonetary wage, or no payment, and those who would be starting a job within the space of a month (Levine, 2007). The effort here was to cover the sporadic and unofficial economy employees which count for roughly half (Levine, 2007). The workers have little to no benefits. Forty eight percent of wage earners have no contract, while 20 percent work less than 35 hours a week and 27 percent work a reported 48+ hours weekly. The Mexican social security system will provide health care, however only 32 percent are covered (Levine, 2007).

The social worker talked about medical care for the students and the Mexican system. For example, if a student gets injured at school they are able to go to the clinic in town and the social worker will take them. They have cases where a traditional family will not go to the doctor because they believe that a medicine man will heal them better and faster than modern medicine. Another instance was a girl came to school with a severe cut on her arm; it had happened over the weekend but the parents did not take her for medical care because they could not afford the visit. In Mexico, for example, total expenditure on health care is only 5.6% of the gross national product—compared with about 15% in the USA (Ruelas, 2002).

One thousand public hospitals have 75% of the beds; 90% of the 3000 private hospitals have ≤20 beds, often as few as ≤5 beds. In fact, some “private hospitals” can hardly be considered hospitals at all, since they have no laboratories, radiography equipment, or even nurses (Ruelas, 2002).

Many of the children in this area live below the poverty line so health care is limited and they pay a heavy price. If one child is born in the Native Indian part of the state of Chihuahua and another is born the same day in Monterey, those children immediately face inequities: the child born in Monterey has a 17-year longer life expectancy. While yearly around 3 million people in Mexico face catastrophic expenses due to major illnesses or injuries (Ruelas, 2002).

As the social worker she estimates that 70-80% of her parents are migrants, which means that many of them were being raised by single mothers who cannot find work. And when they do, it means they will be left to care for their siblings this was not specific to rural populations, as it is the same in urban areas. The social worker said that the migrants in the US are telling people at home not to come to America, but many people are determined to get there. Another obstacle the children face is not knowing their family, some children have never met their fathers and on occasion their mothers either; they are being raised by their grandparents, because they moved to America to work as well. This is distressing to me, because my observations so far have revealed basically good schools with motivated and knowledgeable teachers who truly care about their pupils.
The students themselves are bright, respectful, and hard working.
Although a new trend is happening as children can be left without both parents, in that women are no longer the companion migratory rather they are crossing the border and finding employment for themselves. Figure 4 shows trend of migrant women.
1995 2005 Total Percentage Total Percentage
Citizenship Status 3,089,367 100.0 4,914,161 100.0
American Citizen 482,83 15.6 1,105,348 22.5
Non-American Citizen 2,606,484 84.4 3,808,813 77.5
Arrival in the US 3,089,367 100.00 4,914,161 100.0
Before 1986 1,834,340 59.4 1,418,406 28.9
1986-1994 1,225,027 40.6 1,167,668 23.8
1995-2000 -- -- 2,328,087 47.4
Figure 4

This shows only the female demographics. Mexican’s constitute the largest sector of the foreign born population living in the US (Perez et all, 2007); with around 11 million in 2005 immigrants here. within these population figures the number of house hold headed by Mexicans total 4,070,910. This labor market integration is a collection of push/ pull factors involving economic reorganization and innovation, which has left Mexico with a large population of surplus labor. Therefore they better their by chance by coming to America. There are however, socioeconomic constraints awaiting their arrival in the US as well. The Latino labor force holds a median income of 651 USD weekly. This show approximately 18 million Latino workers not just Mexican migrants. With the largest percent holding janitorial or cook positions (Levine, 2007).


Today we visited a Magon English class. They were in seventh grade and they were learning basic English vocabulary. After the English lesson we gathered four children for an interview to go over what their daily life is like.

As we sat down with two boys and girls ages 13-15 in eighth and ninth grades, we began to discuss their favorite school subjects. All the students said they liked the science classes the best because they found it more interesting and there was more to do.

All of the children walk from the town to school and it is about a 10-minute walk. Their school day is from 7:30 in the morning until 1:15. We asked why is it that when we pull into the school all the kids are walking in almost one huge group, why is that? How does that happen? He said all just start waling and just see each other. If you can imagine this tiny community, to see a hoard of 200 some children walking to school every morning, no one has a car and they are so close in proximity, they all end up walking together and this represents a sense of reliance within the community. American communities are much bigger, but to get a group of that size together takes organization and planning.

We began to talk about what they do after the school day is done. One of the boys said that he goes to work. He told us that his family has a store. And that he goes to the store after school, to sell the candy, pop and other odds and ends. The other boy said the he must go home and help his mother look after his other siblings due to the fact that his father is in America working. The Migrant center in Puebla sets up phone conversations with television-like screens where toddlers often see there fathers for the first time. Three of the other children live with their parents while he lives only with his mother. While girls must go home and help also some of them make stuff to sell.

They have several of the interests as their American counterparts, sports and reading but there is little in the way of extracurricular activities. They read and watch TV and go for walks in the town.

All of the students said that they want to keep studying after high school; they wanted to be accountants, or work in technology. We had several more question as we began to wrap up, I wanted to dig further about the boy whose father worked in New Jersey, but in a situation like this it becomes hard to assess what is it appropriate to ask and not.

Cuetzalan, Mexico
As the weekend got underway we joined other exchange students, teachers, social workers, and nurses on a trip to the city of Cuetzalan in the mountainous part of the state of Puebla. We departed early and enjoyed a comfortable four-hour bus ride through winding and hilly terrain. Upon arrival we checked in and immediately hiked to and explored a local cave. We saw wild coffee, banana, and papaya plants growing amongst the lush vegetation and cultivated fields of maize and other crops. Birds, butterflies, and other animals were numerous. We could choose between shopping in the picturesque town, rappelling and swimming in a waterfall, or horseback riding. The local cuisine was exotic and sumptuous, and at night the UPAEP and hotel staff held a cook out for us. We were also able to explore the Mayan ruins near the village of Yohualichan.

We were explained to on the bus by the UPAEP official that the region around Cuetzalan is famous for growing coffee. It began to resonate with us that we were at the heart of a globalization process that some believe degrades the worker and others that it allows more power to buyer and seller. These are the farmers who work the coffee fields, and grew, picked, and sold the coffee. This aspect of research was very important in order fully understand these very real and complex Human Relations issues. I bought some coffee from a girl selling it on sidewalk to try, and it was delicious.
The daily cup I now sip on is not what I expected to have one the most profound influence on my trip, but it did. This intricate market we now participate in, has us drinking from a global trading system. According to PBS Frontline World News (2003) a coffee bean can change hands up to 150 times before reaching you. In Mexico 90 percent of coffee farms are 12.5 acres or less. The majority of them are owned by indigenous people. We traveled to these beautiful areas past the naturally growing plants. The profit is not equally distributed cross the board. These indigenous workers who grow the plant, which takes coffee plant around three years for a plant to produce around 2000 cherries which is only a pound of coffee. They then must hand pick at just the right time to guarantee the quality. They receive 10 to 12 cents on the dollar. I was looking at their homes and some live on dirt floors and they peddle juice or crafts they have made for a few pesos. One big issue is that production exceeds the use. The average cup goes from growers to traders that often have the only link to the outside knowledge of market worth, to shippers, roasters, and then retailers. Seeing this first hand had a profound impact on my sense of global community and corporate responsibility (Rubin, 2003).
We left with a realistic account and deeper understanding of a major Human Relations concern.

Teacher Interview and the SEP
The week got underway with a visit to Magon science class, where the children were presenting on Natural Phenomena. They presented reports on meteorology and astronomy as well health benefits of science, and they were prepping for a botany exercise that will improve the grounds of the school.

We had a chance to sit down with the teacher and ask a few questions, and we found out much information. She had been teaching for three years. In order to complete a teacher certification it takes six years, she was in her third year leaving three to go. One of the most interesting answers we found was given to us when we asked, “What do you need from the government to better serve your students”? She replied that it would be very good to have a breakfast provided for the students. They often come to class tired form watching their siblings all night, or working long hours, and there is not enough food. Parental involvement was needed as well, because so many of the parents have gone to work in America and that becomes an issue for the government because of a lack of jobs that pay well.

We also later found out that the average starting teacher pay in Mexico is 6,000 pesos a month, which is roughly 600 USD. Education in Mexico is regulated by the Secretariat of Public Education ( Secretaría de Educación Pública) or the SEP. In Mexican schools, students must master specific skills before being promoted to the next. Uniforms are traditionally worn by all students in elementary and middle schools for the purpose of lowering clothing costs, minimizing social class differences, instilling discipline and creating a school environment where all students have a sense of belonging (Roybal, 2004).
Educational standards are set by this Ministry at all levels except in autonomous universities chartered by the government. Basic Education comprises preschool, primary school, and lower secondary school. Preschool covers children aged three through five and is generally provided in three grades; Secondary Education, and Upper-Secondary Education is separate from Basic Education. This stage is non-compulsory and has three pathways: General upper-secondary, Technical professional education, and Technological upper-secondary. Until 1992, education was compulsory only through the end of primaria, or sixth grade. Many families still consider education important only through the primaria years, and there is significant attrition after sixth grade in urban as well as rural schools. (Stein, 2004)

For our dinner that we grabbed tacos from a taco stand and the young man cooking the food asked us if we were from Estados Unidos, when we replied yes he informed us that he was going to Chicago to work. Our Spanish improves so much through these conversations, as well gathering information about the people of Puebla. So many of the people that we address speak to us about leaving, that is what they want to do, all they want to do, and their main goal.

Additional Visits

The next week encompassed writing and reading and joining OU and UPAEP students and staff for short two hour visits to Manuel Acuna Primary School and Miguel Hidalgo Elementary School in Puebla. The focus was on special education in Mexico. We learned that Mexican special needs students are mainstreamed into the public schools, numbering anywhere from three to twenty per school. Special Education teachers and other personnel rotate through the schools 2-3 times per week. We observed pre-school and elementary students reading, dancing, singing, and in physical education. The second school that we visited did not have any electricity, as the bill had not been paid.

My husband and I attended our Spanish class later in the day, and bought bus tickets for our weekend trip to Veracruz, the largest port in Mexico.


The Immersion classes graduated today, and we attended. We enjoyed a huge ceremony, with wonderful traditional Mexican food, and entertainment by a Mariachi band. In Puebla they have a dish called Mole Poblano; it is made of several ingredients including chocolate and various chiles. The origin of Mole Poblano, this thick, rich, chocolate-tinged sauce made so famous in the colonial mountain city of Puebla (Nemerovsky). I know now that the word, “poblano” means the “Puebla people” like Oklahoman or Mexican, so anything with that word has origins of Puebla.

We also had Spanish class with our wonderful instructor, Rosario Robles. Our Spanish is improving significantly; some things are made so much harder due to the simple fact that we can neither speak nor understand the language very well. Afterward we boarded a bus for Veracruz, arriving late and checking in at the hotel near the beach. Joining us was Sherry Cox, OU Spanish instructor.

Veracruz, Mexico

We spent the weekend in the port city of Vera Cruz. Veracruz is Mexico's largest and most important port, and serves today all of Mexico's central and southern states with the extensive rail and road networks directly connected to the port. The port serves with its direct access to the Atlantic Basin all the eastern coast of North America, Central and South America, Europe and Africa (Wallengren, 2006). From 1994 to 1998, the cargo handled at the Port has increased from 8,000,000 to 13,000,000 tons (Sorensen, 1998).
This brings the issue of international trade to the table. Seeing as how I was once again witness to a global dynamic, so I thought I should further my knowledge.
One subject that was to curb migration as well as stimulate the trade between America and Mexico was the North American Free Trade Agreement (NAFTA). President Salinas of Mexico in the early 1990’s boasted that NAFTA would help Mexico to, “export goods and not people.” This came with a promise of modernizing the Mexican economy, higher wages and more jobs. México has figured in the past decade one of the top three trading partners, for both imports and exports, of the US (Levine, 2007). After NAFTA the foreign trade rose to over 50 percent which left Mexico’s economy vulnerable to our fluctuations. (Levine, 2007)
Let us take Tontaca for example, an area in the state of Veracruz where maiz or corn production is not just a crop but a way of life, and with a large Indigenous population they believe gods created humans from a mixture of blood and maiz dough. Maiz is a staple food and consumed on a daily basis in the form of tortillas. After NAFTA, Mexican markets opened to a flood of U.S. exports. From 1994 to 1996, maiz grain prices dropped by as much as 48 percent (King, 2005). Familiarizing these issues is important to understanding the places visited.
Early Saturday we ventured to the Malecon, or board walk, Mercado, and the famous “Grand Café de la Parroquia” for lecheros, which are espresso coffee and steamed milk. We took a boat across the harbor to the fortress of San Juan de Ulna, which for centuries has served as not only a fortress, but also a prison and government building. It was ironic how we pride ourselves on so many advancements in facilities and structures. This fort kept its prisoners there by filling the escape waters with sharks. However inhumane, they stated that no one had ever escaped in the time that it was a holding for criminals. After visiting the beaches near our hotel, we had a traditional Veracruz dinner and called it a day. On Sunday, before leaving for the bus station, we had time to rent another boat and visit Isla Sacrifios, in the Veracruz harbor. We observed fish, sea stars, sea urchins, coral, and other marine life. A brief visit to the world-renowned Veracruz Aquarium was unfortunately cut short due to our travel schedule. We return to Puebla with a few days to go.

After wrapping up and preparing ourselves to disengage from our apartment we had grown to call home and people that had helped get our bearings we were preparing to say good buy. What we have chosen to take with us varies from person to person.

Identity, through this lens, takes on a new meaning; it can call to question one’s stance on public policy of your own country. As you begin to understand the human relationships develop between two countries, your part and place and how you choose to nurture that connection becomes a reality. One group believes that they are at the mercy and dictation of a larger more powerful group with the only option to assimilate, where do we find ourselves in the equation?

Socioeconomic factors, disparities, and problems that separate families and divide countries cannot be solved by individuals alone but by mass movement, like migrations. I learned the issues cannot be tagged or labeled as one, but rather become a conglomerate force. Movement into America comes with a hefty price tag that many do not see, like a three year old boy who sees and hears his father for the first time over a TV screen and/or a phone call from America. Or the alienation that a foreigner feels thousands of miles away from home and family in a place where he or she cannot understand the language and is are not accepted, as public policy proves.
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13.Bread for the World Institute. (2005). Trade and Totomoxtle: Coping with NAFTA in the Totanacan region of Veracruz (Annual Report 2005). Washington DC: King, Amanda. Retrieved July 18, 2008 from http://www.bread.org/BFW-Institute/trade-sidebars/trade-and-totomoxtle.html

Figure 1
Puebla. (n.d.) In Wikipedia online. Retrieved July 29, 2008, from http://en.wikipedia.org/wiki/Puebla,_Puebla

Figure 2
Viallrreal, M. & Davy, M. Sending Money Home the Dynamics of Mexico-US Remittances. In Ashbee, E., & Clausen, H.B., & Pedersen, C. (Eds.), Politics, Economics and Culture of Mexican-US migration. (pp 91-106).New York: Palgrave-McMillan.

Figure 3
Levine, E. From Precarious, Low-Paying jobs in Mexico to Precarious Low Paying jobs in the United States. In Ashbee,E., & Clausen, H.B., & Pedersen, C. (Eds.), Politics, Economics and Culture of Mexican-US migration. (pp 63-90).New York: Palgrave-McMillan.

Figure 4
Saucedo, S.E. & Perez, M.A. & Olvera, S.G. The Other Side of the Migration Story: Mexican Women in the United States. . In Ashbee, E., & Clausen, H.B., & Pedersen, C. (Eds.), Politics, Economics and Culture of Mexican-US migration. (pp 39-61).New York: Palgrave-McMillan
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