Showing papers in "Journal of Research in Science Teaching in 1990"

Concept mapping: A useful tool for science education

Abstract: This article describes the genesis and development of concept mapping as a useful tool for science education. It also offers an overview of the contents of this special issue and comments on the current state of knowledge representation. Suggestions for further research are made throughout the article.

Student conceptions of natural selection and its role in evolution

Abstract: Pretests and posttests on the topic of evolution by natural selection were administered to students in a college nonmajors' biology course. Analysis of test responses revealed that most students understood evolution as a process in which species respond to environmental conditions by changing gradually over time. Student thinking differed from accepted biological theory in that (a) changes in traits were attributed to a need-driven adaptive process rather than random genetic mutation and sexual recombination, (b) no role was assigned to variation on traits within a population or differences in reproductive success, and (c) traits were seen as gradually changing in all members of a population. Although students had taken an average of 1.9 years of previous biology courses, performance on the pretest was uniformly low. There was no relationship between the amount of previous biology taken and either pretest or posttest performance. Belief in the truthfulness of evolutionary theory was also unrelated to either pretest or posttest performance. Course instruction using specially designed materials was moderately successful in improving students' understanding of the evolutionary process.

The concept map as a research tool: Exploring conceptual change in biology

Abstract: This study examined the concurrent validity of concept maps as vehicles for documenting and exploring conceptual change in biology. Students (N = 91) who enrolled in an elementary science methods course were randomly assigned to one of two treatment groups. Subjects in both groups were administered a multiple-choice/free-response inventory which assayed their knowledge of “Life Zones in the Ocean,” and then were asked to construct a concept map on the same topic. Those in the experimental group subsequently received 45 minutes of computer-assisted instruction on marine life zones, while those in the control (“placebo”) group received an equivalent exposure to an unrelated topic (“Body Defenses”). Upon completing the instructional sequence, subjects were again administered the “Life Zones” inventory and asked to develop a postinstruction concept map on marine life zones. The data analysis employed a split plot factorial design with repeated measures. Differences among treatment groups were documented by analysis of variance and chi-square procedures. Subjects in the experimental group showed evidence of significant and substantial changes in the complexity and prepositional structure of the knowledge base, as revealed in concept maps. No such changes were found in the control group. Results suggest that concept mapping offers a valid and potentially useful technique for documenting and exploring conceptual change in biology.

Gender differences in teacher-student interactions in science classrooms

Abstract: Thirty physical science and 30 chemistry classes, which contained a total of 1332 students, were observed using the Brophy-Good Teacher-Child Dyadic Interaction System. Classroom interactions were examined for gender differences that may contribute to the underrepresentation of women in physics and engineering courses and subsequent careers. The Brophy-Good coding process allows for examination of patterns of interactions for individuals and groups of pupils. An analysis of variance of the data yielded a significant main effect for teacher praise, call outs, procedural questions, and behavioral warnings based on the sex of the student and a significant teacher-sex main effect for direct questions. Significant two-way interactions were found for the behavioral warning variable for teacher sex and subject by student sex. Female teachers warned male students significantly more than female students. Male teachers warned both genders with similar frequency. Male students also received significantly more behavioral warnings in physical science classes than female students. In chemistry classes, both male and female students received approximately the same number of behavioral warnings.

Concept Mapping and the Cartography of Cognition.

Abstract: Since concept maps are designed to find out what the learner knows about a subject and are, in effect, maps of cognition, this article synthesizes relevant facts, concepts, and principles from cartography and applies them to concept mapping. The metaphor of the map and its applicability for representing scientific knowledge are discussed. The context of concept mapping is presented and suggestions for successful application of the technique in the science classroom are offered. Finally, researchers are invited to conduct studies that investigate the graphic representation of scientific knowledge in order to create, evaluate, and improve the graphics and graphic metacognitive tools (such as concept mapping) which are used in science teaching.

A Reassessment of the Effects of Inquiry-Based Science Curricula of the 60's on Student Performance.

Abstract: In this project a re-synthesis of the research dealing with student performance in new science curricula was conducted using the refined statistical procedures proposed by Hedges (1981, 1982a, 1982b, 1982c) and Hedges and Olkin (1985). The results of the re-synthesis generally supported the conclusions drawn in the earlier meta-analysis by Shymansky, Kyle, and Alport (1983); i.e., that the new science curricula of the 60's and 70's were more effective in enhancing student performance than traditional textbook-based programs of the time. But the re-synthesis also revealed some notable differences as well. For example, in the re-synthesis mean effects were significantly positive on four performance clusters (achievement, process skills, problem solving, and attitude) compared to seven clusters in the earlier analysis, and then by a smaller margin (the 1981 mean was 0.34 and the 1986 mean was 0.25). In one case (related skills), the mean effect changed from a +0.25 (significant at the 0.05 level) to –0.10. But perhaps more important than any particular change in the many analyses performed, the application of refined statistical procedures in the re-synthesis yielded results of greater precision than those generated in the original study. Thus, it is recommended that the data generated in this re-synthesis be used in any discussion of the effects of the new science curricula on student performance.

Accelerating the development of formal thinking in middle and high school students

Abstract: In an attempt to accelerate the development of formal operations in average young adolescents, intervention lessons relating to all formal schemata were designed in the context of school science courses. Over a period of two years, up to 30 intervention lessons were given by science teachers to their classes in eight schools. Boys who started the program aged 12+ showed a pre-posttest effect size on Piagetian tests of 0.89 SD compared with control classes. In terms of British norms for the development of operational thinking this was a mean change from the 51st to the 74th percentile. Neither the middle school students nor the 12+ girls showed greater gain than the controls. Gains were shown by girls in one 11+ class and in the two 11+ laboratory classes. In the laboratory school students given intervention lessons by the researchers maintained their gains over controls in formal operations at a delayed posttest one year after cessation of the program. There was no effect on tests of science achievement during the intervention. It was argued that the interventions needed to be accompanied by in-service training designed to enable teachers to change their teaching style in line with their students' increased operational thinking capacity.

Students' Misunderstandings and Misconceptions in College Freshman Chemistry (General and Organic).

Abstract: Both chemistry teachers and nonmajor students appear to agree that freshman chemistry may well be the most problematic traditional science discipline taught in the first year of college—as far as students' misunderstandings, learning difficulties, and misconceptions are concerned. The above is probably due to the many abstract, nonintuitive concepts, which are not directly interrelated. Consequently, in such cases, the powerful, general teaching strategy of “concept mapping” must be replaced by alternative, specific strategies. Selected illustrative examples of students' learning difficulties and misconceptions in freshman general and organic chemistry are presented in the students' terms, followed by the corresponding successfully applied, specific, concept-oriented, eclectic intervention strategies the author uses in order to overcome the difficulties. Based on longitudinal in-class observations, interpretive study, and analysis it is suggested that those students' misconceptions in freshman chemistry which are not interrelated logically and/or derived from one another are not prone to the general “concept mapping” approach and should be dealt with by using the appropriate, specific teaching strategy.

Children's conception of changes in the state of matter: From liquid (or solid) to gas

Abstract: This research examines children's (ages 9–15) conception of changes in the state of matter from liquid or solid to gas, as well as their understanding of the reversibility of this process. Children were tested for their ability to conserve matter, its identity, and its weight in tasks using evaporation of acetone and sublimation of iodine. It was found that children who recognized weight conservation in one of the tasks did not necessarily recognize the same in the second task. Students believed that gas has no weight, or that gas is lighter than the same material in its liquid or solid state. In addition, students who recognized weight conservation were not always aware of the reversibility of the process. Until the age of 12 specific perceptual input from the task (e.g., color) dramatically influenced students' responses to the conservation of weight task. The relationship between children's intuitive ideas about matter, as observed in this study, and their logical ability to conserve weight, as observed in this study, is discussed.

Motivation and studying in high school science

Abstract: Three groups of high school science students (college-bound and non-college-bound freshmen, college-bound juniors and seniors) completed surveys measuring their beliefs in the utility of four kinds of study strategies, three types of motivational orientation to science (task orientation, ego orientation, and work avoidance), their reported ability, and attitude toward science. Results indicated that belief in the usefulness of strategies requiring deep processing of information was more strongly positively related to task orientation than to ego orientation in all groups. For the younger groups only, task orientation was positively related to belief in the utility of surface-level strategies (e.g., rote memorization of facts). Task orientation proved to be the best predictor of student beliefs in deep-processing strategies, above and beyond that explained by perceived ability and interest in science. The implications of these findings for the current and future goals of science educators are discussed.

The effects of instruction on college nonmajors' conceptions of respiration and photosynthesis

Abstract: Students in a college nonscience majors' biology course took tests designed to reveal their conceptions of respiration and photosynthesis before and after course instruction. Even though most students had taken at least a full year of biology, serious misconceptions persisted. Most students gave definitions of respiration, photosynthesis, and food which were markedly different from those generally accepted by biologists. These incorrect definitions were associated with more fundamental misunderstandings about how plants and animals function. Most students could not explain how animal cells use either food or oxygen. They understood plants as vaguely analogous to animals, taking in food through their roots instead of mouths. Previous biology instruction seemed neither to improve student performance on the pretest nor to prepare them to master these conceptions during the course. Course instruction did improve student's understanding, but misconceptions persisted for many students. These results raise fundamental questions about the effectiveness of curriculum and instruction in current high school and college biology courses.

The effect of concept mapping on students' anxiety and achievement in biology

Abstract: The results of recent studies into the use of the concept mapping heuristic seem to demonstrate that meaningful learning results through its use in science classrooms. While this underscores the need to use more effective instructional strategies in science teaching, the issue of the intervening variable of anxiety in learning and science achievement, and the possible use of a metacognitive strategy in anxiety reduction have not been addressed. This study, therefore, sought to find out if the metacognitive strategy of concept mapping reduces anxiety and thereby enhances achievement in biology. A total of 51 (30 boys, 21 girls) senior secondary one (grade 10) students participated in this experiment. Two instruments—the Zuckerman Affect Adjective Checklist and the Biology Achievement Test—were used in pre- and posttest administrations to measure the treatment effect on anxiety and achievement, respectively. Findings support the stand that concept mapping is significantly more effective than the traditional/expository teaching strategy in enhancing learning in biology. In addition, it apparently reduces students' anxiety towards the learning of biology. A significant reduction of anxiety was noticed for male subjects.

Semantic Networking: The New Kid on the Block

Abstract: This article briefly describes the SemNet™ software and some of its uses as an educational and research tool, with emphasis on the similarities and differences between concept mapping and semantic networking. A semantic network captures (in part) each concept's position in psychological space, identifying both the other concepts to which it is connected and the nature of the links that bind them. Computer-based semantic networks differ from paper-and-pencil maps in that they are n-dimensional; each concept can be linked to many other concepts; relations are bidirectional; representations can include images, text, and sound; and nets can be very large. Disadvantages of SemNet™ networks include (a) the difficulties in obtaining a clear overview and (b) the homogeneous nature of the representations, in which all links look alike. Advantages include the ability to integrate ideas across a large knowledge base, the ease and rapidity of net creation, the ease with which elements (concepts, relations, or propositions) can be found within nets, and the utility of nets as self-study tools. Concept mapping and semantic networking are complementary strategies that can be used effectively in tandem to help students learn, to help teachers teach, and to support cognitive research.

The Rejection of Nonscientific Beliefs about Life: Effects of Instruction and Reasoning Skills.

Abstract: Nine hundred fifty-four students in a large university nonmajors biology course were pretested to determine the extent to which they held nonscientific beliefs in creationism, orthogenesis, the soul, nonreductionism, vitalism, teleology, and nonemergentism. To test the hypothesis that hypothetico-deductive reasoning skills facilitate movement away from nonscientific beliefs, the degree to which those nonscientific beliefs were initially held and the degree to which they were modified during instruction were compared to student reasoning level (intuitive, transitional, reflective). As predicted, the results showed that the less skilled reasoners were more likely to initially hold the nonscientific beliefs and were less likely to change those beliefs during instruction. It was also discovered that less skilled reasoners were less likely to be strongly committed to the scientific beliefs.

What does it mean to be an exemplary science teacher

Abstract: In order to provide a refreshing alternative to the majority of research reports, which malign science education and highlight its major problems and shortcomings, a series of case studies of exemplary practice was initiated to provide a focus on the successful and positive facets of schooling. The major data-collection approach was qualitative and involved 13 researchers in hundreds of hours of intensive classroom observation involving 20 exemplary teachers and a comparison group of nonexemplary teachers. A distinctive feature of the methodology was that the qualitative information was complemented by quantitative information obtained from the administration of questionnaires assessing student perceptions of classroom psychosocial environment. The major trends were that exemplary science teachers (1) used management strategies that facilitated sustained student engagement, (2) used strategies designed to increase student understanding of science, (3) utilized strategies that encouraged students to participate in learning activities, and (4) maintained a favorable classroom learning environment.

Attitude and behavior are correlates

Abstract: Science attitude scales can be expected to predict science-related behavior. But A-B correspondence can seldom be expected to approach the r value of 1.00. Attitude and behavior covary to the degree that valid measurement and mediating variables are considered: Individual differences of subjects (e.g., high versus low self-monitoring); the social situation (e.g., direct experience); cognitive factors (e.g., attitude accessibility in memory). Attitude and behavior are reciprocal; that is, attitude can follow behavior. Variables other than attitude, e.g., behavioral intention, previous behavior, and habit, may under some conditions better predict behavior. Also, a viable alternative to attitude testing may be direct appraisal of some science classroom behaviors through ethnomethodology.

Establishing an epistemological base for science teaching in the light of contemporary notions of the nature of science and of how children learn science

Abstract: The quality of science education is a pervasive concern in educational improvement efforts. This article examines two aspects of science education that have been identified as being of concern: Is the material presented in science classrooms representative of science “as it really is” and, secondly, what is the bearing of notions of “children's science” on curriculum reform? A review of the literature in both areas shows that educational theory has, so far, had little effect on classroom practice. An attempt is made to synthesize contemporary views on the tentative nature of science with a generative model of learning in science in order to establish a common epistemological base which could be used as a template for curriculum reform efforts.

The effect of simultaneous motion presentation and graph generation in a kinematics lab

Abstract: Real-time microcomputer-based Lab (MBL) experiments allow students to “see” and, at least in kinematics exercises, “feel” the connection between a physical event and its graphical representation. In Brasell’s (1987) examination of the sonic ranger MBL, a delay of graphing by only 20 seconds diminished the impact of the MBL exercises. This article describes a study where kinesthetic feedback was completely removed by only giving students visual replications of a motion situation. Graph production was synchronized with motion reanimation so that students still saw a moving object and its kinematics graph simultaneously. Results indicate that this technique did not have a substantial educational advantage over traditional instruction. Since Brasell and others have demonstrated the superiority of microcomputer-based labs, this may indicate that visual juxtaposition is not the relevant variable producing the educational impact of real-time MBL. Immediate student control of the physical event and its graphical representation might be what makes MBL effective and, in the case of kinematics laboratories, kinesthetic feedback could be the most important component of the MBC learning experience. Further studies are needed in order to clarify this point. Recent studies note that microcomputer-Based Laboratory (MBL) experiences are useful in helping students understand the relationships between physical events and graphs representing those events (Barclay, 1986; Mokros & Tinker, 1987; Thomton, 1986; Tinker, 1986). Research indicates that it is the real-time nature of MBL that accounts for the improvement in student achievement (Brasell, 1987). In other words, the effectiveness of the technique stems from the fact that the situation being examined by the student is actually occurring while the graphs relating to that event are being produced. This study began as an attempt to examine the educational impact of just the visual juxtaposition of a motion event with the corresponding kinematics graphs (the “VideoOraph technique”). The original intent was to show that merely seeing a recreation of the event in the form of a computer animation of videotaped images was sufficient to let students learn significantly more than the traditional kinematics lab experiments allow. This hypothesis proved to be incorrect. Although the VideoGraph students had higher scores than did the traditional groups, this difference was not large enough to be statistically meaningful.

The logic of university students' misunderstanding of natural selection

Abstract: Misunderstanding of the idea of evolution (natural selection) was assumed to occur because students were basing their explanations on the following mistaken assumptions: (1) variations in a population have little importance in its change process; (2) when nature changes, it is not at random. From these assumptions, hypotheses were developed and tested by analyzing the responses of 322 university sophomores (education majors) on an evolution problem “How could the bat have evolved wings?”. A classification system that was developed required judgments on whether a population or typological focus was used, whether the change process was open or closed to environmental information and how the selection process functioned. The contention that misunderstanding is logical was supported by acceptance of the following hypotheses: (1) students adopting a population focus also used a closed-change process; (2) students seeing change as more directed used less functional selection processes, with one exception; (3) students using acquired traits did not use a functional idea of selection.

Attaining Meaningful Learning of Concepts in Genetics and Ecology: An Examination of the Potency of the Concept-Mapping Technique.

Abstract: Studies have shown that in their study of biology, students perceive genetics and ecology to be difficult areas to learn. This has translated into rote learning of genetics and ecological concepts and reflected in poor performance in tests involving these concepts. Considering the importance of genetics and ecology to man's understanding of himself and his environment, there is a need to inquire into ways of ensuring that students attain meaningful learning of genetics and ecology rather than learning by rote. The efficacy of the concept-mapping strategy was tried out in this study with 138 predegree biology students. The results showed that the 63 students in the experimental group who employed the concept-mapping technique performed significantly better on the test of meaningful learning in genetics, t(136) = 16.01. p < 0.001, and ecology, t(136) = 12.27, p < 0.001, than their control group counterparts (N = 75). The implications of these results for teacher education in biology are addressed in the article.

Building an Organized Knowledge Base: Concept Mapping and Achievement in Secondary School Physics.

Abstract: Direct teaching of problem-solving methods to high school physics students met with little success. Expert problem solving depended upon an organized knowledge base. Concept mapping was found to be a key to organizing an effective knowledge base. The investigation of the effect of the degree of concept mapping on achievement was the purpose of this study. Six intact high school physics classes, taught by this investigator, took part in the study. Two classes were control groups and received standard instruction. Four classes received six weeks of concept-mapping instruction prior to the unit under study. Two of these four classes were the low-level treatment group and were required to submit concept maps at the conclusion of the instruction. The other two classes were the high-level treatment group and were required to submit concept maps at the beginning and at the conclusion of the unit under study. One class from each treatment group took a pretest prior to instruction. An analysis of the posttest results revealed no pretest sensitization. A one-way analysis of covariance indicated a significant main effect for the treatment level at the p < 0.05 level. A pair of single-df comparisons of the adjusted treatment means resulted in significant differences (p < 0.05) between the control group and the average of the treatment means as well as between the two experimental groups. It can be concluded that for this sample (upper-middle-class high school physics students) mapping concepts prior to, during, and subsequent to instruction led to greater achievement as measured by posttest scores.

Three Studies of Factors Affecting the Attitudes of Blacks and Females toward the Pursuit of Science and Science-Related Careers.

Abstract: This study involved the development of an instrument, the Science Career Predictor Scale (SCPS), which assesses seven factors thought to be involved with science career choices: teacher/counselor encouragement, participation in science-related hobbies and activities, academic self-image, science-related career interest, parental encouragement and support, the perceived relevance of mathematics and science, and mathematics and science ability. This instrument was administered to a sample of 522 middle and high school students, and a sample of 185 students from an historically black university, and the effects of such factors as sex, race, personal acquaintance with a scientist, and type of community (rural or urban) on the above-mentioned variables were ascertained using a multivariate analysis of covariance with age as the covariate. A separate study on a sample of 81 high school students looked at race and gender differences in critical thinking abilities as measured by the Watson-Glaser Critical Thinking appraisal, and how these abilities correlated with scores on the Science Career Predictor Scale. These studies produced several significant findings. Female subjects did produce significantly lower scores on the career interest factor. Black students actually had significantly higher science-career preference scores than their white counterparts. However, blacks scored significantly lower on the measure of critical thinking ability. Across both races and both sexes, however, the major factor affecting science-related career decisions appears to be personal contact with a scientist. The implications of these findings are discussed, along with possible strategies for increasing the participation of these groups in science.

Comprehension evaluation and regulation in learning from science texts

Abstract: Metacognitive variables influence students' learning from science texts. This article deals with the comprehension monitoring abilities of secondary school science students, one of the areas of metacognition which has drawn considerable attention from researchers. The aims of the study are, in particular: (a) to know the extent to which comprehension is monitored by secondary science students as revealed by inconsistency detection in manipulated science texts, and (b) to identify the strategies used to regulate comprehension by the students who detect the inconsistencies. The results indicate that knowing that one understands or fails to understand science texts could be as important a problem as understanding proper. Besides, some incorrect regulatory strategies used by students who notice the inconsistencies in the texts are identified. These could also have an annoying influence in the regulatory behavior of students when studying regular science texts.

Concept maps as a heuristic for science curriculum development: Toward improvement in process and product

Abstract: This article outlines the use of concept maps as a tool for science curriculum development and discusses the changes that occur in the teacher's view of the curriculum with successive revisions of the maps. Although we have used concept mapping in curriculum development with teachers from grades 4–8, we describe in detail the maps created by sixth-grade teachers. We analyzed the maps using three criteria: hierarchical structure, progressive differentiation, and integrative reconciliation. Changes made to the maps during the revision process, including additions and deletions, show increased clarification of both the concepts to be learned and the connections between them. Consecutive map revisions show the development of a cohesive conceptual grade-six science curriculum. The use of concept maps can help science teachers develop science curriculum that is hierarchically arranged, integrated, and conceptually driven.

A study of student perceptions of physics teacher behavior

Abstract: This study investigates student perceptions of the behavior of physics teachers in relation to some other variables in the classroom situation. The research was carried out as a Dutch option of the Second International Science Study. Data were gathered in 65 classrooms of physics teachers with pupils 15 years old. Some of the teachers (21) used the new PLON curriculum and the others a traditional one. Student perceptions of teacher behavior were measured with a questionnaire based on the interpersonal theory of Leary (1957). The aspect of behavior measured is called interactional teacher behavior. We found remarkably high correlations between student perceptions of teacher behavior and affective outcomes such as appreciation of the lessons and motivation for the subject matter. Also, the correlations with cognitive outcomes measured with a standardized international test were significant. It appears that some differences exist between teacher behaviors that are favorable for high cognitive outcomes and behaviors favorable for high affective outcomes in physics lessons. Hardly any differences were found in teacher behavior between teachers using the traditional and the new physics curriculum.

On the concept “chemical equilibrium”: The associative framework

Abstract: Word associations were used to map the conception of high school students concerning the concepts “chemical equilibrium” and “equilibrium.” It was found that the preconception of the two concepts was differentiated on noncritical dimensions; “equilibrium” being associated with everyday life experiences and “chemical equilibrium” with general chemical concepts. After studying the subject of chemical equilibrium at school the two concepts merged towards one, i.e., becoming synonymous. This can provide an explanation for misconceptions associated with chemical equilibrium via the transfer of static attributes from “equilibrium” to the dynamic “chemical equilibrium”.

Using a computerized concept mapping program to assess preservice teachers' thinking about effective teaching

Abstract: Concept mapping with Learning Tool, a computerized mapping program, was used to assess changes in the content and organization of 17 preservice teachers' concept maps for the topic of effective teaching. Preservice teachers in their senior year of an early childhood teacher education program constructed and revised concept maps with a partner. They entered reflections on each mapping experience into their reflective journals, developing implications for teaching. Analysis of the concept maps revealed that these students had a primary concern with classroom management throughout the year, linking diverse information to that concept. They evidenced detailed and diverse understandings under the labels of knowledge and organization. Professionalism was a common item, though it was less well developed. Their reflective journals indicated that these students moved from describing emotional reactions to using the computer program as a basis for reflection on the teaching/learning process. This study illustrates how concept mapping can be useful in describing students' evolving constructions of knowledge in a particular subject area, and in promoting reflection.

The effects of microcomputer‐based laboratory exercises on the acquisition of line graph construction and interpretation skills by high school biology students

Abstract: Effects of microcomputer-based laboratories and level of cognitive development on tenth-grade biology students' ability to construct and interpret line graphs was investigated. Fortysix students enrolled in general biology classes at a rural high school volunteered to participate in the study. These students were administered instruments to assess level of cognitive development and line-graphing ability. Ten students that scored between zero and three and ten students that scored between six and ten on the graphing assessment were chosen to participate in the study. The 20 students were then assigned to either experimental or conventional groups to achieve a matched design with relation to gender and line-graphing ability. Statistical analysis of the data indicated no effect due to instructional method on graph-interpretation abilities. An instructional effect was demonstrated for graph-construction tasks (p < 0.10) with the conventional group outperforming the microcomputer-based laboratory group. Effect sizes of −1.01 and 0.48 were found for graph-construction and -interpretation skills, respectively. Effects related to cognitive development were indicated with those students classified as high cognitive development outscoring those classified as low (p < 0.10) This was true for both graph-construction and graph-interpretation tasks. No two-way interactions were found.

Determinants of middle school students' intention to enroll in a high school science course: An application of the theory of reasoned action

Abstract: The determinants of intentions to enroll in a high school science course were investigated, using the theory of reasoned action, among earth science students enrolled in a middle school located in a middle-income, suburban community in central Texas. The sample consisted of 5 of 14 eighth-grade earth science classes, randomly selected for this study. Classes contained Caucasian and minority students, male and female, of differing science abilities who were grouped according to general academic abilities—basic, average, and gifted and talented. The prediction of behavioral intention of sample participants was tested using four external variables, attitude, and subjective norm (Direct-Full Effects Model), attitude and subjective norm alone (Direct-Reduced Effects Model), and disaggregated data on attitude and subjective norm (Indirect Effects Model). Results of the study revealed attitude and subjective norm to be the sole predictors of behavioral intention for the aggregated data, but to be differentially effective for groups formed on the basis of sex, ethnicity, general ability, and science ability. Evidence is presented to show that the relative contributions of attitude and subjective norm to the prediction of behavioral intention varies among students depending upon their sex, ethnicity, general ability, and science ability. Results of the study are discussed in terms of increasing the enrollment of all students in elective science courses.