Secondary science teachers' attitudes toward and beliefs about science reading and science textbooks

Science textbooks are dominant influences behind most secondary science instruction but little is known about teachers' approach to science reading. The purpose of this naturalistic study was to develop and validate a Science and Reading Questionnaire to assess secondary science teachers' attitudes toward science reading and their beliefs or informed opinions about science reading. A survey of 428 British Columbia secondary science teachers was conducted and 215 science teachers responded. Results on a 12-item Likert attitude scale indicated that teachers place high value on reading as an important strategy to promote learning in science and that they generally accept responsibility for teaching content reading skills to science students. Results on a 13-item Likert belief scale indicated that science teachers generally reject the text-driven model of reading, but they usually do not have well-formulated alternative models to guide their teaching practices. Teachers have intuitive beliefs about science reading that partially agree with many research findings, but their beliefs are fragmented and particularly sketchy in regard to the cognitive and metacognitive skills required by readers to learn from science texts. The findings for attitude, belief, and total scales were substantiated by further questions in the Science and Reading Questionnaire regarding classroom practice and by individual interviews and classroom observations of a 15-teacher subsample of the questionnaire respondents.     

The science/technology interaction: Implications for science literacy

Science literacy includes understanding technology. This raises questions about the role of technology in science education as well as in general education. To explore these questions, this article begins with a brief history of technology education as it relates to science education and discusses how new conceptions of science and technological literacy are moving beyond the dichotomies that formerly characterized the relationship between science and technology education. It describes how Benchmarks for Science Literacy, the National Science Education Standards, and the Standards for Technological Literacy have been making a case for introducing technology studies into general education. Examples of specific technological concepts fundamental for science literacy are provided. Using one example from the design of structures, the article examines how understanding about design (i. e., understanding constraints, trade‐offs, and failures) is relevant to science literacy. This example also raises teaching and learning issues, including the extent to which technology‐based activities can address scientific and technological concepts. The article also examines how research can provide guides for potential interactions between science and technology and concludes with reflections on the changes needed, such as the creation of curriculum models that establish fruitful interactions between science and technology education, for students to attain an understanding of technology. © 2001 John Wiley & Sons, Inc. J Res Sci Teach 38: 715–729, 2001     

Young children's motivational beliefs about learning science

For learning science, motivational beliefs such as confidence in one's science abilities and liking of science are associated with current and future science achievement, as well as continued interest in science classes and careers. However, there are currently no measures to test young children's motivational beliefs related to science learning. To meet this need, we developed the Puppet Interview Scales of Competence in and Enjoyment of Science (PISCES). We piloted PISCES with 113 kindergarten children in public schools participating in the Scientific Literacy Project (SLP). Factor analysis supported the multidimensional structure of young children's self-related beliefs about learning science. PISCES scales measured Science Liking, Science Competence, and Ease of Science Learning. Correlations among PISCES scales and achievement subtests provided evidence of PISCES's validity. Children's motivational beliefs varied as a function of length of time spent learning science, with competence beliefs associated positively with science experience. There were no gender differences.     

Learning in science project (teacher development): The framework

The Centre for Science and Mathematics Education Research at the University of Waikato is now undertaking the fourth Learning in Science Project, LISP(Teacher Development). The project builds on the findings of the previous three projects on the nature of learning and how to improve learning of science in classrooms. This two-year project is investigating the process of teacher development (as change in behaviour and beliefs) in the context of two kinds of teacher courses that acknowledge and take into account teachers’ existing ideas. This paper summarises the planning done for the first phase of the project as detailed in Bell, Kirkwood and Pearson (1990). Specializations: learning theories, curriculum development, equity issues. Specializations: science education, teacher professional development.     

Knowing,researching, and reporting science education: Lessons from science and technology studies

Recent research in science and technology studies changed the way we understand science as it is practiced—that is, how scientific knowledge emerges from social, natural, social, political, cultural, historical, and economic contingencies of scientific work. Many science educators agree that students should learn not only science but also about science. In this article, we (a) outline important findings, research methods, and ways of reporting research that emerged from science and technology studies; and (b) show how familiarity with science and technology studies research can provide science educators with valuable insights about curriculum design and research on learning. We conclude that science and technology studies can serve as a resource to science education and that there is a potential for conducting collaborative work between science education and science and technology studies. Such collaborations have the potential to yield better theories about how people become competent in science from childhood to adulthood. © 1998 John Wiley & Sons, Inc. J Res Sci Teach 35: 213–235, 1998.     

Why ‘science for all’ is only an aspiration: staff views of science for learners with Special Educational Needs and Disabilities

Teacher and support staff perceptions of science learning, and specifically engagement with science outreach, by pupils with Special Educational Needs and Disabilities (SEND) were ascertained through questionnaires. The responses indicated that science is seen as serving distinctive learning purposes when undertaken by learners with SEND. Staff who accompanied SEND pupils to science outreach events expressed more positive views about separate outreach events for SEND pupils than other respondents, in line with current policy expectations of differentiated classroom practice. The desire for different provision for SEND learners also appeared to be associated with the staffs’ pastoral concerns about their pupils and their reluctance to let their pupils ‘fail’. The data suggests that, despite policy and legislative reform in the UK, curriculum science is still viewed primarily as a means to career progression for an able minority, rather than as an educational and cultural entitlement for all.     

Graduate Experience in Science Education: the development of a science education course for biomedical science graduate students

The University of Rochester's Graduate Experience in Science Education (GESE) course familiarizes biomedical science graduate students interested in pursuing academic career tracks with a fundamental understanding of some of the theory, principles, and concepts of science education. This one-semester elective course provides graduate students with practical teaching and communication skills to help them better relate science content to, and increase their confidence in, their own teaching abilities. The 2-h weekly sessions include an introduction to cognitive hierarchies, learning styles, and multiple intelligences; modeling and coaching some practical aspects of science education pedagogy; lesson-planning skills; an introduction to instructional methods such as case studies and problem-based learning; and use of computer-based instructional technologies. It is hoped that the early development of knowledge and skills about teaching and learning will encourage graduate students to continue their growth as educators throughout their careers. This article summarizes the GESE course and presents evidence on the effectiveness of this course in providing graduate students with information about teaching and learning that they will use throughout their careers.     

Knowledge engineering: An alternative approach to curriculum design for science education at a distance

Most of the curriculum design models within the technical-scientific approach utilise the rational and sequential process of designing and inter-relating the various elements of the design process. While this procedure may be efficient and adequate for conventional education in which the designers are professional science educators, there is doubt if it satisfies the particular needs of distance education. The experience accumulated through a multi-disciplinary team approach to distance learning courseware development for higher education at the University of Southern Queensland Distance Education Centre motivated this study which primarily focused on a search for an alternative approach to curriculum development with a more satisfactory functional value. Using selected units in Engineering as a focus, an experiment was designed in which a variant of the classical Wheeler model was used. This paper reports the results of this experiment. The implications for contemporary curriculum development initiatives in science especially within distance education settings are pointed out. Specializations: science education, learning strategies, curriculum development, instructional design, research and development in distance education. Specializations: Cognitive Science, curriculum development, instructional design, expert systems, research and development in distance education. Specializations: science education, learning strategies, curriculum development, instructional design, research and development in distance education.     

Teacher perceptions of professional development needs and the implementation of the K-6 science and technology syllabus

This study examines teacher perceptions regarding professional development practices used in a region of the NSW Department of School Education to support the implementation of the K-6 Science and Technology Syllabus. The findings from a survey of 97 teachers indicate that teachers have a preference for ‘traditional’ models of in-service which may not bring about significant changes. Teachers also perceive that change is brought about through the influence of external factors such as in-service and resources which are not directly the responsibillity of individual teachers. This contrasts with the perception that the inability to change is due to internal personal qualities. Specializations; K-6 teacher education in science and technology education, children's learning in science and technology.     

Teacher beliefs about learning and teaching in primary science and technology

It is argued that the introduction of many new curricular with their associated teaching practices have failed because the beliefs, views and attitudes of teachers have been ignored. This paper reports the implications of the initial belicfs of primary school teachers involved in a professional development program about science and technology education. In particular, a mismatch between teachers views of learning and teaching is identified and analysed. Specializations: Science education, professional development Specialisation: primary science and technology education     

Changes in perceived attitudes toward the goals for science instruction in schools

Four goal areas were identified by the Project Synthesis research team, including science for affecting daily living, science for resolving societal issues, career awareness in science/technology, and science necessary for further study. In 1976 15 science educators across the U.S. agreed to administer a short, one-page assessment form to at least 50 members of service clubs or community groups in their respective communities. This survey asked the respondents about the relative importance for the four goal areas across the K-12 curriculum (K-3, 4–6, 7–9, and 10–12). The 1976 survey was repeated with similar respondents during 1980, 1984, and 1986. The results indicate that the view of the importance of science as preparation for studying science further is perceived as a most important goal which changes little across grade levels or time. During the 1976–86 period respondents rated the importance of science for improvement of daily living as significantly more important; in fact, its importance was perceived almost as great as academic preparation. Similarly, science for the resolution of societal issues and for meeting career-awareness goals were viewed as significantly more important in 1986 than was the case in 1976. The respondents survey in 1984 and 1986 ranked science goals for resolving societal issues as more important than those associated with information useful in daily living. There is no way of determining how much of this change of perception is caused by professionals and/or forces at work at a given point in time. Nor is it clear how the information can or should be used to plan school programs.     

Interactive learning and technology in the US science and mathematics reform movement

This article presents an overview of the science/mathematics reform movement in the secondary/elementary schools and higher education institutions of the United States. It describes the research and views of educational practitioners regarding the need for change, as well as the particular changes which appear to be required. Emphasis is placed on the roles of interactive learning and technology in meeting reform goals.
Details of a recently completed curricular innovation project in science and mathematics are provided. Funded by the National Science Foundation, the project brought five faculty in the natural sciences together with a learning theorist at Florida Community College at Jacksonville, a large, multi-campus, public institution. The group developed and taught two basic integrated science/mathematics courses in which cooperative and discovery learning, supported by multimedia technology and distance learning, were major components. Details of results are provided as they relate to meeting the goals of the reform movement.     

Teaching portfolios: Developing quality learning in pre-service science teachers

The premise that underlies the pre-service science teacher education program at Monash University is the need to focus on the nature of learning in ways that encourage student-teachers to reconsider their conceptions of learning and how this relates to their view of teaching. The purpose of teaching portfolios is to act as a prompt for student-teachers to reconsider these conceptions and as a way of helping them to better articulate their professional knowledge. The Science (Stream 3) student teachers construct a portfolio of teaching strategies, episodes, ideas, etc. that demonstrate how they see their role as science teachers. The portfolio is ungraded, openended and organised as a dynamic assessment task, not just a static end product. This paper reports on student-teachers' understanding of, and approach to portfolios as they come to understand its purpose and value. Specializations: chemistry and science education, technology and industry links with science curriculum Specializations: science education, reflection, curriculum and evaluation     

Silencing of voices in a Swedish science classroom

From a sociocultural perspective, I discuss data from a Swedish science classroom presented in María Gómez’s article “Student Explanations of their Science Teachers’ Assessments, Grading Practices, and How they learn Science”. In this discussion, I focus on the need to change existing conceptions of assessment in the teaching and learning of science. Next, I talk about the importance of taking into consideration the dialectic between agency and passivity as filters in order to understand what student silence may signify in science classes as well as in relation to their perceptions of assessment. I conclude with the importance of the teacher’s role in developing formative assessment, along with the challenges in developing assessments which transform science education into a relevant field of knowledge for both students and society at large.     

Asia Pacific science education in a knowledge society

Science education, since the end of the nineteenth century has been a formal vehicle to ensure the perpetuation of scientific knowledge necessary for general scientific literacy and the creation of a society of scientists. However, since then, beliefs about knowledge and knowing have changed from science being described as being just a pile of chronologically documented facts, through the dynamic growth of scientific knowledge as explained by Kuhn in his Structure of Scientific Revolutions, to the present twenty-first century concept of knowledge societies by which new scientific knowledge is being interpreted. Science education perspectives in relation to teacher education and pedagogies need to be frequently revisited. Indeed, many nations in the Asia-Pacific region are doing just that. How then is the teaching and learning of scientific knowledge in the region? This article will review and compare research related to science achievement, quality of science education and approaches to teaching science in the Asia-Pacific region in particular five nations, in an attempt to answer this question.     

Towards an indigenous science curriculum

The recent development of a national science curriculum in Māori opened up space to contest whose knowledge and whose ways of knowing are included. This paper outlines the background to the curriculum development work in Aotearoa New Zealand with respect to the indigenous Māori people and science education. Concern is expressed about the fitting of one cultural framework into another and questions are raised about the approach used in the development of the science curriculum. Further research in the area of language, culture and science education is discussed along with how Māori might move forward in the endeavour of developing a curriculum that reflects Māori culture and language. This paper forms part of an MEd thesis. For a fuller analysis of the development of “Te Tauākī Marautanga Pūtaiao: He Tauira” (Draft National Science Curriculum in Māori) see McKinley (1995) in the references. See alsoSAMEpapers 1995 (Hamilton, New Zealand: Centre for Science, Mathematics and Technology Education, University of Waikato).     

How can we find out what 3 and 4 year olds think? New approaches to eliciting very young children's understandings in science

This paper outlines work in progress on a study which is investigating what children understand about natural and processed materials and how scientific learning on the topic could be extended and reinforced in the home. Four different interview schedules for eliciting children's understanding were developed and tried out. Children's understandings prior to each of the four units, and at the conclusion of the teaching program were documented through individual interviews. Family interviews were also conducted prior to and at the conclusion to the teaching. In this paper the difficulties associated with researching young children's thinking are explored. The rationale for a storytelling context for the interviews is presented, and there is a preliminary discussion on the effectiveness of the methodology utilised. Specializations: early childhood science education; the Curriculum Corporation K-3 Science Program. Specializations: primary science education, teacher education in science, adult experiences of science and technology; the K-3 Science Program.     

Experientially learning how to communicate science effectively: A case study on decoding science

The need for science communication programs is matched with the need for program evaluation. This case study is an evaluation of the “Decoding Science” program (DSP) [Rodgers et al. (2018). Science Communication, 40(1), 3–32], a science communication training program, and examines key experiential-learning themes [Kolb, D. A. (1984). Experiential learning: Experience as the source of learning and development. Englewood Cliffs, NJ: Prentice-Hall]. Specifically, we discuss the program's emphasis on learning that science communication is a process that (a) is continual, (b) involves conflict resolution, (c) requires adaptation to the world, (d) requires environmental interaction, and leads to (e) knowledge creation. Additionally, we discuss our analysis of student feedback. Results suggest that the DSP successfully utilizes experiential learning to facilitate the learning of science communication techniques and that future evaluations can lead to the development and improvement of science communication training programs.