Belief, Knowledge, and Science Education

Epistemological questions about the nature of knowledge and belief underlie many of the controversial issues fundamental to research and practice in science teaching and learning. In an effort to bring some clarity to questions of knowledge and belief embedded within science education research and teaching, we first describe the distinctions drawn between knowledge and belief in both philosophy and educational psychology, each of which have shaped the various definitions employed within science education. This discussion is followed by an examination of the distinctions drawn between knowledge and belief employed by three groups of science educators: the traditional distinctions of the foundationalists that are co-opted by researchers focusing on teacher thinking/cognition, the nonfoundational epistemology of the fallibilists and the evolution educators working from this framework, and the radical constructivists who react to and attempt to move past the limitations of these other positions. In this analysis, we explicate the different ways in which knowledge and belief are understood and operationalized in a broad spectrum of research, we describe the theoretical and philosophical assumptions underlying these approaches, and we explore the important areas of contention (both theoretical and empirical) surrounding each of these distinctions.     

理科教师的科学本质观对科学教育的影响

人们对科学本质的认识经历了由科学的“真理观”向科学的“建构观”的转变。不同的科学本质观将直接影响着教师对科学教育目标的不同理解,对科学知识的不同选择,对教学主题的不同设计、教学话语的不同使用,对学生学习的不同评价。教师不同的科学本质观及其教学行为影响着学生的科学本质观的形成,影响着学生对科学内容的理解以及看待问题的思维方式。     

Learning to teach science for all in the elementary grades: What do preservice teachers bring?

Implicit in the goal of recent reforms is the question: What does it mean to prepare teachers to teach “science for all”? Through a teacher research study, I have encountered characteristics that may assist prospective elementary teachers in developing effective, inclusive science instruction. I describe these strengths, link them to requirements for teaching, and suggest how science teacher educators might draw on the strengths of their own students to support teaching practices aimed at universal scientific literacy. My conceptual framework is constructed from scholarship concerning best practice in elementary science education, as well as that which describes the dispositions of successful teachers of diverse learners. This study is based on a model of teacher research framed by the concept of “research as praxis” and phenomenological research methodology. The findings describe the research participants' strengths thematically as propensity for inquiry, attention to children, and awareness of school/society relationships. I view these as potentially productive aspects of knowledge and dispositions about science and about children that I could draw on to further students' development as elementary science teachers. © 2002 Wiley Periodicals, Inc. J Res Sci Teach 39: 845–869, 2002     

New trends in science education

I intend to review the main contributions from the impressive developments made in science education research during the last decade. These developments have made the construction of a coherent body of knowledge possible allowing us to expect a significant improvement in the science teaching/learning process. I shall refer, in particular, to the new trends in science education research, both in the domain of science learning and science teacher‐training.     

Reversing the Downward Spiral of Science Instruction in K-2 Classrooms

This study investigated the extent to which teacher professional development led to changes in science instruction in K-2 classrooms in rural school districts. The research specifically examined changes in (a) teachers’ content knowledge in science; (b) teachers’ self-efficacy related to teaching science; (c) classroom instructional time allotted to science; and (d) instructional strategies used in science. The study also investigated contextual factors contributing to or hindering changes in science instruction. Data sources included a teacher survey, a self-efficacy assessment, content knowledge tests, interviews, and classroom observations. After one year in the program, teachers showed increased content knowledge and self-efficacy in teaching science; they spent more instructional time on science and began using different instructional strategies. Key contextual factors included curricular demands, resources, administrative support, and support from other teachers.     

Observing the Indicators of Technological Pedagogical Content Knowledge in Science Classrooms: Video-Based Research

The purpose of the study was to observe the indicators of science teachers’ technological pedagogical content knowledge (TPACK) using a video-based research method. The study was conducted with four in-service science teachers who taught at a school that offered tablet-based education in primary and secondary levels. Data sources included video-recorded classroom teaching sessions and pre- and post-video teacher interviews. In addition to the in-depth contextual information provided, the findings from the qualitative analysis of teacher cases revealed indicators of teachers’ TPACK in their lesson design and actual teaching processes. Design indicators included technology selection, curriculum planning, lesson preparation, and assessment. Actual teaching indicators included lesson entry behaviors, teaching methods and strategies, technology-enhanced classroom management, troubleshooting, and assessment.     

Preparing teachers as researchers in courses on methods of teaching science

The four standards for professional development of teachers of science from the National Science Education Standards (NRC, 1996) provided a frame for reflection upon ways in which prospective teachers engaged in research in my courses on methods of teaching science. Students learned both science content and science pedagogy by inquiry. An extended research project helped students to integrate knowledge of science, learning, pedagogy, and students, and to apply that to teaching science. Students built knowledge, skills, and attitudes for lifelong learning by participating in a research festival and presenting at conferences. I designed this science-teaching methods course in the context of a teacher education program that is attempting to implement reform approaches to instruction. © 1998 John Wiley & Sons, Inc. J Res Sci Teach 35: 791–809, 1998.     

Examining the Beliefs and Practices of Four Effective Australian Primary Science Teachers

With trends across many countries still indicating the decline of student interest in school science and diminishing numbers of students studying science beyond the compulsory years, it seems that the field remains in crisis. To address these unfortunate trends, there needs to be a greater emphasis on science education research that highlights the good news stories. For example, what are science teachers actually doing in their classrooms to increase student interest and understanding in science? This article focuses on the science teaching beliefs and practices of four Western Australian primary school teachers. The teachers were nominated by a professional colleague as effective practitioners. The study involved gathering information from classroom observations and teacher interviews to provide background information to assist in developing understandings of these teachers and their science teaching. This article reports on the initial findings drawn from Deanne A, Kate B, Lisa C and Rebecca D. Their practices were organised into the following six categories: classroom environment; conceptual knowledge and procedural skills; teaching strategies and approaches; student-specific considerations; teacher-specific considerations; and context-specific considerations. In examining the components contributing to these categories, it was evident that the teachers’ beliefs, as well as the contextual factors inherent in each classroom environment, influenced how and why they teach science in the ways they do.     

Selective traditions in group discussions: teachers’ views about good science and the possible obstacles when encountering a new topic

There is an ongoing discussion about what content that should be taught in science education and there are different views among teachers about what represent good science content. However, teachers are not isolated individuals making their own interpretations, but are part of institutionalised systems building on patterns in the selection of teaching goals and content. Earlier research shows that teachers teach in alignment with different selective traditions, which can be understood as well-developed teaching habits. Individual teachers seem to develop their personal habits on the basis of the contextual situations created by earlier generations of teachers. In order to find out which content teachers find representative for science education, we asked nine teachers to take part in group interviews to talk about what they value as “good” science content. The participants were grouped according to their selective traditions expressed in earlier studies. The method was used to dynamically explore, challenge and highlight teachers’ views. The starting point for the group discussions is national tests in science. In Sweden, national tests in biology, physics and chemistry were introduced in secondary school science (year 9) in 2009. One overarching aim of these tests is to support the implementation of the science curricula and to include for example knowledge about socio-scientific issues (SSI). The content of the tests can consequently be seen as important for teachers to consider. The findings show that ‘resistance’ to including SSI is not just an issue for individual teachers. As individuals teachers can create many kinds of obstacles, but still be interested in integrating SSI in their science teaching. However, in group discussions the teachers tend to collectively adopt the scientific rational discourse. This discourse is what joins them and creates their common identity as science teachers. In turn, they seek to free scientific knowledge from social knowledge and thereby make assessment easier.     

Researching balance between cognition and affect in science teaching and learning

This paper is based on findings from a three year collaborative action research project on classroom teaching and learning. The research, which involved 33 teachers, over two thousand students from six schools, and the authors, centred on exploring how various features of the classroom context influence teaching and learning processes. We interpret project findings as indicating the importance of balance between cognition and affect for effective teaching and learning. We advance the notion of challenge as a way of conceptualising this balance. Challenge comprises a cognitive/metacognitivedemand component and an affectiveinterest component. Nine major features of a teaching/learning event were found to interact to influence these cognitive and affective components of challenge. Specializations: Collaborative research on science teaching and learning; staff development and school improvement; quality of science education. Specializations: Learning and teaching science; pre-service teacher education. Specializations: teacher development in science education; technology education. Specializations: Science and teachnology curriculum, environmental education, educational disadvantage. Specializations: learning theory, probing of understanding, conceptual change.     

Teachers' Conceptions of Education: A Practical Knowledge Perspective on 'Good' Teaching

Research on teachers' practical knowledge is considered to be an alternative to several other research approaches to teaching which study teaching from a limited point of view and from an outsider's perspective, often with the aim of exerting control over teachers. It is argued that research on teachers' practical knowledge takes into account in a better way what really matters in teaching because it emphasizes the knowledge and beliefs of teachers themselves about teaching. In this study, the issue of 'good' teaching is highlighted from a perspective on teaching based on teachers' practical knowledge. The conceptions of education of eight experienced teachers were investigated with a multi-methodical approach. Teachers' conceptions of education consist of their views on the objectives of education, the contents of the curriculum, and the role of the teacher and the students in the teaching and learning process. Several contextual factors and teachers' interpretations of these factors seem to exert influence on teachers' conceptions of education, such as the schools in which they work, the characteristics of the students and subjects they teach, and general developments in society. It is concluded that it is difficult to give a precise definition of good teaching from a practical knowledge perspective because of the personal and context-embeddedness of teachers' practical knowledge. However, the results indicate that research on teachers' practical knowledge adds new information to the discussion of good teaching when compared with the results of more traditional research approaches to teaching.     

教师认知研究的综述与展望

教师认知研究是教师教育研究的重要内容之一,体现了教学研究范式从关注教师行为到关注教师思维的重大转变。教师认知研究主要包括教师决策、教师知识和教师信念研究。这些研究的相关成果有助于提高教学效能,促进教师专业发展,推动教学改革。     

Investigation of the science achievement models for low and high achieving schools and gender differences in Turkey

A science achievement model was separately investigated for students in low and high achieving schools (LAS and HAS) in Turkey. Then, gender differences based on variables that significantly contributed to each achievement model were investigated. The student-level variables that were under investigation for multiple regression analyses include attitudes toward science, epistemological beliefs, metacognition, views on science teaching, and socioeconomic status (SES). The science achievement scores of students on a nationwide exam were used to measure science achievement. Both for LAS and HAS, two schools were selected. Results were reported for 241 and 320 students in LAS and HAS, respectively. According to the results, self-concept in science, knowledge of cognition, SES, importance of science, gradual learning, and views on lab work significantly contributed to the science achievement model in LAS. On the other hand, self-concept in science, SES, gradual learning, studying, and learning science in school significantly contributed to the science achievement model in HAS. Results also revealed that girls outperformed boys on knowledge of cognition and importance of science in LAS. Moreover, girls scored higher than boys on gradual learning and studying in HAS. According to these findings, implications for science education were discussed.     

Proposing an Operational Definition of Science Teacher Beliefs

Much research has shown that a science teacher’s beliefs are related to their teaching practice. This line of research has often defined “belief” epistemologically. That is, beliefs are often defined relative to other mental constructs, such as knowledge, dispositions, or attitudes. Left unspecified is the role beliefs play in cognition and how they come to influence science teachers’ classroom practice. As such, researchers and science teacher educators have relied on an (at times, implicit) assumption that there is a direct causal relationship between teachers’ beliefs and classroom practice. In this paper, we propose an operational, as opposed to epistemological, definition of belief. That is, we are explicit about the role a belief plays in science teachers’ cognition and how that leads to classroom practice. We define a belief as a mental representation that influences the practice of a teacher if and only if the belief is active in cognition. We then turn our attention to two limitations in the literature on that have arisen via previous definitions and assumptions regarding science teacher beliefs, showing how defining beliefs operationally helps think about these issues in new ways. The two limitations surround: (1) the difficulty in precisely delineating belief from knowledge; and (2) the interconnectedness of beliefs such that they draw meaning from one another. We then show how our definition of beliefs is congruent with other models of teacher cognition reported in the literature. Finally, we provide implications arising from this definition of belief for both science teacher educators and those who conduct research on the beliefs of both preservice and in-service science teachers.     

Developing preservice teachers' pedagogical reasoning ability

Teachers not only need to develop a knowledge base for teaching, but also should be able to make reasoned decisions regarding their classroom science teaching. Preservice teachers need opportunities to begin developing their pedagogical reasoning ability as part of their undergraduate education so that science teaching in primary schools is based on sound reasoning. This paper, using a case study methodology, reports on the initial pedagogical reasoning ability of second-year preservice primary teachers. By completing a problem-based science education topic, these preservice teachers had the opportunity to explore all stages in the pedagogical reasoning process. Preservice teachers initially demonstrated limited pedagogical reasoning ability, but as a result of the framework provided in the problem-based approach, they were able to refine their reasoning ability. Through a combination of group work and individual research, the preservice teachers were able to integrate their science knowledge, curriculum knowledge and knowledge of learners and apply this to a peerteaching situation and in the process develop their pedagogical reasoning skills.     

Overlooked aspects in the education of science professionals: Mentoring,ethics, and professional responsibility

Science as profession is generally defined narrowly as research. Science education as preparation for a profession in research is usually perceived as course work and laboratory training, even though the necessary knowledge and skills to pursue a research career are more extensive and diverse and are learned in one-on-one interaction with mentors. A complete education of science professionals includes the values, ethical standards and conventions of the discipline since they are fundamental to the profession. Mentoring and education in the responsible conduct and reporting of research and in the ethical dimensions of science are among the professional responsibilities of scientists and need to be discussed as part of science education. Moreover, science as an enterprise is much more than research and includes a number of other components, including science teaching, science journalism, and science policy. Each of these contributes to the nature of science and its role in society.     

The Development of Prospective Secondary Biology Teachers PCK

In order to understand how prospective teachers develop knowledge for teaching, researchers must identify the types of knowledge that are integral to effective science teaching. This case study investigated how 4 prospective secondary biology teachers’ science teaching orientations, knowledge of science learners, and knowledge of instructional sequence, developed during a post-baccalaureate teacher education program. Data sources included a lesson planning task and two interview-observation cycles during the participants’ year-long internship. Over the course of a year, the participants’ science teaching orientations were based primarily on their K-16 learning experiences, and were robust and highly resistant to change. The prospective teachers became more aware of student learning difficulties, and therefore, developed more elaborated knowledge of the requirements of learning. They consistently sequenced instruction in ways that gave priority to transmitting information to students. Prospective teachers’ development of knowledge of student understanding of science and instructional sequence were congruent with their science teaching orientations. Implications are given for teacher education and future research.     

Excavating silences and tensions of agency|passivity in science education reform

I reflect on studies by Rodriguez and Carlone, Haun-Frank, and Kimmel to emphasize the ways in which they excavate silences in the science education literature related to linguistic and cultural diversity and situating the problem of reform in teachers rather than contextual factors, such as traditional schooling discourses and forces that serve to marginalize science. I propose that the current push for top-down reform and accountability diminishes opportunities for receptivity, learning with and from students in order to transform teachers’ practices and promote equity in science education. I discuss tensions of agency and passivity in science education reform and argue that attention to authentic caring constitutes another silence in the science education literature. I conclude that the current policy context positions teachers and science education researchers as tempered radicals struggling against opp(reg)ressive reforms and that there is a need for more studies to excavate these and other silences.