History,philosophy, and science teaching: The present rapprochement

This paper traces the use of, and arguments for, the history and philosophy of science in school science courses. Specific attention is paid to the British National Curriculum proposals and to the recommendations of the US Project 2061 curriculum guidelines. Some objections to the inclusion of historical material in science courses are outlined and answered. Mention is made of the Piagetian thesis that individual psychological development mirrors the development of concepts in the history of science. This introduces the topic of idealisation in science. Some significant instances are itemised where science education has, at its considerable cost, ignored work in philosophy of science. Arguments for the inclusion of the history and philosophy of science in science teacher education programmes are given. The paper finishes with a list of topical issues in present science education where collaboration between science teachers, historians, philosophers, and sociologists would be of considerable benefit.     

Environmental Education Course Development for Preservice Secondary School Science Teachers in the Republic of Korea

Abstract

In Summer 1996, an opinionnaire survey was used to evaluate the opinions of Korean professors, in earth science education and geology departments, about the science concepts related to environmental issues that might be important for secondary preservice earth science teachers in the Republic of Korea. The opinionnaire contained 63 items within the 14 major topics being considered. It used a 4-choice, Likert-type scale and was completed by 47 professors (response rate = 51%). There was a good coincidence in opinions on major topics to be included. Respondents favored an environmental earth science course that emphasized the “human impact on the environment” rather than “natural environmental hazards.” Also, they favored study of natural hazards that commonly occur in Korea within a context of worldwide natural hazards.     

Essential Concepts of Nanoscale Science and Technology for High School Students Based on a Delphi Study by the Expert Community

Nanoscale science and technology (NST) is an important new field in modern science. In the current study, we seek to answer the question: ‘What are the essential concepts of NST that should be taught in high school'? A 3-round Delphi study methodology was applied based on 2 communities of experts in nanotechnology research and science education. Eight essential concepts in NST were identified. Each concept is accompanied by its explanation, definition, importance and includes subcategories that compose it. Three concepts emerged in the Delphi study, which were not identified before: functionality, classification of nanomaterials, and the making of nanotechnology. Differences between the concepts suggested by the 2 communities of experts were found. The results of this study serve as a tool to examine different nanotechnology programs that were reported thus far and to make recommendations for designing a NST program for high school students that includes the essential concepts.     

A study of the presence of evolutionary protoconcepts in pre-high school textbooks

Abstract Elementary and middle school science texts were analyzed for the presence of evolutionary protoconcepts, which are defined as topics that prepare students to study evolution in later years. Elementary and middle school texts were content-analyzed for protoconcepts in both life science and earth science. Seventeen concepts considered important for student understanding of evolution were gleaned from the misconception literature and used to review the life science texts. Concepts used to analyze other texts were chosen by exploring all texts used in the analysis for any topics that might qualify as evolutionary protoconcepts, thus generating grounded theory. Coverage of evolutionary protoconcepts varies considerably among published textbooks. We recommend using this analysis when considering textbooks for adoption and for supplementing texts currently in use. We also recommended this type of analysis of textbooks for inclusion of other topics of interest to science education research.     

Exploring Secondary Science Teachers' Perceptions on the Goals of Earth Science Education in Taiwan

The educational reform movement since the 1990s has led the secondary earth science curriculum in Taiwan into a stage of reshaping. The present study investigated secondary earth science teachers' perceptions on the Goals of Earth Science Education (GESE). The GESE should express the statements of philosophy and purpose toward which educators direct their attention, and provide the visions or broad aims that earth science education is designed to achieve. Based on this rationale, the purpose of this study was to explore teachers' perceptions on the GESE at secondary school level (Grades 7–12) in Taiwan. A national survey of 1,000 earth science teachers was conducted in May 2004, with a response rate of 70.2%. The results revealed that ‘Students acquire basic earth science concepts’ is the most important GESE both in teachers' preferred goal and their actual teaching practice in the secondary earth science education; that there is a major gap between teachers' preferred and actual GESE in terms of ‘Preparing students for the entrance examinations’; and that the differences between teachers' preferred and actual GESE are contingent on the teachers' age, the school size, and the teacher education background of teachers.     

The Delphi Technique in Identifying Learning Objectives for the Development of Science,Technology and Society Modules for Palestinian Ninth Grade Science Curriculum

This article outlines how learning objectives based upon science, technology and society (STS) elements for Palestinian ninth grade science textbooks were identified, which was part of a bigger study to establish an STS foundation in the ninth grade science curriculum in Palestine. First, an initial list of STS elements was determined. Second, using this list, ninth grade science textbooks and curriculum document contents were analyzed. Third, based on this content analysis, a possible list of 71 learning objectives for the integration of STS elements was prepared. This list of learning objectives was refined by using a two-round Delphi technique. The Delphi study was used to rate and to determine the consensus regarding which items (i.e. learning objectives for STS in the ninth grade science textbooks in Palestine) are to be accepted for inclusion. The results revealed that of the initial 71 objectives in round one, 59 objectives within round two had a mean score of 5.683 or higher, which indicated that the learning objectives could be included in the development of STS modules for ninth grade science in Palestine.     

Explanations in STEM Areas: an Analysis of Representations Through Language in Teacher Education

Constructing explanations of scientific concepts is one of the most frequent strategies used in the science classroom and is a high-leverage teaching practice. This study analysed the explanations provided by student teachers in STEM areas from a socio-materiality perspective focused on verbal and nonverbal language and representations. The study was conducted in a hybrid research format by scholars and a preservice teacher. First, the study compared the representational elements used by 86 student teachers to construct explanations about various concepts in a roleplay setting. Next, a positioning analysis was done by a preservice teacher, to a selection of five of these explanations focused on the concept of “force”. The positioning analysis highlighted the embedded voices in the construction of explanations, with a focus on the intersection between science and language. The results showed that the student teachers created explanations as static artefacts, mainly using examples, graphs and images to clarify the concepts. The voices of learners and scientists were mostly absent from the explanations, which led to the presentation of explanations in STEM areas as finished and unquestionable artefacts, with references neither to nature nor to the history of science. We reflect on the meanings attributed to learning to be a practitioner in the context of interconnecting science and language through explanations, as a process of meaning (re)production within the classroom. Implications for teacher education are discussed in order to enhance student teachers’ awareness about constructing knowledge by enacting explanations in the science classroom.

     

Social Capital, Collective Intelligence and Expansive Learning: Thinking through the Connections. Education and the Economy

The paper seeks to draw out the connections between social capital, collective intelligence and expansive learning, interrogating the terms for their progressive potential. It sets these concepts within their socio-economic context, one which asserts that the development of social capitalwill be a vehicle for economic regeneration and competitiveness as well as a mechanism for the generation of social inclusion and cohesion. It concludes by arguing that the debate is set within a context that accepts capitalist relations and that this places a limit on the progressive potential of social capital, collective intelligence and expansive learning.     

Do Elementary Science Methods Textbooks Facilitate the Understanding of Magnet Concepts?

The study of magnets is a common physical science topic for elementary students. This study examined elementary science methods textbooks to determine how magnet concepts were presented. Each methods textbook's section relating to magnets was read. Particular attention was paid to the organization, sequence of concepts, potential misconceptions, and types of investigations included. A previously validated magnet concept list was used. A detailed analysis of 11 elementary science methods textbooks found great variation in the magnet concepts presented, general omission of ceramic magnets, frequent misconceptions about poles, and limited investigations that address both attraction and repulsion.     

Socio-Political-Cultural Foundations of Environmental Education

Abstract

This research project identified concepts from the social sciences that are prerequisite for understanding or analyzing environmental issues. Concepts were identified through a review of social science textbooks and educational materials and through interviews with social scientists. A list of 57 concepts was sent to a validity panel to rate each concept for clarity, acceptability to environmental education, and importance to environmental education. Means and standard deviations were calculated. Results showed that the panelists generally thought the concepts were acceptable and important to environmental education. Concepts were then revised and 6 were added based on panelists' comments.     

Results and Implications of a 12-Year Longitudinal Study of Science Concept Learning

This paper describes the methods and outcomes of a 12-year longitudinal study into the effects of an early intervention program, while reflecting back on changes that have occurred in approaches to research, learning and instruction since the preliminary inception stages of the study in the mid 1960s. We began the study to challenge the prevailing consensus at the time that primary school children were either preoperational or concrete operational in their cognitive development and they could not learn abstract concepts. Our early research, based on Ausubelian theory, suggested otherwise. The paper describes the development and implementation of a Grade 1–2 audio tutorial science instructional sequence, and the subsequent tracing over 12 years, of the children’s conceptual understandings in science compared to a matched control group. During the study the concept map was developed as a new tool to trace children’s conceptual development. We found that students in the instruction group far outperformed their non-instructed counterparts, and this difference increased as they progressed through middle and high school. The data clearly support the earlier introduction of science instruction on basic science concepts, such as the particulate nature of matter, energy and energy transformations. The data suggest that national curriculum standards for science grossly underestimate the learning capabilities of primary-grade children. The study has helped to lay a foundation for guided instruction using computers and concept mapping that may help both teachers and students become more proficient in understanding science.     

Risk and school science education

In this paper I consider a role for risk understanding in school science education. Grounds for this role are described in terms of current sociological analyses of the contemporary world as a ‘risk society’ and recent public understanding of science studies where science and risk are concerns commonly linked within the wider community. These concerns connect with support amongst many science educators for the goal of science education for citizenship. From this perspective scientific literacy for decision making on contemporary socioscientific issues is central. I argue that in such decision making, risk understanding has an important role to play. I examine some of the challenges its inclusion in school science presents to science teachers, review previous writing about risk in the science education literature and consider how knowledge about risk might be addressed in school science. I also outline the varying conceptions of risk and suggest some future research directions that would support the inclusion of risk in classroom discussions of socioscientific issues.     

"集体行动"研究中的概念谱系

在中国当前各类研究社会矛盾或冲突的文献中,有一组具有"家族相似性"的概念,如"集体抗争"、"维权行动"、"群体性事件"、"社会冲突""社会运动"、"集体行动"等,而且每一个概念又往往包含一系列的子概念。学者们在阐述自己所使用的概念时,往往坚持该概念在内涵或研究方法上的独特性。本文认为这些概念本身在逻辑或经验意义上有明显的不足,而且这种研究现状,不利于研究者们之间的学术对话或交流。因此,本文在对这些概念进行必要的梳理或评估的基础上,试图提出基于利益表达的"集体行动"概念,并认为它是契合当前中国情境的研究社会矛盾或冲突的一个统摄性、规范性和学理性概念。     

The internal consistency of a concept mapping scoring scheme and its effect on prediction validity

This study examines the internal consistency of Novak and Gowin's scoring scheme and its effect on the prediction validity of concept mapping as an alternative science classroom achievement assessment. Data were collected in three typical situations: very limited concept mapping experience with free‐style concept mapping; some concept mapping experience with questions provided; extensive concept mapping experience with a list of concepts provided for. It was found that Novak's scoring scheme was not internally consistent, and therefore there was generally no significant correlation between students’ scores on concept mapping and students’ scores on conventional classroom achievement assessments. The need for a new scoring scheme when concept mapping is used as an alternative science assessment is discussed.     

Students’ and Teachers’ Application of Surface Area to Volume Relationships

The National Science Education Standards emphasize teaching unifying concepts and processes such as basic functions of living organisms, the living environment, and scale (NRC 2011). Scale includes understanding that different characteristics, properties, or relationships within a system might change as its dimensions are increased or decreased (NRC 2011). One such relationship involves surface area to volume which is a pervasive concept that can be found throughout different sciences. This concept is important for students to not only understand the association of the two, but to also be able to apply this relationship in science contexts. The purpose of this study is to investigate the factors that influence the understanding surface area to volume relationships. This study examined middle school students’, high school students’, and science teachers’ logical thinking skills (including proportional reasoning), visual-spatial skills, and understandings of surface area to volume relationships. Regression results indicated that participants’ reasoning abilities and components of visual-spatial skills could be possible predictors for one’s ability to understand surface area to volume relationships. Implications for teaching scale concepts such as surface area to volume relationships in the science classroom are discussed.     

New Simulation Methods to Facilitate Achieving a Mechanistic Understanding of Basic Pharmacology Principles in the Classroom

We present a simulation tool to aid the study of basic pharmacology principles. By taking advantage of the properties of agent-based modeling, the tool facilitates taking a mechanistic approach to learning basic concepts, in contrast to the traditional empirical methods. Pharmacodynamics is a particular aspect of pharmacology that can benefit from use of such a tool: students are often taught a list of concepts and a separate list of parameters for mathematical equations. The link between the two can be elusive. While wet-lab experimentation is the proven approach to developing this link, in silico simulation can provide a means of acquiring important insight and understanding within a time frame and at a cost that cannot be achieved otherwise. We suggest that simulations and their representation of laboratory experiments in the classroom can become a key component in student achievement by helping to develop a student’s positive attitude towards science and his or her creativity in scientific inquiry. We present results of two simulation experiments that validate against data taken from current literature. We follow with a classroom example demonstrating how this tool can be seamlessly integrated within the traditional pharmacology learning experience.     

Urban fifth graders’ connections-making between formal earth science content and their lived experiences

Earth science education, as it is traditionally taught, involves presenting concepts such as weathering, erosion, and deposition using relatively well-known examples—the Grand Canyon, beach erosion, and others. However, these examples—which resonate well with middle- and upper-class students—ill-serve students of poverty attending urban schools who may have never traveled farther from home than the corner store. In this paper, I explore the use of a place-based educational framework in teaching earth science concepts to urban fifth graders and explore the connections they make between formal earth science content and their lived experiences using participant-driven photo elicitation techniques. I argue that students are able to gain a sounder understanding of earth science concepts when they are able to make direct observations between the content and their lived experiences and that when such direct observations are impossible they make analogies of appearance, structure, and response to make sense of the content. I discuss additionally the importance of expanding earth science instruction to include man-made materials, as these materials are excluded traditionally from the curriculum yet are most immediately available to urban students for examination.     

Textbook treatments and students' understanding of acceleration

A single science textbook often provides the syllabus for courses at upper secondary and tertiary levels, and may be used as a principal source of information or explanation. The research reported in this article challenges such practices. The ways in which the concept, acceleration, is treated in physics textbooks is compared with understandings of the concept demonstrated by final-year secondary (Year 12) and first-year university students. Some students' understandings are shown to be incomplete in ways that parallel misleading or inaccurate textbook treatments of the concept. In addition to misleading or inaccurate statements, the limitations of some textbook treatments of acceleration were found to include: lack of attempts to make explicit relationships with other concepts, failure to point out when it is appropriate to use particular definitions or that an alternative definition might be more appropriate in specific situations, inclusion of operational definitions without conceptual explanations, and a focus on quantitative treatments while overlooking the development of qualitative understanding. Two principal aspects that distinguished the ways in which the students understood acceleration were identified: (a) the relation between acceleration and velocity; and (b) the relation between acceleration and force(s). The results of the study have implications for teaching and, in particular, for the use of textbooks in teaching. These implications are discussed in the article.     

Science Instruction with a Humanistic Twist: Teachers' Perception and Practice in Using the History of Science in Their Classrooms

Scholars have argued that the history of science should be included in the science curriculum because it provides meaningful perspective about scientific concepts, processes, and context. This article begins with a review of efforts to humanize science education by including the history of science, and a review of the rationale for including the history of science in the science education curriculum. The authors then synthesize a conceptual framework for examining the role of the history of science in science education. The framework is organized around realms in the history of science: a) conceptual understanding, b) procedural understanding, and c) contextual understanding, and includes approximately 3 sub-elements within each realm. The framework has been used previously to study the inclusion of the history of science in high school physics textbooks (Wang 1998). In this study, it is used to examine the perceptions and practices of elementary and secondary school teachers in using the history of science in their classrooms. Thirty-eight teachers completed a questionnaire which used Likert scale items to assess their perception of the value of the history of science, and practice in using it in their classroom. A sub-set of teachers were then interviewed to understand the interconnection of these views in more detail. Teachers believe that the inclusion of the history of science should not be used for elementary school students. Teachers who believe in and practice the inclusion of the history of science identify many benefits for their students. However, they believe that it is difficult to include the procedural realm of understanding. The authors conclude that humanizing science isn't a matter of making it fun so much as making it a human and meaningful endeavor.     

The “Species” Concept as a Gateway to Nature of Science

The nature of science (NOS) is a primary goal in school science. Most teachers are not well-prepared for teaching NOS, but a sophisticated and in-depth understanding of NOS is necessary for effective teaching. Some authors emphasize the need for teaching NOS in context. Species, a central concept in biology, is proposed in this article as a concrete example of a means for achieving increased understanding of NOS. Although species are commonly presented in textbooks as fixed entities with a single definition, the concept of species is a highly discussed one in the science and the philosophy of biology. A multitude of species concepts exist, reflecting both the views and interests of researchers and their utility in different organism groups. The present study serves to address the following questions: How do textbooks in Norwegian primary and lower secondary schools present the concept of species? Can inquiries into the concept of “species” serve to highlight aspects of NOS? A review of the available literature on species and species concepts in school is also performed. In the schoolbooks, the biological species concept is commonly used as the main definition, whereas the morphological species concept is represented by additional remarks of similarity. The potential and pitfalls of using the species concept for teaching NOS are discussed, with NOS being discussed both as a family resemblance concept and as a consensus list. Teacher education is proposed as a starting point for inducing a more sophisticated view of biology into schools.