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1.
Kalle Juuti 《Science & Education》2014,23(8):1663-1680
The goal of this paper is to study the question of whether a phenomenological view of the Earth could be empirically endorsed. The phenomenological way of thinking considers the Earth as a material entity, but not as an object as viewed in science. In the learning science tradition, tracking the process of the conceptual change of the shape of the Earth, science’s view of the Earth as an object—a celestial body—has been applied. I reanalysed data published in Vosniadou and Brewer’s (Cognit psychol 24:535–585, 1992) seminal paper. According to my reanalysis of their interview material, it is plausible to conclude that the Earth as an infinite surface is the way to experience the Earth. Further, the ‘dual Earth model’ is the first model of the Earth as an object. I conclude that experiences in the lifeworld need to be taken into consideration more seriously in science education research. 相似文献
2.
Learning from and responding to students' questions: The authoritative and dialogic tension 总被引:1,自引:1,他引:0
In this study we present an analysis of classroom interactions initiated by students' wonderment questions. Our interest in such events arises from their potential to stimulate active intellectual engagement in classrooms, which can impact upon the subsequent development of the classroom discourse. In investigating this issue we shall address the following research question: How do student questions impact upon the teaching explanatory structure and modify the form of the ongoing classroom discourse, in selected science lessons? From data collected in a Brazilian secondary school we have selected three classroom episodes, with large differences in both the context in which the student's question emerges and in the communicative approach developed in response to it. The analysis, based on the framework proposed by Mortimer and Scott [Mortimer and Scott (2003). Meaning making in secondary science classrooms. Maidenhead: Open University Press], shows that questions made by students are important in providing feedback from students to the teacher, enabling adjustments to the teaching explanatory structure. These adjustments sometimes occur smoothly, at other times with major changes to the features of the classroom discourse, and elsewhere with misunderstanding and disagreement. The data also suggest the need to consider students' intentions and their active participation in the negotiation of both the content and structure of classroom discourse. © 2009 Wiley Periodicals, Inc. J Res Sci Teach 47:174–193, 2010 相似文献
3.
This study had the goal of investigating the association among elementary students' (N = 276) science and math beliefs and the relationship between those beliefs and teachers' ratings of mathematical and science understanding. Results of structural path analysis indicate that in science, intellectual risk‐taking (IRT; the willingness to share tentative ideas, ask questions, attempting to do, and learn new things) was positively related to teachers' ratings of science understanding, while creative self‐efficacy (CSE) beliefs (i.e., students' confidence in their ability to generate ideas and solutions in science) were indirectly related (working through IRT). Results also indicate that students' scientific certainty beliefs (i.e., the belief that science knowledge is stable, fixed, and represented by correct answers) were negatively related to teachers' ratings of science understanding. With respect to math, results indicate that students' CSE beliefs were positively related to teachers' ratings of math understanding; whereas students' mathematical source beliefs (i.e., believing that math knowledge originates from external sources) were negatively related. © 2012 Wiley Periodicals, Inc. J Res Sci Teach 49: 942–960, 2012 相似文献
4.
A group of preservice primary teachers (46) in their third year of a Bachelor of Education degree were overtly taught the nature of science (NOS) and nature of technology (NOT) within an authentic context of the issues of UV radiation. The research question asked was, ‘What characteristics of NOS and NOT are identified, illustrated and justified within an authentic context by the preservice teachers?’ This context was accessed via a web-based resource, ‘You, Me and UV’ (www.sciencelearn.org.nz), which provided preservice teachers with virtual access to the science research community. The goal of this research was to explore the potential of providing a virtual authentic resource, accompanied by explicit teaching of NOS and NOT, to develop preservice teachers' understandings of NOS and NOT. A data collection instrument where preservice teachers were required not only to identify examples of NOS and NOT, but also to justify and contextualise them from this context, was able to capture their level of understanding. It also showed the potential of an authentic context and the possibilities of a virtual resource to provide access to communities of practice of science and technology research. 相似文献
5.
Issues regarding scientific explanation have been of interest to philosophers from Pre-Socratic times. The notion of scientific explanation is of interest not only to philosophers, but also to science educators as is clearly evident in the emphasis given to K-12 students' construction of explanations in current national science education reform efforts. Nonetheless, there is a dearth of research on conceptualizing explanation in science education. Using a philosophically guided framework—the Nature of Scientific Explanation (NOSE) framework—the study aims to elucidate and compare college freshmen science students', secondary science teachers', and practicing scientists' scientific explanations and their views of scientific explanations. In particular, this study aims to: (1) analyze students', teachers', and scientists' scientific explanations; (2) explore the nuances about how freshman students, science teachers, and practicing scientists construct explanations; and (3) elucidate the criteria that participants use in analyzing scientific explanations. In two separate interviews, participants first constructed explanations of everyday scientific phenomena and then provided feedback on the explanations constructed by other participants. Major findings showed that, when analyzed using NOSE framework, participant scientists did significantly “better” than teachers and students. Our analysis revealed that scientists, teachers, and students share a lot of similarities in how they construct their explanations in science. However, they differ in some key dimensions. The present study highlighted the need articulated by many researchers in science education to understand additional aspects specific to scientific explanation. The present findings provide an initial analytical framework for examining students' and science teachers' scientific explanations. 相似文献
6.
Anita Rampal 《Interchange》1992,23(3):309-314
This article concludes theInterchange debate on the author's own “A Possible ‘Orality’ for Science?” (Interchange, Vol. 23, No. 3, pp. 227–244). The author contrasts two movements in science education: Science for Scientists and Science for All. The author maintains that we need to review the language of science to the end of producing a more palatable school science curriculum for all of our pupils. 相似文献
7.
Students often perceive school science as purely theoretical, overloaded with facts, and mostly disconnected from their school, home, and community life. One way to bridge the disconnection between school science and lived experiences, and support students in realizing the relevance of science to their everyday life, is by enabling them to integrate their funds of knowledge (FoK), the knowledge and expertise people have because of their roles in their families, communities, and culture, within science. To support students in this task, we developed Together with Science, a series of Vlogs (video blogs) designed to guide families and students through home-based experiments and support the emergence of a third space, where science and everyday life intersect. The Vlogs provided the necessary scientific background for the experiments and encouraged participants to share aspects of their lived experiences and reflect upon the realization of scientific phenomena in their lives. Using videotaped discussions of students and family members, we examined the interactions between them, as well as the FoK addressed in the conversation. The results indicate that multiple types of interactions emerged between students and family members, as they jointly conducted the science experiments and discussed their findings. Shifts in these interactions were associated with the development of a shared third space, in which both students and family members were able to concurrently relate everyday life to the scientific phenomenon. Most FoK were associated with participants' homes and culture. Our results suggest that family members can serve as brokers to support their children in realizing the relationship between science and their everyday life, by bringing in their unique FoK into the scientific discussion, and highlighting the importance of thoughtfully designed learning environments to support them in the process. 相似文献
8.
Barbara A. McMillan 《Interchange》2013,43(2):129-145
This paper reports on the development of a science unit for Nunavut students and my collaboration with Louise Uyarak, an early years teacher and a graduate of Arctic College’s teacher education program. The unit addresses light outcomes in the Canadian Common Framework of Science Learning Outcomes, K–12. More importantly, it incorporates aspirations of the local community, the District Education Authority, and the Nunavut government for bi-cultural education in science: an education that develops knowledge in and about science and knowledge passed on to the Inuit by their ancestors. Components of lessons are presented and discussed in the context of how Louise and I worked together to develop a resource that would embody the fundamental nature of culturally responsive teaching and “two-way” science learning. 相似文献
9.
Edvin Østergaard 《Science & Education》2017,26(5):557-582
Focus of this article is the current situation characterized by students’ de-rootedness and possible measures to improve the situation within the frame of education for sustainable development. My main line of argument is that science teachers can practice teaching in such a way that students are brought in deeper contact to the environment. I discuss efforts to promote aesthetic experience in science class and in science teacher education. Within a wide range of definitions, my main understanding of aesthetic experience is that of pre-conceptual experience, relational to the environment and incorporated in students’ embodied knowledge. I ground the idea of Earth at rest in Husserl’s phenomenological philosophy and Heidegger’s notion of science’ deprivation of the world. A critique of the ontological reversal leads to an ontological re-reversal that implies giving lifeworld experience back its value and rooting scientific concepts in students’ everyday lives. Six aspects of facilitating grounding in sustainability-oriented science teaching and teacher education are highlighted and discussed: students’ everyday knowledge and experience, aesthetic experience and grounding, fostering aesthetic sensibility, cross-curricular integration with art, ontological and epistemological aspects, and belongingness and (re-)connection to Earth. I conclude that both science students and student-teachers need to practice their sense of caring and belonging, as well as refining their sensibility towards the world. With an intension of educating for a sustainable development, there is an urgent need for a critical discussion in science education when it comes to engaging learners for a sustainable future. 相似文献
10.
Päivi H. Taskinen Kerstin Schütte Manfred Prenzel 《Educational Research and Evaluation》2013,19(8):717-733
Many researchers consider a lacking interest in science and the students' belief that science is too demanding as major reasons why young people do not strive for science-related careers. In this article, we first delineated a theoretical framework to investigate the importance of interest, self-concept, and school factors regarding students' career preferences. Then, we tested the expected effects on a sample of German 9th-grade students (N = 7,813). We focused on two school factors: the amount of (additional) science activities and the real-life applications in science classes. The multi-level analysis showed that school factors were highly relevant for the students' interest in science and science self-concept. In turn, interest in science and science self-concept affect the students' interest in science-related careers. We conclude that focusing on the link between individual and school characteristics is important for the understanding of students' interest in science-related careers. 相似文献
11.
Eileen Carlton Parsons 《科学教学研究杂志》2008,45(6):665-683
As other countries vigorously promote rapid advancement in science, optimizing the participation of all students in the United States in science is imperative. This study focused on African American students and examined their science achievement in relation to Black Cultural Ethos (BCE), a construct rooted in psychology. Via qualitative and quantitative data obtained from a non‐random control group design, the study addressed three questions: (1) With respect to BCE, what characterizes the natural instructional contexts of two middle school science teachers? (2) What characterizes the achievement of African American students in contexts that incorporate BCE and contexts that do not? (3) What achievement patterns, if any, exist in BCE and non‐BCE instructional contexts? With regard to the natural contexts, the teachers did not incorporate BCE even when the opportunities were available to do so. Within these non‐BCE contexts, the group's mean scores on the study‐specific test that aligned with instruction decreased from pretest to posttest with approximately one‐third of the students' scores improving. When a context was altered with a moderate effect size of 0.47 to include BCE, the group's mean scores on the aforementioned test increased from pretest to posttest with two‐thirds of the students' scores improving. An illustration of the interplay between BCE and context and a consideration of the interplay as a mediating factor in research involving African American students encapsulate the significance and implications of the study's findings. © 2008 Wiley Periodicals, Inc. J Res Sci Teach 45: 665–683, 2008 相似文献
12.
The primary purpose of this study was to develop and apply a method for assessing teachers' context beliefs about their science teaching environment. Interviews with 130 purposefully selected teachers resulted in 28 categories of environmental factors and/or people who were perceived to influence science teaching. These categories were used to develop items for the Context Beliefs about Teaching Science instrument and provided evidence for content validity. Construct validity was partially confirmed through factor analysis that resulted in 26 items and two subscales on the final instrument. Using Ford's Motivation Systems Theory and Bandura's Theory of Collective Efficacy, additional evidence for construct validity was found in the modest correlation of context beliefs with outcome expectancy beliefs and the low correlation with science teaching self‐efficacy beliefs. The instrument was tested using 262 teachers participating in long‐term science professional development programs. These teachers possessed fairly positive context beliefs and, according to Ford's theory, should be capable of effective functioning in the classroom. It was concluded that the assessment of context beliefs would complement current science teacher self‐efficacy measures, thereby allowing researchers to develop profiles of science teachers' personal agency belief patterns. It could also be used to determine the factors which predict particular personal agency belief patterns, and assess teachers' perceptions of the strengths and weaknesses of school science programs, and could be used in planning and monitoring professional development experiences for science teachers. © 2000 John Wiley & Sons, Inc. J Res Sci Teach 37: 275–292, 2000. 相似文献
13.
Renia Gasparatou 《Science & Education》2017,26(7-9):799-812
The move from respecting science to scientism, i.e., the idealization of science and scientific method, is simple: We go from acknowledging the sciences as fruitful human activities to oversimplifying the ways they work, and accepting a fuzzy belief that Science and Scientific Method, will give us a direct pathway to the true making of the world, all included. The idealization of science is partly the reason why we feel we need to impose the so-called scientific terminologies and methodologies to all aspects of our lives, education too. Under this rationale, educational policies today prioritize science, not only in curriculum design, but also as a method for educational practice. One might expect that, under the scientistic rationale, science education would thrive. Contrariwise, I will argue that scientism disallows science education to give an accurate image of the sciences. More importantly, I suggest that scientism prevents one of science education’s most crucial goals: help students think. Many of my arguments will borrow the findings and insights of science education research. In the last part of this paper, I will turn to some of the most influential science education research proposals and comment on their limits. If I am right, and science education today does not satisfy our most important reasons for teaching science, perhaps we should change not just our teaching strategies, but also our scientistic rationale. But that may be a difficult task. 相似文献
14.
15.
Research in science education confirms the importance of self-efficacy in students' persistence and success in the sciences. The current study examined the role of science self-efficacy in nonspecialist, arts and communication-oriented students encountering science in a general education context. Participants (N = 275) completed a beginning- and end-of-semester survey including a Science Self-Efficacy Scale, a “connection to science” measure—the Inclusion of Science in Self Scale—and a Science Anxiety Scale. Participants also responded to two open-ended “sources of science efficacy” questions, and provided background/demographic information and access to their academic records. Results showed a significant increase in science self-efficacy and connection to science—although no change in science anxiety—over the course of the semester. The observed shift in self-efficacy for minority and international students was of particular note. These students started the course with lower confidence but, by the end of the semester, reported comparable science self-efficacy, and achieved similar grades to their White/Non-Hispanic and US resident classmates. Contrary to expectations, science self-efficacy did not predict performance in the class. However, students' self-reported sources of efficacy indicated increased confidence in using science in daily life, and confirmed the value of mastery experiences and of personally meaningful, student-centered course design in scaffolding student confidence. Results are discussed in terms of the individual and instructional factors that support science self-efficacy and student success in this unique, general education science environment. 相似文献
16.
How to improve students' understanding of energy transformation and conservation remains one of the main challenges of energy teaching. To address this challenge, we developed a new teaching strategy suited to high school based on history and philosophy of science (HPS). It involves five key ingredients: study and reproduction of Joule's paddle-wheel experiment, introduction of Rankine's definition, study of a historical text of Joule, use of an “ID card of energy,” and early introduction and multiple application of the principle of energy conservation. This strategy was built and implemented in the frame of a collaborative and iterative work involving researchers and teachers. We examined the effects of this HPS-based teaching strategy on students' understanding of energy. We used a quantitative method based on pre- and post-tests (N = 95/87) completed by a qualitative analysis using both video recordings of classroom activities and videos produced by students during one of the teaching sequences. The outcomes show that the teaching strategy had an overall positive impact on students' learning of energy: in particular, Joule's paddle-wheel experiment seems to favor their understanding of the notion of energy transformation, while the early introduction and multiple application of the conservation principle appears as a relevant option to facilitate its mastering. This study illustrates how HPS might actually be introduced in classrooms and brings to light its usefulness for building new science teaching strategies. 相似文献
17.
Lyn Carter 《科学教学研究杂志》2005,42(5):561-580
Like Lemke (J Res Sci Teach 38:296–316, 2001), I believe that science education has not looked enough at the impact of the changing theoretical and global landscape by which it is produced and shaped. Lemke makes a sound argument for science education to look beyond its own discourses toward those like cultural studies and politics, and to which I would add globalisation theory and relevant educational studies. Hence, in this study I draw together a range of investigations to argue that globalisation is indeed implicated in the discourses of science education, even if it remains underacknowledged and undertheorized. Establishing this relationship is important because it provides different frames of reference from which to investigate many of science education's current concerns, including those new forces that now have a direct impact on science classrooms. For example, one important question to investigate is the degree to which current science education improvement discourses are the consequences of quality research into science teaching and learning, or represent national and local responses to global economic restructuring and the imperatives of the supranational institutions that are largely beyond the control of science education. Developing globalisation as a theoretical construct to help formulate new questions and methods to examine these questions can provide science education with opportunities to expand the conceptual and analytical frameworks of much of its present and future scholarship. © 2005 Wiley‐Liss, Inc. 相似文献
18.
Eric Leake 《Technical Communication Quarterly》2013,22(2):129-144
In this article I examine The Lancet Iraq casualty reports for their demonstration of prefigured accommodation, a rhetorical strategy in which the authors anticipate and attempt to influence their work's wider popularization. My reading of the reports and accompanying commentaries attends to the introduction of journalistic features and calls to political action. As part of my analysis, I interview a lead author of the reports about his rhetorical concerns in composing the work of a politically engaged science. 相似文献
19.
Kapil Dev Regmi 《International Journal of Lifelong Education》2020,39(2):219-233
ABSTRACT The idea of learning rooted in behavioural psychology has become dominant in the field of teaching and learning for several decades. Even though it has been widely used in formal education it is inadequate for informing lifelong learning policies and plans. In this paper, first I critique the psychological foundation of learning and in the second part, drawing on Habermasian conceptualisation of three structural components of the lifeworld (culture, society, and personality), I conceptualise the three components as the social foundations of learning: learning as cultural reproduction, learning as social integration and learning as socialisation. In the context of the UN’s declaration of ‘lifelong learning’ as one of the Sustainable Development Goals, this paper will be useful for developing policies to address challenges faced by individual countries at cultural, societal and individual levels. 相似文献
20.
Agustín Adúriz-Bravo 《Science & Education》2004,13(7-8):717-731
This article refers to a framework to teach the philosophy of science to prospective and in-service science teachers. This framework includes two components: a list of the main schools of twentieth-century philosophy of science (called stages) and a list of their main theoretical ideas (called strands). In this paper, I show that two of these strands, labelled intervention/method and context/values, can be taught to science teachers using some of the instructional activities sketched in Michael Matthews’s Time for Science Education. I first explain the meaning of the two selected strands. Then I show how the pendulum can be used as a powerful organiser to address specific issues within the nature of science, as suggested by Matthews. 相似文献