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1.
Susan Bobbitt Nolen 《科学教学研究杂志》2003,40(4):347-368
In a study of the relationship between high school students' perceptions of their science learning environments and their motivation, learning strategies, and achievement, 377 students in 22 introductory science classrooms completed surveys in the fall and spring of their ninth‐grade year. Hierarchical linear regression was used to model the effects of variables at both the classroom and individual level simultaneously. High intraclass agreement (indicated by high parameter reliability) on all classroom environment measures indicated that students shared perceptions of the classroom learning environment. Controlling for other factors, shared perceptions that only the most able could succeed in science classrooms and that instruction was fast‐paced and focused on correct answers negatively predicted science achievement, as measured on a districtwide curriculum‐linked test. Shared perceptions that classrooms focused on understanding and independent thinking positively predicted students' self‐reported satisfaction with learning. Implications of these results for both teaching and research into classroom environments are discussed. © 2003 Wiley Periodicals, Inc. J Res Sci Teach 40: 347–368, 2003 相似文献
2.
Brian L. Gerber Anne M.L. Cavallo Edmund A. Marek 《International Journal of Science Education》2013,35(5):535-549
Informal learning experiences have risen to the forefront of science education as being beneficial to students' learning. However, it is not clear in what ways such experiences may be beneficial to students; nor how informal learning experiences may interface with classroom science instruction. This study aims to acquire a better understanding of these issues by investigating one aspect of science learning, scientific reasoning ability, with respect to the students' informal learning experiences and classroom science instruction. Specifically, the purpose of this study was to investigate possible differences in students' scientific reasoning abilities relative to their informal learning environments (impoverished, enriched), classroom teaching experiences (non-inquiry, inquiry) and the interaction of these variables. The results of two-way ANOVAs indicated that informal learning environments and classroom science teaching procedures showed significant main effects on students' scientific reasoning abilities. Students with enriched informal learning environments had significantly higher scientific reasoning abilities compared to those with impoverished informal learning environments. Likewise, students in inquirybased science classrooms showed higher scientific reasoning abilities compared to those in non-inquiry science classrooms. There were no significant interaction effects. These results indicate the need for increased emphases on both informal learning opportunities and inquiry-based instruction in science. 相似文献
3.
Mijung Kim 《International Journal of Science Education》2016,38(1):51-72
Research on young children's reasoning show the complex relationships of knowledge, theories, and evidence in their decision-making and problem solving. Most of the research on children's reasoning skills has been done in individualized and formal research settings, not collective classroom environments where children often engage in learning and reasoning together to solve classroom problems. This study posits children's reasoning as a collective social activity that can occur in science classrooms. The study examined how children process their reasoning within the context of Grade 2/3 science classrooms and how the process of collectivity emerges from classroom interactions and dialogue between children as they attempt to solve their classroom problems. The study findings suggest that children's reasoning involves active evaluation of theories and evidence through collective problem solving, with consensus being developed through dialogical reasoning. 相似文献
4.
Internationally there is concern in relation to the traditional learning environments evident in many science classrooms and
the levels of understanding of science developed by students in such environments. Further, students have generally been found
to be poor in relation to thinking in terms of models or theories and in terms of evidence to support their theories. The
majority of research on classroom environments has focused on characterising the learning environment in classrooms rather
than monitoring changes to a class's or an individual's perceptions to their learning environments as a consequence of interventions.
This study reports an attempt to change the learning environment in a classroom and documents changes in participants' perceptions
of their learning environments and the corresponding changes in a teacher's and her students' perceptions of their reasoning
and understanding that such changes facilitated. A community of learners in which students and teachers began to understand
the processes and the value of reasoning in terms of theories and evidence was developed as a result of the involvement of
the researchers with the teacher and her class of students.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
5.
Abstract The study of learning environments provides a useful research framework for investigating the effects of educational innovations such as those which are associated with the use of the Internet in classroom settings. This study reports an investigation into the use of Internet technologies in high-school classrooms in Australia and Canada. Specifically, it combined the investigation of the physical and psychosocial learning environments featured within these ‘technological settings’, as well as interactions among the selected physical and psychosocial factors in influencing students' satisfaction with their learning in these settings. Further, we explored how both the physical and psychosocial domains can effectively enable or, alternatively, constrain the teaching methods used in these classrooms. We first explored the learning environment in these classrooms through the use of a questionnaire measuring aspects of the psychosocial learning environment together with ergonomic site evaluations. Next, we investigated interactions among physical and psychosocial variables in these classrooms through selected and detailed case studies, which included a more detailed assessment of the physical classroom environment in tandem with classroom observations and student/teacher interviews. The results offer insights into new approaches to technology implementation and teaching practice and call for teachers to take a leading role in classroom laboratory design. 相似文献
6.
Although classroom inquiry is the primary pedagogy of science education, it has often been difficult to implement within conventional classroom cultures. This study turned to the alternatively structured Montessori learning environment to better understand the ways in which it fosters the essential elements of classroom inquiry, as defined by prominent policy documents. Specifically, we examined the opportunities present in Montessori classrooms for students to develop an interest in the natural world, generate explanations in science, and communicate about science. Using ethnographic research methods in four Montessori classrooms at the primary and elementary levels, this research captured a range of scientific learning opportunities. The study found that the Montessori learning environment provided opportunities for students to develop enduring interests in scientific topics and communicate about science in various ways. The data also indicated that explanation was largely teacher-driven in the Montessori classroom culture. This study offers lessons for both conventional and Montessori classrooms and suggests further research that bridges educational contexts. 相似文献
7.
What are the barriers to technology‐rich inquiry pedagogy in urban science classrooms, and what kinds of programs and support structures allow these barriers to be overcome? Research on the pedagogical practices within urban classrooms suggests that as a result of many constraints, many urban teachers' practices emphasize directive, controlling teaching, that is, the “pedagogy of poverty” (Haberman, 1991 ), rather than the facilitation of students' ownership and control over their learning, as advocated in inquiry science. On balance, research programs that advocate standards‐based or inquiry teaching pedagogies demonstrate strong learning outcomes by urban students. This study tracked classroom research on a technology‐rich inquiry weather program with six urban science teachers. The teachers implemented this program in coordination with a district‐wide middle school science reform. Results indicated that despite many challenges in the first year of implementation, students in all 19 classrooms of this program demonstrated significant content and inquiry gains. In addition, case study data comprised of twice‐weekly classroom observations and interviews with the six teachers suggest support structures that were both conducive and challenging to inquiry pedagogy. Our work has extended previous studies on urban science pedagogy and practices as it has begun to articulate what role the technological component plays either in contributing to the challenges we experienced or in helping urban science classrooms to realize inquiry science and other positive learning values. Although these data outline results after only the first year of systemic reform, we suggest that they begin to build evidence for the role of technology‐rich inquiry programs in combating the pedagogy of poverty in urban science classrooms. © 2002 John Wiley & Sons, Inc. J Res Sci Teach 39: 128‐150, 2002 相似文献
8.
Mr Jeffrey P. Dorman Dr Campbell J. McRobbie Dr Barry J. Fraser 《Research in Science Education》1993,23(1):61-67
Much Catholic school and church rhetoric suggests that Catholic schools possess distinctive learning environments. Research
into this aspect of Catholic schooling has been hampered by the lack of an appropriate assessment instrument. By drawing on
contemporary church literature, the perceptions of personnel involved in Catholic education and existing classroom environment
questionnaires, a new instrument was developed to assess student perceptions of classroom psychosocial environment in Catholic
schools. The use of this instrument in 64 classrooms in Catholic and Government schools indicated significant differences
on some scales. The distinctive nature of Catholic schooling did not extend to all classroom environment dimensions deemed
important to Catholic education.
Specializations: Catholic education, learning environments.
Specializations: conceptual change in students, science teacher professional development, scientific reasoning, learning environments.
Specializations: learning environments, science education, educational evaluation, curriculum. 相似文献
9.
Although learning environments research has thrived for decades in many countries and school subjects, English classroom environment research is still in its infancy. This article paves the way for expanding research on English classroom environments by (1) reviewing the limited past research in English classrooms and (2) reporting the first study of English learning environments in Singaporean primary schools. For a sample of 441 grade 6 students, past research in other subjects was replicated in that a modified version of the What Is Happening In this Class? questionnaire was cross-validated, classroom environment was found to vary with the determinants of student sex and ethnicity, and associations emerged between students’ attitudes and the nature of the classroom environment. 相似文献
10.
Metacognition refers to an individual's knowledge, control and awareness of his/her learning processes. An important goal
of education is to develop students as metacognitive, life-long learners. However, developing students' metacognition and
evaluating whether classrooms are oriented to the development of students' metacognition are difficult and often time-consuming
tasks. Further, no instruments that measure key dimensions related to classroom factors that specifically influence the development
of students' metacognition have been available. This article describes the conceptualisation, design, and validation of an
instrument for evaluating the metacognitive orientation of science classroom learning environments. The metacognitive orientation
of a learning environment is the extent to which that environment supports the development and enhancement of students' metacognition.
Social constructivism was the guiding referent informing the instrument's orientation and development. This instrument measures
students' perceptions of the extent to which certain psychosocial dimensions, evident in learning environments where interventions
have resulted in enhanced student metacognition, are evident in their science classrooms. Findings from the use of this instrument
complement what is already known from research studies to be generally the case in relation to science classrooms' metacognitive
orientation.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
11.
Practicum experiences in schools are highly valued in science teacher education programs. Yet, there are few studies examining secondary preservice science teachers' practicum classrooms. This mixed-methods study explored secondary preservice science teachers' perceptions of their practicum classroom learning environments, interpreted from an open-ended survey questionnaire, as well as from an adapted version of the Constructivist Learning Environment Survey (CLES; Taylor, Fraser, & Fisher, 1997). Twenty-two preservice teachers within secondary science methods courses volunteered to complete the survey. Qualitative survey findings were corroborated by quantitative results from the CLES survey. Overall, the preservice teachers perceived their practicum classrooms to incorporate some constructivist learning environment factors, but the critical constructivist perspective underpinning the survey was not found. Additionally, innovative practices cogent with these practices were not supported by most of their co-operating teachers. Implications of how preservice education programs can better support prospective science teachers' views and practices during practicum are discussed. 相似文献
12.
Eye‐rollers,risk‐takers,and turn sharks: Target students in a professional science education program
In classrooms from kindergarten to graduate school, researchers have identified target students as students who monopolize material and human resources. Classroom structures that privilege the voice and actions of target students can cause divisive social dynamics that may generate cliques. This study focuses on the emergence of target students, the formation of cliques, and professors' efforts to mediate teacher learning in a Master of Science in Chemistry Education (MSCE) program by structuring the classroom environment to enhance nontarget students' agency. Specifically, we sought to answer the following question: What strategies could help college science professors enact more equitable teaching structures in their classrooms so that target students and cliques become less of an issue in classroom interactions? The implications for professional education programs in science and mathematics include the need for professors to consider the role and contribution of target students to the learning environment, the need to structure an equitable learning environment, and the need to foster critical reflection upon classroom interactions between students and instructors. © 2006 Wiley Periodicals, Inc. J Res Sci Teach 43: 819–851, 2006 相似文献
13.
Parent and student perceptions of classroom learning environment and its association with student outcomes 总被引:2,自引:2,他引:2
This research is distinctive in that parents’ perceptions were utilised in conjunction with students’ perceptions in investigating
science classroom learning environments among Grade 4 and 5 students in South Florida. The What Is Happening In this Class?
(WIHIC) questionnaire was modified for young students and their parents and administered to 520 students and 120 parents.
Data analyses supported the WIHIC’s factorial validity, internal consistency reliability and ability to differentiate between
the perceptions of students in different classrooms. Both students and parents preferred a more positive classroom environment
than the one perceived to be actually present, but effect sizes for actual-preferred differences were larger for parents than
for students. Associations were found between some learning environment dimensions (especially task orientation) and student
outcomes (especially attitudes). Qualitative methods suggested that students and parents were generally satisfied with the
classroom environment, but that students would prefer more investigation while parents would prefer more teacher support.
The study provides a pioneering look at how parents and students perceive the science learning environment and opens the way
for further learning environment studies involving both parents and students. 相似文献
14.
The authors conducted ethnographic research to provide deep understanding of the learning environment of a selection of computer science classrooms at a large, research university in the United States. Categories emerging from data analysis included (1) impersonal environment and guarded behavior; and (2) the creation and maintenance of informal hierarchy resulting in competitive behaviors. Both of these categories describe patterns of recurring communication taking place in the classroom learning environments. We identify particular and recognizable types of discourse, which, when prevalent in a classroom, can preclude the development of a collaborative and/or supportive learning environment. Alternative communication choices, both explicit and implicit, can lead to a more balanced and supportive climate for learning. An example of a successful effort to alter traditional patterns of interaction, without compromising the quality of learning, in a higher education astrophysics class is presented. 相似文献
15.
Michalinos Zembylas 《科学教学研究杂志》2004,41(7):693-719
In this article, the role of young children's emotional practices in science learning is described and analyzed. From the standpoint of performativity theory and social‐constructionist theory of emotion, it is argued that emotion is performative and the expression of emotion in the classroom has its basis in social relationships. Arising from these relationships is the emotional culture of the classroom that plays a key role in the development of classroom emotional rules as well as the legitimation of science knowledge. These relationships are reflected in two levels of classroom dialogue: talking about and doing science, and expressing emotions about science and its learning. The dynamics of the negotiations of classroom emotional rules and science knowledge legitimation may dispose students to act positively or negatively toward science learning. This analysis is illustrated in the experiences of a teacher and her students during a 3‐year ethnographic study of emotions in science teaching and learning. This research suggests the importance of the interrelationship between emotions and science learning and the notion that emotional practices can be powerful in nurturing effective and exciting science learning environments. © 2004 Wiley Periodicals, Inc. J Res Sci Teach 41: 693–719, 2004 相似文献
16.
《Teaching and Teacher Education》1996,12(1):49-61
This study explored the classroom learning environments and instructional strategies of four teachers in culturally diverse classrooms. All teachers were deemed successful by their school colleagues, including administrators and instructional specialists, at meeting the needs of their culturally diverse students. The teachers in the study, who were teaching in four different regions of the U.S.A. and who represented different grade levels, taught in schools that contained richly diverse student populations. Using the constant comparative method of data analysis, I conducted a cross-case analysis of the teachers' learning environments. A primary focus of the research was the relationship between teachers' biographies and culturally sensitive classroom instruction. Three themes about culturally sensitive teaching emerged during data analysis: reshaping traditional school curriculum, rethinking the role of the teacher, and acquiring and using cultural sensitivity. Implications for preparing teachers for culturally diverse learning environments are discussed. 相似文献
17.
This study reports on the impact of a 2-month classroom intervention that sought to alter the learning environment of two
Hong Kong Primary Year 3 general studies classrooms. Mixed methodology, employing quantitative and qualitative data-gathering
strategies, was used to investigate changes to the learning environments, including changes to the teachers' language and
ultimately the students' metacognition. The quantitative facet of the research involved the development of a 15-item learning
environments instrument, the General Studies Metacognitive Orientation Scale (GSMOS), that evaluated elements of the metacognitive
orientation of the classrooms' learning environments. While the data from the administration of the GSMOS suggested no statistical
differences between the pre- and post-intervention environments of the classrooms, student interviews and classroom observations
provided supportive data for some changes, which resulted in students developing metacognitive knowledge of teacher-selected
thinking and learning strategies, as well as some awareness and limited control of their use of such strategies in their classrooms. 相似文献
18.
Thanita Lerdpornkulrat Ravinder Koul Chanut Poondej 《Tertiary Education and Management》2013,19(4):395-408
AbstractThe purpose of this study was to examine student perceptions of the learning environment in their program major and general education classrooms. The participants were 870 undergraduate students majoring in engineering, fine arts, education, economics and nursing programs at a university in Thailand. We found significant differences in the perceptions of the classroom learning environment across various disciplines. Engineering and economics students perceived the learning environment in general education classrooms as more cooperative than the learning environment in program major classrooms. Fine arts and nursing students perceived greater involvement among students in the program major classrooms than in the general education classrooms. Our findings contribute to the body of research on inter-disciplinary differences in classroom learning environments in universities and the ways in which these differences may impact student learning outcomes. 相似文献
19.
《Learning and Instruction》2000,10(3):249-266
Recent research on learning and instruction has substantially advanced our understanding of the processes of knowledge and skill acquisition. However, school practices have not been innovated and improved in ways that reflect this progress in the development of a theory of learning from instruction.It is argued in this article that to be successful in making psychological theory and research applicable to education one should develop a strategy that combines the following basic characteristics:
- •good communication with practitioners which means that the relevant outcomes are translated in such a way that they become palatable, accessible, and usable for the teachers;
- •an orientation toward a fundamental change of teachers' belief systems about the goals of education and about good teaching and productive learning;
- •a holistic (as opposed to a partial) approach to the teaching–learning environment, i.e. all relevant components of the learning environment should be addressed.
20.
The study of learning environments has developed into a productive field of research in science education. Initially, the
design and application of classroom perceptual measures of particular dimensions of science classrooms attracted much attention.
More recently, such instruments have been used alongside of qualitative techniques to provide a richer understanding of sub-environments.
We continue this trend in the present interpretive study by exploring the nature of multiple environments within a middle
school classroom from the different perspectives of teacher, student and participant observer. In particular, we examine the
activity settings of lectures and group work, as well as the issues of learning and assessment. We conclude by arguing that
teachers need to adopt procedures that enable them to identify and plan for multiple environments. 相似文献