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1.
We investigated differences between field-study classrooms and traditional science classrooms in terms of the learning environment and students’ attitudes to science, as well as the differential effectiveness of field-study classrooms for students differing in sex and English proficiency. A modified version of selected scales from the What Is Happening In this Class? questionnaire was used to assess the learning environment, whereas students’ attitudes were assessed with a shortened version of a scale from the Test of Science Related Attitudes. A sample of 765 grade 5 students from 17 schools responded to the learning environment and attitude scales in terms of both their traditional science classrooms and classrooms at a field-study centre in Florida. Large effect sizes supported the effectiveness of the field-studies classroom in terms of both the learning environment and student attitudes. Relative to the home school science class, the field-study class was considerably more effective for students with limited English proficiency than for native English speakers. 相似文献
2.
During their years of schooling, students develop perceptions about learning and teaching, including the ways in which teachers
impact on their learning experiences. This paper presents student perceptions of teacher pedagogy as interpreted from a study
focusing on students' experience of Year 7 science. A single science class of 11 to 12 year old students and their teacher
were monitored for the whole school year, employing participant observation, and interviews with focus groups of students,
their teacher and other key members of the school. Analysis focused on how students perceived the role of the teacher's pedagogy
in constructing a learning environment that they considered conducive to engagement with science learning. Two areas of the
teacher's pedagogy are explored from the student perspective of how these affect their learning: instructional pedagogy and
relational pedagogy. Instructional pedagogy captures the way the instructional dialogue developed by the teacher drew the students into the learning process and enabled
them to “understand” science. How the teacher developed a relationship with the students is captured as relational pedagogy, where students said that they learned better when teachers were passionate in their approach to teaching, provided a supportive
learning environment and made them feel comfortable. The ways in which the findings support the direction for the middle years
and science education are considered. 相似文献
3.
Catherine Martin-Dunlop Barry J. Fraser 《International Journal of Science and Mathematics Education》2008,6(1):163-190
This study assessed the effectiveness of an innovative science course for improving prospective elementary teachers’ perceptions
of laboratory learning environments and attitudes towards science. The sample consisted of 27 classes with 525 female students
in a large urban university. Changing students’ ideas about science laboratory teaching and learning and creating more positive
attitudes towards science were accomplished by using a guided open-ended approach to investigations, together with instructors
who used cooperative learning groups to create a supportive environment. Ideas and attitudes prior to the course were assessed
using a questionnaire focusing on the students’ previous science laboratory courses, and these were compared to data collected
at the end of the course. Students reported large and statistically significant improvements on all seven scales assessing
the laboratory learning environment and attitudes towards science. The largest gains were observed for Open-Endedness and
Material Environment (with effect sizes of 6.74 and 3.82 standard deviations, respectively). An investigation of attitude-environment
associations revealed numerous positive and statistically significant associations in both univariate and multivariate analyses.
In particular, the level of Instructor Support was the strongest independent predictor of student attitudes at two levels
of analysis. 相似文献
4.
Lisa Incantalupo David F. Treagust Rekha Koul 《Journal of Science Education and Technology》2014,23(1):98-107
The use of technology in schools is now ubiquitous, but the effectiveness on the learning environment has mixed results. This paper describes the development and validation of an instrument to measure students’ attitudes toward and knowledge of technology with the aim of investigating any differences based on gender after a course where the science department made use of technology as an integral part of teaching biology. In this study, conducted in one school in the state of New York, in the United States of America, the Students’ Attitudes Toward and Knowledge of Technology Questionnaire was administered to nearly 700 high school science students. A principal component and principal factor analysis resulted in new scales from the validation of the instrument that demonstrated high reliabilities. There were statistically significant gender differences in all the scales of the questionnaire in favor of males. 相似文献
5.
The interpretation of data and construction and understanding of graphs are central practices in science; therefore, an important skill needed in the undergraduate physics laboratory is the ability to analyze data obtained from experiments. Often students are not able to reach logical deductions based on data, acquired from the experiments that they conducted, because they lack appropriate analysis skills. The aim of this study is to evaluate the effectiveness of a short teaching unit developed for this purpose, among undergraduate students. Learning in context approach was implemented in building the unit. Also, both procedural and conceptual knowledge were given emphasis. The “data analysis” questionnaire was used to compare the results between the experimental group and control group. The findings indicate that students who participated in the teaching unit arrived at significantly better results in the data analysis questionnaire as compared to students in the control group. This study may contribute to those who wish to design a contextual-based learning environment for physics laboratory data analysis. 相似文献
6.
The constructivist paradigm opens abundant opportunities for effective knowledge construction in which student build knowledge and continually evaluated and improved their knowledge. The teaching mode under constructivist pedagogy redefines the role of students and the teachers and their interrelationships by creating a nurturing environment. By adapting constructivist framework, this article demonstrates how the variation of learning practices was critical in facilitating Primary 4 students in Singapore to carry out seamless science learning. The variation of learning practices enables the students to explore a particular scientific concept through various learning experience across the contexts. The study adapted the framework of the Objects of Constructivist Learning Model for the improvement of the seamless science learning design. When redesigning the lesson, a conscious effort was made by the teacher to create relevant patterns of variation, that is, varying certain critical aspect(s) while keeping other aspects of the object of learning invariant in order to help students discern those critical aspects. The findings contribute knowledge to how the Theory of Variation can be used in analyzing seamless learning as well as designing for constructivist learning experiences. The findings have also demonstrated that the complementary practice of constructivist pedagogy with variation theory as a viable and effective approach in seamless science learning, at which it deepened students' understanding through constructing the critical aspects of a phenomenon. Engagement with primary school students in experiencing the variations allowed the translation of theory into practice. 相似文献
7.
Effectiveness of student response systems in terms of learning environment,attitudes and achievement
In order to investigate the effectiveness of using Student Response Systems (SRS) among grade 7 and 8 science students in New York, the How Do You Feel About This Class? (HDYFATC) questionnaire was administered to 1097 students (532 students did use SRS and 565 students who did not use SRS). Data analyses attested to the sound factorial validity and internal consistency reliability of the HDYFATC, as well as its ability to differentiate between the perceptions of students in different classrooms. Very large differences between users and non-users of SRS, ranging from 1.17 to 2.45 standard deviations for various learning environment scales, attitudes and achievement, supported the efficacy of using SRS. 相似文献
8.
Because there has been very little past research into gifted students’ science learning environments, especially in Singapore, we selected from four established questionnaires six learning environment scales that are consistent with Van Tassel-Baska and Stambaugh’s guidelines for gifted education. These scales were modified slightly to enhance suitability for the target population and refined further based on feedback from teachers and students in a pilot study. Data from administration of the questionnaires to 722 gifted science students in grades 9 and 10 were analysed to provide support for the questionnaire’s factorial validity, internal consistency reliability, ability to differentiate between classrooms, and predictive validity (in terms of associations with self-efficacy). To evaluate a new one-student one-laptop program being implemented for the first time, we compared the learning environments of this program with regular classrooms and found higher levels of perceived investigation, task orientation, collaboration, computer usage and formative assessment in technology-based classrooms.
相似文献9.
Rob Toplis 《Research in Science Education》2012,42(3):531-549
This paper reports an interpretive study that sought students' views about the role that practical work plays in their school
science lessons. Twenty-nine students aged between 13 and 16 years were selected from three secondary schools in England.
Data were collected from initial lesson observations and in-depth interviews in order to explore students’ views about practical
work. The findings suggest that students have three main reasons why practical work is important in their school science lessons:
for interest and activity, including social and personal features such as participation and autonomy; as an alternative to
other forms of science teaching involving a pedagogy of transmission, and as a way of learning, including memorizing and recall.
The findings are discussed in the context of a critical view of previous work on the role of practical work, work on attitudes
to science and on the student voice. The paper concludes that practical work is seen to provide opportunities for students
to engage with and influence their own learning but that learning with practical work remains a complex issue that needs further
research and evaluation about its use, effectiveness and of the role of scientific inquiry as a component of practical activity. 相似文献
10.
This case study explores how a group of Grade 9 students engaged in sociopolitical discourses and actions in a science class in a mostly indigenous student school in Nepal. The study used sociopolitical consciousness (SPC) as a framework to document and understand indigenous students’ SPC-oriented science interactions and subsequent social change actions. We used ethnographic methods of data collection over 6 months. The study focused on the actions of 4 girls and 2 boys belonging to the indigenous Tharu group. Data were analyzed using iterative qualitative methods. The study findings show that students are capable of engaging in critical thinking, critical reflecting, and taking actions for social change. Additionally, students are competent to link their experiences with social, structural, and political discrimination to the relevant science content they learn. The study presents four thematic findings related to SPC and science teaching and learning: Fostering social justice awareness in science class, fostering structural understanding of inequities in sickle cell disease, fostering sociopolitical actions for sickle cell disease, and the teacher's activist pedagogy for SPC in science learning. Implications of the study are that culturally relevant pedagogy helps indigenous students to become sociopolitically more aware of the links between science and social change. Adding aspects of critical pedagogies in science teaching could encourage students to become more sociopolitically reflective about science learning. 相似文献
11.
Miri Barak 《Journal of Science Education and Technology》2017,26(5):459-469
The new guidelines for science education emphasize the need to introduce computers and digital technologies as a means of enabling visualization and data collection and analysis. This requires science teachers to bring advanced technologies into the classroom and use them wisely. Hence, the goal of this study was twofold: to examine the application of web-based technologies in science teacher preparation courses and to examine pre-service teachers’ perceptions of “cloud pedagogy”—an instructional framework that applies technologies for the promotion of social constructivist learning. The study included university teachers (N = 48) and pre-service science teachers (N = 73). Data were collected from an online survey, written reflections, and interviews. The findings indicated that university teachers use technologies mainly for information management and the distribution of learning materials and less for applying social constructivist pedagogy. University teachers expect their students (i.e., pre-service science teachers) to use digital tools in their future classroom to a greater extent than they themselves do. The findings also indicated that the “cloud pedagogy” was perceived as an appropriate instructional framework for contemporary science education. The application of the cloud pedagogy fosters four attributes: the ability to adapt to frequent changes and uncertain situations, the ability to collaborate and communicate in decentralized environments, the ability to generate data and manage it, and the ability to explore new venous. 相似文献
12.
The main objective of this research was to use learning environment and attitude scales in evaluating online resource materials for supporting a traditional mathematics curriculum. The sample consisted of 914 middle-school students in 49 classes. A second research focus was the validation of the chosen learning environment questionnaire, the Technology-Rich Outcomes-Focused Learning Environment Inventory (TROFLEI), with an ethnically-diverse sample of middle-grade mathematics students in Florida. Finally, we complemented quantitative questionnaire data with qualitative interview data that were analysed thematically. In addition to cross-validating the TROFLEI, our study suggested that the online resource provided neither much advantage nor much disadvantage. 相似文献
13.
Mad City Mystery: Developing Scientific Argumentation Skills with a Place-based Augmented Reality Game on Handheld Computers 总被引:3,自引:5,他引:3
While the knowledge economy has reshaped the world, schools lag behind in producing appropriate learning for this social change.
Science education needs to prepare students for a future world in which multiple representations are the norm and adults are
required to “think like scientists.” Location-based augmented reality games offer an opportunity to create a “post-progressive”
pedagogy in which students are not only immersed in authentic scientific inquiry, but also required to perform in adult scientific
discourses. This cross-case comparison as a component of a design-based research study investigates three cases (roughly 28
students total) where an Augmented Reality curriculum, Mad City Mystery, was used to support learning in environmental science.
We investigate whether augmented reality games on handhelds can be used to engage students in scientific thinking (particularly
argumentation), how game structures affect students’ thinking, the impact of role playing on learning, and the role of the
physical environment in shaping learning. We argue that such games hold potential for engaging students in meaningful scientific
argumentation. Through game play, players are required to develop narrative accounts of scientific phenomena, a process that
requires them to develop and argue scientific explanations. We argue that specific game features scaffold this thinking process,
creating supports for student thinking non-existent in most inquiry-based learning environments. 相似文献
14.
Augmented reality (AR) offers potential advantages for intensifying environmental context awareness and augmenting students’ experiences in real-world environments by dynamically overlapping digital materials with a real-world environment. However, some challenges to AR learning environments have been described, such as participants’ cognitive overload and the ways to provide assistance in constructing the presented learning materials. In this study, a mindtool-based AR learning system was developed, based on the repertory grid method and the contiguity principle of multimedia learning, for assisting students in constructing their knowledge in a natural science course. Furthermore, an experiment was carried out on an elementary school natural science course to compare the influences of this method with those of the conventional AR learning system on students’ learning effectiveness. The experimental results show that the designated approach effectively promoted the students’ learning achievements, and no significant difference existed between the mindtool-based AR learning system and the conventional AR learning system in terms of students’ cognition load and satisfaction degree; moreover, both the experimental group and the control group perceived low cognition load during the learning activity and rated their own AR learning systems as being highly satisfactory. 相似文献
15.
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
16.
Weishen Wu Huey-Por Chang Chorng-Jee Guo 《International Journal of Science and Mathematics Education》2009,7(1):207-233
This study developed, validated, and utilized the Technology Integrated Classroom Inventory (TICI) to examine technology-integrated
science learning environments as perceived by secondary school students and teachers. Using technology-oriented classroom
climate instruments and considering the science classroom’s characteristics, TICI was developed. More than 1,100 seventh through
ninth grade science students validated the instrument, revealing eight scales: technological enrichment, inquiry learning,
equity and friendliness, student cohesiveness, understanding and encouragement, competition and efficacy, audiovisual environment,
and order, with alpha reliabilities ranging between 0.69 and 0.91 (0.93 for the entire questionnaire). In measuring actual
and preferred learning environments, TICI results indicated that both students and teachers ranked equity and friendliness
highest. The largest actual–preferred discrepancy was order (students) and inquiry learning (teachers). TICI offers additional
utilities for technology-enriched science leaning environments. 相似文献
17.
Kim Jesper Herrmann Anna Bager-Elsborg Anna Parpala 《Scandinavian Journal of Educational Research》2017,61(5):526-539
While focus on quality in Danish higher education has been growing in recent years, limited attention has been devoted to developing and thoroughly validating instruments that allow collecting data about university students’ perceptions of the teaching-learning environment. Based on data from a large sample of Danish university students, a Danish version of the Learn questionnaire was validated using confirmatory and exploratory factor analysis. Analyses confirmed the existence of three scales reflecting students’ approaches to learning and six scales reflecting students’ perception of the teaching-learning environment. The results suggest that the Danish version of Learn is a valid instrument to be used for evaluation of the teaching-learning environment as well as for research into Danish university students’ learning strategies. 相似文献
18.
Fu-Yun Yu 《Interactive Learning Environments》2019,27(2):226-241
In view of contribution-based pedagogy and observational learning theory, students’ perceived uses, preferences, usage, and selection considerations with regard to citing peers’ work were examined in an online learning environment targeting student-constructed tests. Data were collected from 84 fifth-grade students who participated in online student-constructed tests with and without citing in an 11-week study. Quantitative and qualitative data in response to an end-of-session questionnaire and actual online citing behaviour were analyzed. Several major findings were obtained. First, significantly more participants supported and preferred “citing” over “no citing” for online student-constructed tests. Second, data with regard to perceived uses, preferences, and reported usage all supported the potential of citing for providing an observational learning space. Third, citing allowed the participants to attend to areas pinpointed by their peers but initially ignored by them, thus making social construction of knowledge possible. Fourth, the quality and the author of the item are the two determining factors affecting citing decisions. Fifth, a statistically significant positive correlation between students’ academic achievement and their generated questions cited by peers was confirmed. Finally, actual online citing behaviour varied greatly among participants, with the majority using the citing function during online test-construction to various extents. 相似文献
19.
Deidra J. Young 《Educational Research and Evaluation》2013,19(2):129-158
ABSTRACT The International Association for the Evaluation of Educational Achievement (IEA) Second International Science Study (SISS) was conducted in 1984, resulting in a vast amount of educational data collected from 23 countries and educational systems. This research study reports on the analyses of 12 of those countries using multilevel modeling, investigating the relationships between the students’ reported perceptions of the science learning environment and their science achievement when controlling for student background variables. The three science learning environment scales which were collected in the SISS and analysed here were Student Participation, Teacher Directed Learning and Practical Work. Additionally, this research reports on the effect of these science learning environment scales on gender and socioeconomic differences in science achievement. 相似文献
20.
Ashraf Shady 《Cultural Studies of Science Education》2014,9(1):31-51
Classrooms across the United States increasingly find immigrant science teachers paired with urban minority students, but few of these teachers are prepared for the challenges such cultural assimilation presents. This is particularly true in secondary science education. Identifying potential prospects for culturally adaptive pedagogy in science education is important for students and teachers alike because it provides means for increasing marginalized students’ access to science fields. In this autoethnography, I document my experience as an immigrant science teacher in an urban intermediate school in New York City. Although I possessed the content knowledge highly valued by the current neoliberal agenda, I lacked the cultural adaptivity necessary to foster a successful learning environment. I utilized cogenerative dialogue (cogen) as a tool to ameliorate instances of cultural misalignments and improve teaching and learning in my classroom. The results of the study show that the interstitial culture produced through the implementation of the different forms of cogen became a reference point to draw upon in improving the overall learning environment. 相似文献