Spelling suggestions: "subject:"communmunication off cience"" "subject:"communmunication off cscience""
121 |
Student discourse in a natural science classroom : a case study of high school teaching in SwazilandSitsebe, Vusi Friday 07 1900 (has links)
The aim of the study was to investigate classroom discourse among high school natural science students in Swaziland.
The research problem was:
Can student interactions tell us something about the negotiation of understanding during natural science teaching?
A qualitative approach was used, specifically, the observational case study style. The population comprised three Form 4 students and their natural science teacher, purposely selected. Data was collected using the non-participant observation and the standardised open-ended interview methods.
The collected data was analysed using the discourse analysis approach. The analysed data indicated that prevailing discourse patterns were teacher and student talk, as well as written work.
A conclusion was that student classroom discourse in the natural sciences should be encouraged among all students for improved understanding and meaning making. / Science and Technology Education / M. Ed. (Natural Science Education)
|
122 |
Mot en delad framtid? : Mendeley som exempel på vetenskaplig kommunikation online / Towards a Shared Future? : Mendeley as an Example of Scientific Communication OnlineLundin, Kristina January 2012 (has links)
The last few years have been characterised by increasing online communication and the emergence of social media, made possible by Web 2.0. In society as well as in research, social media is used for knowledge produc- tion and networking. One example of this is Mendeley, a social reference management tool. With answers from users all over the world, this study investigates the use of Mendeley, if the respondents use other social media and if all of this affects scientific communication. The aim is also to study what the respondents think about the future of scientific communication and if this can be related to current tendencies. The theoretic framework for this study is based on Leah Lievrouws research on the Cycle of Scientific Communication and the relationship between the ”Little Science 2.0”-scenario and the ”Big Science Retrench- ment”-scenario. A qualitative web based survey was conducted (41 answers) and complemented with an interview with a professor in environmental sciences. The main purpose with the interview was to study how Mendeley can be used in collaborations. The results show that Mendeley is used by researchers to store and organize references, read and annotate pdf:s, cite, share articles in groups, search for new references and to present their research and make new ac- quaintances. The answers show that one effect that Mendeley and other social media has on scientific communi- cation is facilitating cooperation across traditional divides. At the same time, some respondents have not seen an effect on their scientific communication yet. Methods to measure impact in social media are requested, which would complement standard citation analysis. Mendeley’s related research function is found valuable in theory, but is in need of significant improvements. The respondents think that the future will be characterized by an increase in openness and sharing, but a tendency to keep scientific results copyrighted and locked behind pay- walls is also present. This is a two years master’s thesis in Library and Information science.
|
123 |
Enhancing discourse through motivation : a case study of high school teaching in SwazilandSitsebe, Vusi Friday 30 January 2019 (has links)
Communication seems to play a pivotal role in any high school classroom. But it was found those classes or certain individual students shy away from engaging in effective communication during natural science lessons in Swaziland. One of the directives in the Swaziland National Education Policy states that syllabuses for studies in Form 4 and 5 should enable learners to develop essential skills which include communication and language skills. This study then, on realising that there was a gap between what was stated in the Education Policy and what was actually the case in the natural science classrooms, sought for a solution that would encourage effective communication in natural sciences. Therefore, the main purpose of the study was to encourage active participation of high school students in natural science lessons. The main research question posed for this purpose was:
Can student motivation enhance classroom discourse for the negotiation of science understanding?
Five sub-questions emanated from the main research question:
(a) How does classroom discourse relate to natural science understanding?
(b) What effect does external motivation have on discourse during natural science lessons?
(c) What is the effect of feedback during natural science learning?
(d) How can feedback be enhanced in the natural science class?
(e) Which teaching strategies improve interactions during natural science learning?
The study is organised into five chapters. The first chapter summarises the whole study by giving the problem statement, research aim and objectives, definition of terms, as well as chapter divisions. Chapter two provides the background to the study through the discussion of education theories based on classroom discourse and motivation. The third chapter presents detailed information about the research design, methods of data collection and analysis, as well as a proposed method for motivating students. The fourth chapter presents the research results, analysis and discussion. The fifth and the final chapter presents research findings, concluding remarks drawn from the research findings, as well as recommendations for similar future research.
The case study style uses a qualitative, descriptive and exploratory approach. The study concentrated on theories explaining learning and motivation. The sample comprised six purposefully selected students and their two physical science teachers. Data were collected using the standardised open-ended interview and non-participant lesson observation methods, and from documents. The data were collected in two phases, the pre-motivation phase and the motivation phase. The collected data was further categorised into two segments, with each segment being a unit of analysis. One of the segments was composed of oral interchanges, while the other was composed of students’ written work. The data was then transcribed, coded, analysed and discussed using the thematic discourse analysis approach. The principles of triangulation, reliability and validity ensured the credibility of the study remained intact. Research ethics were also observed by the researcher and there was trust, respect and autonomy during data collection. The ethics observed included informed consent, confidentiality, beneficence, anonymity and non-malificence. Permission to collect data was sought and obtained from all concerned.
The motivation method helped the physics group improve more (55%) than the chemistry group (7%) in tests. In the overall performance the two groups improved more or less the same: the chemistry group improved by 4% while the physics group improved by 5%. There were three main findings for the study and they revolved around the purpose and the research question. The first major finding was that the motivation method used with the students instilled self-discipline in the students, resulting in self-regulated behaviour and better understanding of science concepts. The finding suggested that motivated students are self-disciplined and take ownership of their learning. The second major finding was that during the motivation phase of data collection interactions improved between the students and their science teachers. These interactions were in the form of classroom talk, submission of school work and feedback. It was inferred that motivated students communicate more effectively and with better understanding of the concepts taught. The third major revelation was that the students were motivated by learner-centred teaching strategies and the use of teaching aids in a science laboratory.
A main finding for the first sub-question was that the more students interacted with each other, with their natural science teachers, and with their books the more they appreciated and understood science concepts. For the second sub-question the main finding was, the motivation method used with the students improved discourse during natural science lessons. The marks the students were awarded gave them the energy to engage more in science activities and to behave well. The main finding for the third sub-question was that prompt feedback and positive comments motivated students to engage more in science discourse and to understand science concepts better. An important finding from the fourth sub-question was that prompt and positive feedback enhanced feedback, as well as giving students tasks that were not too far above their abilities, enhanced feedback in the natural science class. For the fifth sub-question it was found that student-centred teaching methods as well as teaching aids and learning in science laboratories improved interactions during natural science learning. / Curriculum and Instructional Studies / D. Ed. (Curriculum Studies)
|
Page generated in 0.1297 seconds