192 resultados para teaching science
Resumo:
Developing relevant and innovative University courses is a complex and often difficult task. This is particularly true when developing environmental science courses as the banner of environmental science has the potential to include an extremely vast array of subject material and course content. Added to this is the diversity of students entering these courses, and their associated course expectations and aspirations. A third component that cannot be ignored when developing courses includes employer demands and expectations of graduates at course completion. As tertiary educators we therefore have the challenge of developing innovative environmental science courses that are academically challenging, but meet the expectations of students, staff and potential future employers. To ensure that we meet this challenge it is vital that we determine the expectations of all relevant parties (students, staff, and potential employers) and develop our courses accordingly. Here we report on the 'student expectations' component of this. To determine student expectations we conducted a survey of all commencing first year environmental science students. The survey asked students to provide information on drivers for course selection, preferred learning styles, the importance of different approaches to teaching, subject interest areas and employment aspirations. Our results found that environmental science students have a preference for fieldwork and hands-on experience and are very supportive of teaching that combines different teaching methods. On-line teaching was not supported by commencing environmental science students. Commencing students showed a very strong interest in key subject areas of environmental science such as Wildlife, animal conservation, national and marine parks, conservation and marine Wildlife; however, some of the critical areas of environmental science such as population statistics, social sciences and chemistry did not attract the same level of interest. Most commencing students had some idea on where they would like to gain employment on course completion. Knowledge relating to student expectations is Vital, particularly when designing courses, developing specific unit content and undertaking marketing and course information sessions. With this knowledge we can be confident that students enrolling in environmental science will, to a large extent, have their expectations met.
Resumo:
Building environmental services can often be categorised as ‘one of the least desirable courses’ in the curriculum of architecture and building. Nevertheless, it is also one of the most important and confronting subjects in the procurement of real building projects. The principal message to designers is that of spatial requirements while to the builders it may become one of capital cost, installation specifications and maintenance of equipment. Getting these concepts across in a creative, yet project oriented, manner can be challenging to the students and to the lecturer. This paper presents the developments of ten years of teaching the subject, as well as the methods of delivery which have proven to be successful.
Resumo:
This paper is a case study of the introduction of a studio environment for the teaching of multimedia practice. This change is in the context of multimedia being placed within an information technology degree program, where the conventions and traditions of computer science prevail. The studio based teaching was accepted and now new studios are being built at the university and a research project is proposed with the Queensland University of Technology to explore further teaching and learning issues using studio
teaching methods.
Resumo:
Calls for major curriculum reform, arguing that the time has passed for tinkering around the edges of a science curriculum that belongs to the past.
Resumo:
In recent years there has been a significant shift in the way courses and subjects are delivered to students in tertiary institutions. Advances in technology have resulted in a change to the traditional face-to-face lecture and tutorial teaching format, with many subjects in tertiary education now available online. Although research has explored the advantages and disadvantages of online learning, there has been little attention paid to this teaching format in the field of environmental science. In particular, there is little evidence in the literature to suggest that this method of teaching is appropriate for studies in environmental science or for environmental science students. This study examined the outcomes from a wholly online subject in environmental science at Deakin University, Australia. More specifically, the study aimed to investigate student views about online learning in environmental science as well as online group work. Questionnaires were distributed to all students who completed the core second year subject Society and Environment in semester 1, 2005. Although many of the responding students (n = 48) recognised the benefits of wholly online learning, the findings suggest that most prefer to learn in a face-to-face environment. This paper examines the implications of these findings for future online teaching methods in this discipline.
Resumo:
The concept of blended learning has begun to change the nature of all teaching and learning in higher education. Information and communication technologies have impacted by providing a means of access to digital resources and interactive communication for all courses and the blending of pedagogy and technology has produced a range of approaches to teaching and learning. This paper discusses the research literature and the writers’ research, defining what they have concluded are teaching practices that use the concept of blended learning effectively. In investigating how ICT can add variation for student learning, they analyze this from two dominant modes of pedagogy, learning environment and pedagogy through both on-campus and distance education. In both modes, students acknowledged the power and effectiveness of blended learning.
Resumo:
‘School Innovation in Science’ represents a model, developed through working with more than 200 Victorian schools, to improve science teaching and learning. SIS works at the level of the science team and the teacher, providing resources to challenge and support the change process. Its emphasis is on strategic planning supported by a framework for describing effective teaching, materials for auditing practice and planning initiatives, and a networked support structure. Experience and results from the project, concerning the nature and extent of change, will be used to provide insight into the multidimensional nature of the change process and to suggest a number of principles concerning support for change. Arising out of this, the major elements of a School Innovation Model are identified, that supports a transformative agenda for schools more generally.
Resumo:
The author stresses the need for schools and science teachers to develop new approaches to attract the imagination of students in Australia. He believes that changes in the nature of post-industrial societies and in the accessibility of science knowledge and youth expectations are the culprits of crisis in science education. He argues that schools and teachers should re-examine the purposes of school science. He suggests that science re-imagining needs to be supported by national effort, create teacher development and training initiatives and assessment.
Resumo:
As the number of students pursuing mathematics and science in higher education decline, it becomes imperative· that we look for the causes of the decline. As part of the Australian Improving Middle Years Mathematics and Science (IMYMS) project, students were asked to rate their perceptions of classroom practice in mathematics and science and their attitudes to these subjects. Results of this survey reveal little difference in perceptions of classroom practice, but significant differences in students' attitudes between mathematics and science. Differences were particularly evident for items relating to the usefulness of mathematics and science (mathematics was more useful) and enjoyment of the subjects (science is more fun). If teachers are aware of such perspectives, it may be possible to change students' attitudes.
Effective student engagement depends on students enjoying their studies in mathematics and science, being confident in their ability and recognising the relevance of these subjects to everyday life, now and in the future.
(Education Training Committee, 2006, p. xvii)
Science and technology are the widely acknowledged foundation of Australia's future development. Underpinning these are the key learning areas of mathematics and science. However, Australia is experiencing a decline in numbers of mathematics and science students in higher education. Moreover, studies over the last two decades have shown a general decline in Australian students' interest and enjoyment of science across the compulsory secondary school years, with a particularly sharp decline across the primary to secondary school transition (e.g. Adams, Doig, & Rosier 1991; Goodrum, Hackling, & Rennie, 200 I) and a decline in the numbers of students studying' advanced mathematical courses in upper secondary school (Thomas, 2000).
Improving teaching and learning in the middle years of schooling (Years 5 to 9) is receiving particular attention because of the coincidence of the disengagement of students with the significance of these years for the preparation of students for their future role in society. Thus the Improving Middle Years Mathematics and Science: The role of subject cultures in school and teacher change (IMYMS) project, which is the source of data for this paper, is investigating the role of mathematics and science' knowledge and subject cultures in mediating change processes in the middle years of schooling.
Mathematics and science are sometimes seen as "love-hate" subjects, rating highest for subjects disliked, but also rating relatively highly among preferred subjects (Hendley & Stables, 1996). Students, even primary aged students, can often shed light on what constitutes good practice (see, for example, 'van den Heuvel-Panhuizen, 2005). Students' attitudes towards mathematics and science and their perceptions of what they regard as positive aspects of classroom practice have been shown to decline from the primary years to junior secondary (Race, 2000). The decline in interest in science in the early years of secondary school is of particular concern, since it is in these years that attitudes to the pursuit of science subjects and careers are formed (Speering & Rennie, 1996). Students' negative attitude towards the relevance of science ,content for their lives was a strong theme in the report by Goodrum, Hackling, & Rennie (2001) on the status and quality of teaching and learning of science.
As part of the IMYMS project, the IMYMS Student Survey was administered to all students in 2004 and 2005. The survey included a 36 item section on students' perceptions of classroom practice and attitudes towards mathematics and science, and a 24 item section on students' learning preferences. Students completed separate, parallel surveys for mathematics and science.
This paper focuses on students' perceptions and attitudes. It explores the differences in 700 Year 5 and 6 students' perceptions of their learning environment and their attitudes to mathematics and science during 2005, the second (and final) year of schools , involvement in the IMYMS project.
Resumo:
Situated in regional areas of Victoria, a group of 16 primary and secondary teachers participated in an intensive program of professional development designed to assist them in embedding lCT into their classroom practice. Most teachers made significant changes to their teaching practice becoming risk-takers and problem solvers.This paper reports on the strategic innovations introduced by the teachers including training, preparation, curriculum planning, software evaluation and selection, classroom management strategies, cooperative learning strategies and embedded assessment tasks. The paper will explore the ways these innovations responded to a variety of constraints including limited resources, time and support.
Resumo:
This collection of fourteen essays by renowned scholars in the field of Holocaust studies seeks to reflect on the experience of teaching and researching this complicated and emotional topic. Contained within are the pioneering stories of those presently engaged in the work of Holocaust education. Separately, they represent a variety of disciplines and orientations. Collectively, they give evidence of the strong commitment to continue this important work, and the moral and ethical demands such teaching, writing, and research place upon all who engage in it. Different perspectives from historical, philosophical, and religious frameworks come together to create a unique contribution to the literature on the Holocaust. Educators discuss what they teach, their methodologies and theoretical orientations and reflect on their own journeys that brought them to this field. The unique nature of these stories bring needed background to the field of Holocaust studies and also serve to inspire others to enlarge their thinking and understanding of previous work on this topic. The stories of these committed Holocaust educators will serve to inspire a new generation of thinkers, writers, and activists to engage in such work. In reading their stories, their collective commitment to make a difference today and tomorrow shines through. This volume will be a valuable resource for courses in the Holocaust, contemporary post-Holocaust realities, as well as courses in genocide. Scholars and anyone with an interest in enriching their understanding of the Holocaust will find much within to inspire them and provoke new ideas.
Resumo:
Science education is in crisis, which is evidenced by the increasing negative attitudes to Science by secondary school students and decreasing participation in post compulsory Science subjects. There is a need for re-imagining science by adopting contextual learning.
