An exploration of the pedagogies employed to integrate knowledge in work-integrated learning

This article describes a three‐sector, national research project that investigated the integration aspect of work‐integrated learning (WIL). The context for this study is three sectors of New Zealand higher education: business and management, sport, and science and engineering, and a cohort of higher educational institutions that offer WIL/cooperative education in variety of ways. The aims of this study were to investigate the pedagogical approaches in WIL programs that are currently used by WIL practitioners in terms of learning, and the integration of academic‐workplace learning. The research constituted a series of collective case studies, and there were two main data sources — interviews with three stakeholder groups (namely employers, students, and co‐op practitioners), and analyses of relevant documentation (e.g., course/paper outlines, assignments on reflective practice, portfolio of learning, etc.). The research findings suggest that there is no consistent mechanism by which placement coordinators, off‐campus supervisors, or mentors seek to employ or develop pedagogies to foster learning and the integration of knowledge. Learning, it seems, occurs by means of legitimate peripheral participation with off‐campus learning occurring as a result of students working alongside professionals in their area via an apprenticeship model of learning. There is no evidence of explicit attempts to integrate on‐ and off‐campus learning, although all parties felt this would and should occur. However, integration is implicitly or indirectly fostered by a variety of means such as the use of reflective journals

Sustainability of the chemical manufacturing industry - Towards a new paradigm?

This paper describes the current situation of the chemicalmanufacturingindustry, with special reference to Europe and looks to the future sustainability demands on the sector, and the implications of these demands for chemical engineering education. These implications include definitions of sustainability criteria for the sector and the need for transparent reporting under the Triple Bottom Line approach. The response of the education system to the sustainability agenda over the years and a number of strategies to incorporate it into courses are described. The important role of chemical (or more generally, process) engineers in delivering sustainable solutions is emphasised but this also suggests that anew way of thinking about the discipline is required. Indeed, this paper argues that the demand for a sustainable chemicalmanufacturing sector could bring about the next paradigm shift in the discipline which has been predicted for some time

Managing affect in learners' questions in undergraduate science

This is the author's accepted manuscript. The final published article is available from the link below. Copyright @ 2012 Society for Research into Higher Education.This article aims to position students' classroom questioning within the literature surrounding affect and its impact on learning. The article consists of two main sections. First, the act of questioning is discussed in order to highlight how affect shapes the process of questioning, and a four-part genesis to question-asking that we call CARE is described: the construction, asking, reception and evaluation of a learner's question. This work is contextualised through studies in science education and through our work with university students in undergraduate chemistry, although conducted in the firm belief that it has more general application. The second section focuses on teaching strategies to encourage and manage learners' questions, based here upon the conviction that university students in this case learn through questioning, and that an inquiry-based environment promotes better learning than a simple ‘transmission’ setting. Seven teaching strategies developed from the authors' work are described, where university teachers ‘scaffold’ learning through supporting learners' questions, and working with these to structure and organise the content and the shape of their teaching. The article concludes with a summary of the main issues, highlighting the impact of the affective dimension of learning through questioning, and a discussion of the implications for future research

Making use of icould: learning from practice

icould, is an online careers resource which provides individual’s with access to the work and life experiences of hundreds of people in the form of online careers films. The films are supplemented with labour market information and other resources. This approach seeks to provide both a self-directed resource for career explorers and a resource that can be used by career and education professionals to enhance their practice. In addition, icould provides a range of information, games, interactive activities and other resources that can also be used either directly by a career explorer or as underpinning resources for professionals working in the field. icould is a technically innovative product which utilises multi-media content, interactivity and social media in new ways to provide career support. icould has become popular with career professionals and other educators and is frequently used as part of the delivery of career support. icould has produced a very useful suite of resources for teachers to facilitate its use in practice. However, up until now there has been no investigation of the ways that icould is actually being used in practice. Consequently in this project we sought to draw this practice together and to present it in a way that might stimulate, inform and inspire future practice. To do this a diverse group of practitioners were recruited to form a community of practice (COP). This report provides new ideas and insights into the way which the icould website is used by practitioners

Rethinking the education of chemists - the odyssey is over, time for action!

Chemistry is a mature discipline with a distinguished pedigree and a long tradition, but times are changing and student numbers in chemistry are declining. The need for a reappraisal of what constitutes chemistry and a chemistry education at the beginning of the new millennium, is apparent. The paper examines some of the current issues surrounding chemistry and chemistry teaching and suggests ways in which we might go forward. A message of vision and imagination, applying a little of the ideals of Zarathustra in the setting of, '2001, A Chemistry Odyssey', is promulgated. [Chem. Educ. Res. Pract.: 2003, 4, 83-96]

The Practices of Play and Informal Learning in the miniGEMS STEAM Camp

Science, Technology, Engineering, and Mathematics (STEM) play an important role in the educational reform and global economy. However, STEM education lacks the hands-on laboratory in the formal middle school and high school curricula. The widespread gender gap in multiple STEM disciplines causes middle-school aged girls have lower positive attitudes and interests towards STEM fields than male students. In recent years, Science, Technology, Engineering, Arts, and Mathematics (STEAM) education has been viewed as other approaches to increase students’ interests and improve study accesses to STEM fields in the United States. The addition of the arts in STAEM education provides more learning opportunities and real-world contexts which meet more students’ interests. miniGEMS 2017 was a free two-week summer STEAM and programming camp for middle school girls in grades six to eight hosted by the Autonomous Vehicle Systems (AVS) Research and Education Laboratory at the University of the Incarnate Word (UIW). miniGEMS was the first free camp with a special focus on engineering and programming in San Antonio. The camp utilized project-based learning curriculum and provided multiple hands-on experiments, field trips, and significant interactions with guest speakers, all of which were designed to increase the middle school girls’ interests in STEM-related fields. This paper provides an overview of miniGEMS STEAM camp, motivation for miniGEMS camp, and details on practicing project-based play activities in an informal learning environment.Cockrell School of Engineerin

Using PeerWise to support the transition to higher education

© 2019 Contributing Author

Science-teacher education advanced methods national workshop for Scotland report

The first phase of the S-TEAM project at the University of Strathclyde - evaluating the state of the art of inquiry-based science teaching and education in teacher education institutions and schools in Scotland - is now well advanced. Phase one identifies the opportunities for and the constraints facing either the implementation or increase of inquiry-based science teaching activity in schools, in the process investigating impressions from current practice in classrooms, from teacher education courses, the policymaking context, as well as the implications for the S-TEAM project itself. All teacher education institutions within Scotland were invited to take part in a one-day workshop at the University of Strathclyde in Glasgow; representatives from the Scottish Government, Her Majesty's Inspectorate of education, a leading science centre, the Early Professional Learning project, and of course the teaching profession itself were also in attendance, giving a total of 19 participants. Key Findings The curriculum and assessment background to promoting advanced methods in science education in Scotland comprises the Curriculum for Excellence (CfE) initiative. The conference participants generally framed their contributions with this in mind. The findings suggested that the CfE, while still in its infancy, is generally supportive and encouraging of investigative science lessons, the range of possible activities that could count as investigative, and in the diversity of the ways in which scientists work. There was however some concern about the relationship between the CfE and Scotland's portfolio of upper-secondary school examinations, as yet unspecified in policy, and thus leaving open to question the degree to which the new curriculum will continue to support investigations as it currently is. Over emphasis on summative assessment through grading and examinations tend to work against the spirit of investigative activity in the science classroom, a practice that depends on a more sophisticated formative approach. There is the associated danger that schools may continue to garner exam success with more traditional teaching methods with the consequence that CfE, though clear enough in its intention to promote investigation / inquiry and creativity, could 'crystallise' into typical assessment styles. Teaching would then be guided by this and genuine investigative activity would be unlikely to develop in the face of the relative certainty (for teachers) of more 'direct' methods. The experience of the workshop delegates suggests that there are current examples of investigative science work in schools, and that these tend to be enjoyable for learners - exciting, good fun, etc. This affective dimension of learning is important and points to the need for S-TEAM to develop indicators that can accommodate affective engagement. Other 'harder' indicators could also be developed as discussion revealed that examination results and pupil uptake of science (girls in this case, helping to change possible preconceptions) could benefit from inquiry based activity. The efficacy of investigative activity in the classroom, however, is unlikely to be fully caught by the strictly quantitative. A further consideration is that S-TEAM could develop indicators that go beyond an immediate research function to operate in such a way as to contribute to the learning of teachers in the classroom through the capacity for practitioner self-evaluation. For example, the critical evaluation of investigative activity that a cohort of initial science-teacher education students have already completed for the project, as part of their professional portfolios, has since been commended by teacher educators as being an effective intervention in its own right. The early results from this indicator confirm the existence of a number of implicit components of developing confidence in undertaking investigative activity - for example, knowledge of the subject curriculum, class, resources, and so on - and teaching methods, from structured additions to the more opportunistic and ad hoc, that practitioners employ. While arguing that teachers could and ought to accommodate a degree of inquiry in their teaching, a critical caveat is that beginners benefit from protected exploratory practice prior to their full teaching post and need space themselves to investigate and explore; it is reasonable for them to exercise restraint in their first year until their confidence is fairly secure. Implications 1. Promote inquiry in teaching by using examples of existing good practice and by working with experienced teachers in order to take lessons back from them to beginners. 2. Develop purpose specific indicators of inquiry and reflection that go beyond an immediate research function to contribute to the learning of (new) teachers through a capacity for the self-evaluation of the use of innovative methods in the classroom. 3. Collate video examples of inquiry as it happens in the classrooms of student and practising teachers, as well as stories and reflective discussion about how it happened, so as to learn how teachers solve the problems of introducing more investigative approaches into lessons. 4. For the development of teachers' knowledge base in science, create a typology of investigative knowledge and experience, upon which the project's activities might draw, of the following levels of scientific perspective: The socio-historical nature of science. Contemporary research activity in science. Initial teacher education in science. Experienced teaching of science. Beginning teaching of science. The child's classroom experience of science. 5. For the ongoing practical application of inquiry-based research, S-TEAM will continue to pursue, interrogate and engage with existing examples of inquiry and resources in the months ahead