The Potential of Non-Formal Laboratory Environments  for Innovating the Chemistry Curriculum and Promoting Secondary School Level Students Education for Sustainability

Garner, Nicole; Siol, Antje; Eilks, Ingo

doi:10.3390/su7021798

Cited by 26 publications

(39 citation statements)

References 50 publications

(60 reference statements)

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“…Only very few non-formal laboratory-based science learning courses, as e.g. described in Garner, Siol & Eilks (2015) or Affeldt, Tolppanen, Aksela & Eilks (2017) have thus far been described using comics in intense practical work but did not present findings about their use from a student perspective.…”

Section: General Frameworkmentioning

confidence: 74%

The Use of Comics in Experimental Instructions in a Non-formal Chemistry Learning Context

Affeldt¹,

Meinhart²,

Eilks³

2018

International Journal of Education in Mathematics, Science and Technology

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Practical work is an essential component of science education. However, insufficient approaches towards practical work can limit the potential it has for promoting both students' motivation and situational interest. One suggestion to solve this problem is to use alternative forms of lab instruction which are both motivating and easy to comprehend. One potential avenue is the increased use of pictorial information instead of pure text-based approaches. This case describes the use of comics in experimental instructions in non-formal chemistry learning. Comics visualise stories, are viewed as comprehensible to students, and also allow instructors to connect scientific tasks with authentic situations taken from students´ lives. This paper describes a study of 6th grade students´ perceptions (age range 11-13 years) of using comic-based lab instructions in a non-formal inquiry-based laboratory learning environment which focused on the chemistry of water quality. Semi-structured interviews of pairs of students were conducted during their visits to the non-formal laboratory. These 22 interviews (44 students total) were then analysed using qualitative content analysis. Overall, very positive perceptions by the students could be identified with respect to comicbased experimental instructions. Further research on the most promising use of comics in science education is needed.

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Section: General Frameworkmentioning

confidence: 74%

The Use of Comics in Experimental Instructions in a Non-formal Chemistry Learning Context

Affeldt¹,

Meinhart²,

Eilks³

2018

International Journal of Education in Mathematics, Science and Technology

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“…The integration of ESD requires the nurturing of skills for the care and protection of the environment such as solution finding and multifaceted problem solving in the real world (Warner & Elsier, 2015). Similarly, there is an increasing integration of green or sustainable chemistry in chemistry education as a way of implementing ESD (Karpudewan et al, 2012;Bertolin et al, 2013;Makoni, 2013;Jegstad & Sinnes, 2015;Garner, Siol & Eilks, 2015). The purpose of the study was to develop and implement placebased pedagogy activities for the integration of ESD and green chemistry in the teaching and learning of the environmental chemistry component of the Zimbabwe schools examination council (ZIMSEC) physical science 5009 syllabus in rural settings.…”

Section: Tsakenimentioning

confidence: 99%

“…The frameworks have an ultimate goal of reducing and/or eliminating the generation and release of toxic materials (Garner et al, 2015;Karpudewan, Ismail & Mohamed, 2011). Burmeister, et al (2012) mention four ways to integrate green chemistry into chemistry education.…”

Section: Education For Sustainable Development Through Green Chemistrmentioning

confidence: 99%

“…Green chemistry is based on the 12 principles as propounded by Anastas and Warner, 1998. Summarised, the principles advocate for the prevention of excessive generation of waste, the reduction of excessive consumption of materials including energy and the prevention of the release of hazardous chemicals into the environment (Karpudewan et al, 2012, Garner, Siol & Eilks, 2015Warner & Elsier, 2015). Instructional strategy implications include the use of local place examples as a springboard to understand global environmental issues.…”

Section: Introductionmentioning

confidence: 99%

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The promotion of sustainable environmental education by the Zimbabwe Ordinary level science syllabi

Tsakeni

2017

PiE

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“…Interestingly, while there is no specific course in green chemistry for bachelor chemistry students, laboratories in the University of Bremen offer practical work for secondary school students to conduct experiments focusing sustainability and green chemistry (Garner, Siol & Eilks, 2015;Affeldt, Weitz, Siol, Markic & Eilks, 2015). Secondary students from many schools in Bremen and its surrounding come to the university laboratories to explicitly learn about chemistry's contribution to sustainability.…”

Section: Ijpce -International Journal Of Physics and Chemistry Educationmentioning

confidence: 99%

Incorporating Sustainability in Higher Chemistry Education in Indonesia through Green Chemistry: Inspirations by Inquiring the Practice in a German University

Hamidah

Prabawati

Fajriati

et al. 2017

International Journal of Physics and Chemistry Education

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Green chemistry is suggested as an important guide to allow the practice of chemistry to become more sustainable. In this study, a chemistry department at a German university is analyzed by an outside view to how it integrates the philosophy of green chemistry into its research and teaching practices to inform higher education institutions in Indonesia on how this issue could be approached. The study reveals that the level of understanding of green chemistry is largely varying among different stakeholders, however its principles are well integrated in both research and teaching. In addition, it became clear that today modern chemistry departments should operate a broader approach towards sustainability than just practicing green chemistry in laboratory practices. The vision is to highlight the importance of green chemistry and other corresponding practices to support education for sustainable development (ESD) in a broad sense. The integration of green chemistry to support the implementation of ESD in higher education can only be achieved by strong commitments from all groups involved, namely the head and administration of the department, researchers, and teachers. Although not all aspects that were observed during this study are suitable to be applied in the Indonesian context, some implications can be derived for reform in Indonesian higher chemistry education.

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The Potential of Non-Formal Laboratory Environments for Innovating the Chemistry Curriculum and Promoting Secondary School Level Students Education for Sustainability

Cited by 26 publications

References 50 publications

The Use of Comics in Experimental Instructions in a Non-formal Chemistry Learning Context

The Use of Comics in Experimental Instructions in a Non-formal Chemistry Learning Context

The promotion of sustainable environmental education by the Zimbabwe Ordinary level science syllabi

Incorporating Sustainability in Higher Chemistry Education in Indonesia through Green Chemistry: Inspirations by Inquiring the Practice in a German University

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