scholarly journals Toward Ecological Literacy: A Permaculture Approach to Junior Secondary Science

2013 ◽  
Vol 29 (2) ◽  
pp. 241-242
Author(s):  
Nelson Lebo ◽  
Chris Eames ◽  
Richard Coll ◽  
Katherine Otrel-Cass
Keyword(s):  
Science Education ◽  
New Zealand ◽  
Systems Thinking ◽  
Scientific Literacy ◽  
Ecological Literacy ◽  
Secondary Science ◽  
Design System ◽  
Learning Science ◽  
Junior Secondary ◽  
Sustainability Learning

AbstractEnvironmental, economic, and social trends suggest the need for more sustainable ways of thinking and patterns of behaviour. Such a shift would require humanity to function at high levels of ecological literacy, which relies on a certain amount of scientific literacy. However, troubling evidence indicates an international pattern of student disengagement with science at the secondary level. Evidence also suggests that it is difficult to integrate environmental or sustainability education at this level, both within New Zealand and elsewhere. This research was aimed at examining the use of a novel approach, using permaculture, in junior secondary science (Years 9 and 10) to enhance students’ ecological and scientific literacy, as well as their attitudes toward studying science in school.Permaculture is an ecological design system based on science and ethics. A permaculture approach to science education involves eco-design thinking, as well as the use of local permaculture properties and practitioners, and the science behind common permaculture practices. The approach is also meant to be relevant and engaging, and to promote systems thinking. This study involved the design and delivery of an intervention based on permaculture principles to one Year 10 science class in New Zealand.Research took the form of a naturalistic, interpretive, mixed methods case study, which included the use of questionnaires, interviews, and observations. Data collection focused on the impacts of a permaculture approach on the teaching and learning of science, on students’ ecological literacy, and on students’ attitudes toward learning science in school. Pre- and post-intervention questionnaires probed students’ opinions on the environment, science, and learning science in school, and tested their sustainable thinking and systems thinking with concept mapping and SOLO Taxonomy exercises. Classroom observations took place over the course of 12 weeks, on average 3 days per week, totalling 31 days. Before and after some classroom visits, I had informal conversations with the teacher, along with three formal interviews before, during and after the intervention. Three focus groups of students were interviewed immediately following the intervention.Findings show that a permaculture approach to junior secondary science can impact positively on students’ understanding of science and sustainability, and may impact on their attitudes toward studying science in school. It also appeared to impact positively on the science teacher'sattitude toward including sustainability in his teaching practice, and on his own sustainability learning. Regarding both students and teachers, a permaculture approach appears to have been effective to cultivate attitudes and trellis learning.The teacher and the students responded favourably to many aspects of the intervention, including the overall focus on the environment, the field trips, and some classroom learning activities. The teacher reported appreciating the way the intervention contextualised science with real world examples. Most students reported appreciating the experiential aspects of the intervention, as well as the relevance that a permaculture approach to science education provided. Findings indicate that advances in ecological and scientific literacy varied among students. Some students appeared to: improve their use of science and sustainability vocabulary; become more aware of select socio-scientific issues; better recognise scientific and ecological limits and possibilities. Some students also showed advances in sustainable thinking and systems thinking. Although many students expressed concern about issues such as pollution, wildlife, and genetic engineering — and prioritised protecting the environment over making money — there appeared to be a disconnect between these feelings and a sense of personal responsibility to act. Most students reported enjoying learning science with a focus on the environment, with one cohort indicating much greater enjoyment of the permaculture approach than their usual level of enjoyment of learning science in school.Trends in environmental degradation, population growth, energy inflation, and economic stagnation — especially pronounced since the beginning of this inquiry in 2008 — indicate that the world of the future will require ecologically literate citizens who can design and create truly sustainable systems for all human endeavors. Cultivating such citizens, and trellising their science and sustainability learning has implications for science education. This thesis identifies an innovative approach for junior secondary science in New Zealand that provides a way towards a more sustainable future.

scholarly journals Curriculum Reform of Science in Elementary Schools in China

2019 ◽  
Vol 1 (2-3) ◽  
pp. 573-578
Author(s):  
Wenjie Pei
Keyword(s):  
Science Education ◽  
Elementary Schools ◽  
Curriculum Reform ◽  
Scientific Literacy ◽  
Capital Investment ◽  
Learning Science ◽  
Ministry Of Education ◽  
Learning And Development ◽  
Learning Time ◽  
Science Subject

In January 2017, the Chinese Ministry of Education issued the Curricular Standards of Science in Elementary Schools, aiming at developing students’ scientific literacy and a foundation for their learning and development as competent citizens. To achieve its overall goal, the reform reflects four main strategies: extending the learning time of science education, integrating engineering and technological contents into science subject, phased design based on the idea of learning progressions, and using big concepts to guide teaching contents. The Curricular Standards of Science in Elementary Schools has been implemented in major provinces and cities across the country and achieved initial outcomes in stimulating students’ enthusiasm for learning science. To better implement these standards, increasing capital investment, improving experiments, and upgrading equipment become urgent to be considered.

Cultivating Attitudes and Trellising Learning: A Permaculture Approach to Science and Sustainability Education

2015 ◽  
Vol 31 (1) ◽  
pp. 46-59 ◽  
Author(s):  
Nelson Lebo ◽  
Chris Eames
Keyword(s):  
Student Attitudes ◽  
Design Thinking ◽  
Sustainability Education ◽  
Field Trips ◽  
Secondary Science ◽  
Learning Science ◽  
Mixed Methods Case Study ◽  
Sustainability Research ◽  
Sustainability Learning

AbstractThis article reports on an inquiry that used permaculture design thinking to create a science and sustainability education intervention for a secondary science class. The aims were to cultivate student attitudes towards science, towards learning science in school, and towards the environment, and to trellis learning of science and sustainability. Research into impacts of the intervention took the form of an interpretive, mixed methods case study, which included the use of questionnaires, interviews and observations. As a context for learning, local permaculture food production projects, as experienced through field trips in the intervention, appear to promote the relevance of science and sustainability learning and the ability to engage students. Science and sustainability learning outcomes appeared to vary among students, although nearly all of them reported they enjoyed learning science with a focus on the environment, including one group of students who reported they did not generally enjoy learning science in school. There was some evidence that the teacher transformed his own thinking through his participation in the intervention.

scholarly journals SciNow: Multimodal Educational Resources

2021 ◽  
Author(s):  
◽  
Brontë Ammundsen
Keyword(s):  
Science Education ◽  
Academic Success ◽  
New Zealand ◽  
Business Model ◽  
Real Life ◽  
Business Case ◽  
Secondary Science ◽  
Economic Prosperity ◽  
Literature Reviews ◽  
Charitable Trust

<p>The necessity for this project was identified as a response to declining levels of science engagement, academic success and literacy observed in New Zealand secondary science education (OECD, 2016). As international advancements in sciences and technology create shifts in the current economic landscape, increasing importance is being placed on knowledge-intensive industries. This changed weighting of industry contributions to economic prosperity creates a simultaneous change in future workforce skill requirements (Gilbert & Bull, 2013). With the importance of education in long-term social and economic prosperity being long acknowledged, the changing economic climate intensifies the urgent need to address New Zealand’s declining science engagement and academic success.  While the most significant facets of educational operations lie in education pedagogy and policy, the wide range of factors involved in educational outcomes yield expansive opportunities for potential innovations and commercialisation in the education sector. The opportunity for this project was derived from identifying the elements that contribute to these challenges, and isolating a gap in the market of science education resources. The purpose of this project was to research this potential market gap, as well as identifying how to appeal to it. This led to the proposal for the SciNow multimodal resource database, a resource database designed to provide engaging lesson and study materials to science students and teachers with an emphasis on real-life application of content. Through utilising the concept of multimodality, the database design proposes offering materials through ranging modes of communication to increase appeal to varying student learning preferences (Jewitt, 2008). The overall intention for the SciNow database is to raise attractiveness of science education by making it more interesting and relevant to students, thereby positively affecting educational outcomes and in turn leading to economic benefits in the form of a more ideally skilled workforce.  While initial investigation focused on creating a business model for commercialising the SciNow resource database, this intention was adjusted in response to literature reviews revealing the significant performance gap between high and low achievers in science education (Education Review, 2016). In addition to New Zealand exhibiting one of the largest performance gaps in the OECD, concerns are exacerbated by the lowest performing population’s overrepresentation of Maori and Pasifika students and students from low socioeconomic backgrounds (OECD, 2015). In response to the level of inequality in science education, the SciNow proposal was adjusted to be provided to all students and teachers nationwide for free.  The methodology implemented in this project was of a qualitative nature (Morgan, 1997). Interviews were conducted with secondary science teachers and students in which questioning focused on experiences with science education, including education resource availability and provision. Further focus groups were held with university students from wide-ranging backgrounds to gather reflective insight into experiences with science in school and in subsequent life.  The key findings indicated a desire for improved resource availability and quality, responding favourably to the proposition of the SciNow resource database. Further findings validated the proposed use of multimodality for engagement and focus on real-life content application.  Considering research findings, literature reviews, and the decision to provide the service freely, a flexible business model and case for investment is proposed and outlined in a strategic assessment business case. This business case proposes a three-phase process of development and implementation, influenced by the lean start-up business model. This three-phased plan begins with further research and subsequent development of a prototype as a minimum viable product. Following development, the prototype will then undergo testing and enhancement through feedback analysis, followed finally by expansion of the prototype to encompass the full database spectrum. The initial governing body will be composed of a core working group. Upon formation of a charitable trust, this core working group will evolve into an advisory board to act alongside the more commercially focused charitable trust board.  Key implications derived from this project are dual. In part, the project research emphasises the necessity for the education sector to consider more deep-rooted changes in the New Zealand education system (Bull, Gilbert, Barwick, Hipkins, & Baker, 2010). Significant changes are needed to truly optimise New Zealand science education, and provision of a resource database can only accommodate educational challenges, not fix them. However, the research and business case demonstrate that execution of the SciNow proposal is feasible, with the intended research and development crucial in maximising potential benefit of the service. Upon completion of this project, further work is intended to bring the SciNow concept to fruition.</p>

scholarly journals SciNow: Multimodal Educational Resources

2021 ◽  
Author(s):  
◽  
Brontë Ammundsen
Keyword(s):  
Science Education ◽  
Academic Success ◽  
New Zealand ◽  
Business Model ◽  
Real Life ◽  
Business Case ◽  
Secondary Science ◽  
Economic Prosperity ◽  
Literature Reviews ◽  
Charitable Trust

<p>The necessity for this project was identified as a response to declining levels of science engagement, academic success and literacy observed in New Zealand secondary science education (OECD, 2016). As international advancements in sciences and technology create shifts in the current economic landscape, increasing importance is being placed on knowledge-intensive industries. This changed weighting of industry contributions to economic prosperity creates a simultaneous change in future workforce skill requirements (Gilbert & Bull, 2013). With the importance of education in long-term social and economic prosperity being long acknowledged, the changing economic climate intensifies the urgent need to address New Zealand’s declining science engagement and academic success.  While the most significant facets of educational operations lie in education pedagogy and policy, the wide range of factors involved in educational outcomes yield expansive opportunities for potential innovations and commercialisation in the education sector. The opportunity for this project was derived from identifying the elements that contribute to these challenges, and isolating a gap in the market of science education resources. The purpose of this project was to research this potential market gap, as well as identifying how to appeal to it. This led to the proposal for the SciNow multimodal resource database, a resource database designed to provide engaging lesson and study materials to science students and teachers with an emphasis on real-life application of content. Through utilising the concept of multimodality, the database design proposes offering materials through ranging modes of communication to increase appeal to varying student learning preferences (Jewitt, 2008). The overall intention for the SciNow database is to raise attractiveness of science education by making it more interesting and relevant to students, thereby positively affecting educational outcomes and in turn leading to economic benefits in the form of a more ideally skilled workforce.  While initial investigation focused on creating a business model for commercialising the SciNow resource database, this intention was adjusted in response to literature reviews revealing the significant performance gap between high and low achievers in science education (Education Review, 2016). In addition to New Zealand exhibiting one of the largest performance gaps in the OECD, concerns are exacerbated by the lowest performing population’s overrepresentation of Maori and Pasifika students and students from low socioeconomic backgrounds (OECD, 2015). In response to the level of inequality in science education, the SciNow proposal was adjusted to be provided to all students and teachers nationwide for free.  The methodology implemented in this project was of a qualitative nature (Morgan, 1997). Interviews were conducted with secondary science teachers and students in which questioning focused on experiences with science education, including education resource availability and provision. Further focus groups were held with university students from wide-ranging backgrounds to gather reflective insight into experiences with science in school and in subsequent life.  The key findings indicated a desire for improved resource availability and quality, responding favourably to the proposition of the SciNow resource database. Further findings validated the proposed use of multimodality for engagement and focus on real-life content application.  Considering research findings, literature reviews, and the decision to provide the service freely, a flexible business model and case for investment is proposed and outlined in a strategic assessment business case. This business case proposes a three-phase process of development and implementation, influenced by the lean start-up business model. This three-phased plan begins with further research and subsequent development of a prototype as a minimum viable product. Following development, the prototype will then undergo testing and enhancement through feedback analysis, followed finally by expansion of the prototype to encompass the full database spectrum. The initial governing body will be composed of a core working group. Upon formation of a charitable trust, this core working group will evolve into an advisory board to act alongside the more commercially focused charitable trust board.  Key implications derived from this project are dual. In part, the project research emphasises the necessity for the education sector to consider more deep-rooted changes in the New Zealand education system (Bull, Gilbert, Barwick, Hipkins, & Baker, 2010). Significant changes are needed to truly optimise New Zealand science education, and provision of a resource database can only accommodate educational challenges, not fix them. However, the research and business case demonstrate that execution of the SciNow proposal is feasible, with the intended research and development crucial in maximising potential benefit of the service. Upon completion of this project, further work is intended to bring the SciNow concept to fruition.</p>

scholarly journals Integrating engineering in K-12 science education: spelling out the pedagogical, epistemological, and methodological arguments

2019 ◽  
Vol 1 (1) ◽  
Author(s):  
Senay Purzer ◽  
Jenny Patricia Quintana-Cifuentes
Keyword(s):  
Science Education ◽  
Scientific Literacy ◽  
Student Learning Outcomes ◽  
School Science ◽  
School Resources ◽  
Science And Engineering ◽  
Teaching Models ◽  
Engineering Design Process ◽  
Stem Literacy ◽  
K 12

AbstractThis position paper is motivated by recent educational reform efforts that urge the integration of engineering in science education. We argue that it is plausible and beneficial to integrate engineering into formal K-12 science education. We illustrate how current literature, though often implicitly, discusses this integration from a pedagogical, epistemological, or methodological argumentative stance. From a pedagogical perspective, a historically dominant argument emphasizes how engineering helps make abstract science concepts more concrete. The epistemological argument is centered on how engineering is inherently interdisciplinary and hence its integrative role in support of scientific literacy and more broadly STEM literacy is natural. From a methodological perspective, arguments focus on the engineering design process, which is compatible with scientific inquiry and adaptable to answering different types of engineering questions. We call for the necessity of spelling out these arguments and call for common language as science and engineering educators form a research-base on the integration of science and engineering. We specifically provide and discuss specific terminology associated with four different models, each effectively used to integrate engineering into school science. We caution educators against a possible direction towards a convergence approach for a specific type of integrating engineering and science. Diversity in teaching models, more accurately represents the nature of engineering but also allows adaptations based on available school resources. Future synthesis can then examine student learning outcomes associated with different teaching models.

scholarly journals Bibliometric analysis of scientific literacy using VOS viewer: Analysis of science education

2021 ◽  
Vol 1796 (1) ◽  
pp. 012096
Author(s):  
Denti Nanda Effendi ◽  
Irwandani ◽  
Welly Anggraini ◽  
Agus Jatmiko ◽  
Henita Rahmayanti ◽  
...  
Keyword(s):  
Science Education ◽  
Bibliometric Analysis ◽  
Scientific Literacy ◽  
Vos Viewer

Exploring Pre-service Science Teachers’ Perspectives on the Nature of Science: A Comparative Study Between China and Canada

2021 ◽  
pp. 209653112096678
Author(s):  
Guihua Zhang ◽  
Yuanrong Li ◽  
George Zhou ◽  
Sonia Wai-Ying Ho
Keyword(s):  
Teacher Education ◽  
Science Education ◽  
Science Teacher ◽  
Nature Of Science ◽  
Science Teachers ◽  
Scientific Literacy ◽  
Survey Design ◽  
Science Teacher Education ◽  
Teaching Behaviors ◽  
Preservice Science Teachers

Purpose: The Nature of Science (NOS) is an important component of scientific literacy. Science teachers’ Views of the Nature of Science (VNOS) directly affect their teaching behaviors. Therefore, it is of great significance to explore science teachers’ VNOS and find ways of improvement. This study was designed to comparatively investigate preservice science teachers’ VNOS between China and Canada. Design/Approach/Methods: The study employed a survey design to explore how Chinese and Canadian preservice science teachers understood the seven different aspects of NOS. Findings: Data showed that preservice science teachers in China and Canada both hold a modern view about science education. The level of Chinese and Canadian participants’ understanding of NOS was above the relatively naive level. Chinese teachers had better macro-understanding toward science education but their micro-mastery was insufficient. While the Canadian participants had a better understanding of the NOS than their Chinese counterparts. Originality/Value: Based on the research results and the experience of science education and teacher education in Canada, we suggested that there is a need to reconstruct the preservice science teacher education curriculum in China and promote the transformation in the science teacher educational system.

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