Can School Children Support Ecological Research? Lessons from the &lt;i&gt;Oak Bodyguard&lt;/i&gt; Citizen Science Project

Castagneyrol, Bastien; Valdés‐Correcher, Elena; Bourdin, Audrey; Barbaro, Luc; Bouriaud, Olivier; Branco, Manuela; Centenaro, Giada; Csóka, György; Duduman, Mihai‐Leonard; Dulaurent, Anne‐Maïmiti; Eötvös, Csaba Béla; Faticov, Maria; Ferrante, Marco; Fürjes-Mikó, Ágnes; Galmán, Andrea; Goßner, Martin M.; Harvey, Deborah; Howe, Andy G.; Kaennel-Dobbertin, Michèle; Koricheva, Julia; Löveï, Gábor L.; Lupaştean, D.; Milanović, Slobodan; Mrázová, Anna; Opgennoorth, Lars; Pitkänen, Juha-Matti; Popović, Marija; Roslin, Tomas; Scherer‐Lorenzen, Michael; Sam, Kateřina; Tahadlová, Markéta; Thomas, Rebecca L.; Tack, Ayco J. M.

doi:10.5334/cstp.267

Cited by 22 publications

(28 citation statements)

References 39 publications

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“…To maximize success, a CS project still needs resources and careful design (Bonney et al, 2016;Edelson et al, 2018;Herodotou et al, 2018;Naqshbandi et al, 2020), ideally including preliminary trials. CS projects involving school students may require greater investment in quality control (Castagneyrol et al, 2020;Saunders et al, 2018).…”

Section: Discussion and Future Direc Tionsmentioning

confidence: 99%

Grass Gazers: Using citizen science as a tool to facilitate practical and online science learning for secondary school students during the COVID‐19 lockdown

Haeften

Milić

Addison-Smith

et al. 2020

Ecology and Evolution

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The coronavirus disease of 2019 (COVID‐19) pandemic has impacted educational systems worldwide during 2020, including primary and secondary schooling. To enable students of a local secondary school in Brisbane, Queensland, to continue with their practical agricultural science learning and facilitate online learning, a “Grass Gazers” citizen science scoping project was designed and rapidly implemented as a collaboration between the school and a multidisciplinary university research group focused on pollen allergy. Here, we reflect on the process of developing and implementing this project from the perspective of the school and the university. A learning package including modules on pollen identification, tracking grass species, measuring field greenness, using a citizen science data entry platform, forensic palynology, as well as video guides, risk assessment and feedback forms were generated. Junior agriculture science students participated in the learning via online lessons and independent data collection in their own local neighborhood and/or school grounds situated within urban environments. The university research group and school coordinator, operating in their own distributed work environments, had to develop, source, adopt, and/or adapt material rapidly to meet the unique requirements of the project. The experience allowed two‐way knowledge exchange between the secondary and tertiary education sectors. Participating students were introduced to real‐world research and were able to engage in outdoor learning during a time when online, indoor, desk‐based learning dominated their studies. The unique context of restrictions imposed by the social isolation policies, as well as government Public Health and Department of Education directives, allowed the team to respond by adapting teaching and research activity to develop and trial learning modules and citizen science tools. The project provided a focus to motivate and connect teachers, academic staff, and school students during a difficult circumstance. Extension of this citizen project for the purposes of research and secondary school learning has the potential to offer ongoing benefits for grassland ecology data acquisition and student exposure to real‐world science.

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Section: Discussion and Future Direc Tionsmentioning

confidence: 99%

Grass Gazers: Using citizen science as a tool to facilitate practical and online science learning for secondary school students during the COVID‐19 lockdown

Haeften

Milić

Addison-Smith

et al. 2020

Ecology and Evolution

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“…The concept of creative science teaching or creative pedagogy is embedded in several instances of unconventional teaching strategies, among which meaningful discovery (Khabibah et al, 2017;Wartono et al, 2017), student-based investigations (Allchin et al, 2014), inquiry in historical experiment exploration (Schvartzer et al, 2021), engagement in scientifically oriented inquiry (Cairns & Areepattamannil, 2019;Wagh et al, 2017), prioritizing direct experience and personal reflection (Djonko-Moore et al, 2018;Horng et al, 2005), evidence-based explanations by a field expert (Castagneyrol et al, 2020;Kelemen-Finan et al, 2018), interdisciplinary STEM (Abdullah et al, 2018;Karampelas, 2019) and connecting explanations to scientific knowledge (Henriksen & Mishra, 2015;Miller & Krajcik, 2019). In addition to the listed strategies for teaching science content, skills and values, creative science learning is also infused in the way knowledge is transferred or communicated (Conradty et al, 2020).…”

Section: Creative Pedagogymentioning

confidence: 99%

Primary School Science Teachers’ Creativity and Practice in Malaysia

Abdullah

Mustafa

Hamzah

et al. 2021

IJLTER

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Creative pedagogy has been explored extensively, and previous research suggests that there is a gap between the level and practice of creativity of science teachers, and that it varies by school location. The aim of this study was to determine the levels of creativity, and creativity practice of primary school science teachers, and differences in the levels of creativity and creativity practice of primary school science teachers based on school location. The Torrance Tests of Creative Thinking (TTCT) were used to acquire qualitative data from 20 participants, and a questionnaire of creativity practice in science teaching was used to collect quantitative data from 409 participants. The qualitative data were analyzed according to the TTCT scoring technique and the quantitative data were analyzed descriptively using Statistical Package for the Social Sciences 26. This study found that, that while overall teacher creativity was low, the teachers perceived that they employed highly creative practices. No difference was found in relation to environment, teaching aids, skills and science process skills of teachers in urban and rural areas. However, teachers in rural areas were more knowledgeable about creativity, while teachers in urban areas were better at practising it. This research provides baseline evidence on current practices in creative pedagogy of science teachers nationwide.

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“…For example, when birds attempt to glean caterpillar decoys, they leave beak imprints, and small mammals and arthropods leave bite marks (Low et al 2014). These artificial larvae are used in ecological research such as testing for the effect of plant diversity on herbivore control by predators (Muiruri, Rainio, and Koricheva 2016) as well as citizen science (Castagneyrol et al 2020).…”

Section: Context Of the Study And Participantsmentioning

confidence: 99%

Exploring the impacts of contextualised outdoor science education on learning: the case of primary school students learning about ecosystem relationships

Ayotte-Beaudet

Chastenay

Beaudry

et al. 2021

Journal of Biological Education

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The present study explored the impacts of a contextualised outdoor science curriculum on what and how elementary students learn when immersed in the local contexts in which natural phenomena occur. We conducted 63 individual interviews with fifth-and sixth-graders (between 10 and 12 years old) living in the inner city of Montréal, Québec province, Canada. These allowed us to identify (1) three categories of impacts on what students learned: evolution of conceptual understanding about living organisms, development of scientific investigation abilities, and evolution of connection to nature, and (2) two categories of impacts on how students learned: a context that encourages deeper learning and a context that promotes engagement. Our results show that impacts on students went beyond learning about living organisms. A strength of our findings is that although the method of data collection did not aim a priori to corroborate the work of other research in the field of outdoor education, it in fact corroborated several results from other research, which is an important step for the development of this field. We also found that some students developed a connection to nature without addressing environmental problems during outdoor activities.

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Can School Children Support Ecological Research? Lessons from the <i>Oak Bodyguard</i> Citizen Science Project

Cited by 22 publications

References 39 publications

Grass Gazers: Using citizen science as a tool to facilitate practical and online science learning for secondary school students during the COVID‐19 lockdown

Grass Gazers: Using citizen science as a tool to facilitate practical and online science learning for secondary school students during the COVID‐19 lockdown

Primary School Science Teachers’ Creativity and Practice in Malaysia

Exploring the impacts of contextualised outdoor science education on learning: the case of primary school students learning about ecosystem relationships

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