Community-driven science and science education: Living in and navigating the edges of equity, justice, and science learning

IF 3.6 1区 教育学 Q1 EDUCATION & EDUCATIONAL RESEARCH
Heidi L. Ballard, Angela Calabrese Barton, Bhaskar Upadhyay
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From “alternative facts” to climate change denial, there is increasing public rhetoric, driven by corporate and political interests, that any empirical position can be denied because it does not fit with one's wishes or desires.</p><p>In the face of inequitable access to science, distrust, and debate on what can even be considered verifiable information, many look to science education to rescue society from this destructive spiral. Surely, we just need to find better ways of engaging people in science? Yet, the culture and practice of dominant science has been used to justify racism, and to position particular ways of knowing, doing, and being as outside the realm of science. By “dominant science,” we mean the particular forms of Western science that have become dominant to the point that “other ways of knowing, doing, and being are deemed illegitimate or are erased” (Liboiron, <span>2021</span>; p. 21). The historical lack of inclusion of multiple voices and perspectives in decision-making around scientific issues and in the production of scientific understandings, a lack of transparency of how science is done, including insights into who controls the agenda, whose knowledge counts, and who benefits, all shape how and why communities may—or may not—engage in science. Consequently, a significant divide exists between the scientific community and many members of local communities. Among these tensions emerges the notion of community-driven science.</p><p>Consider Flint, MI, a city home to primarily African American families, where 40% of residents live in poverty. In 2014, residents of the city began complaining of discolored and foul smelling and tasting water. However, the city and state were slow to respond. It took a resident-organized effort in collaboration with outside researchers at Virginia Tech University to document what was to become known as one of the “most significant” environmental injustice events of “recent history” (Pauli, <span>2019</span>). They documented low levels of chlorine in the city's water that led to high levels of the bacteria that causes Legionnaires' disease, and the heavy metals leaching into the water supply at levels in violation of the Safe Drinking Water Act (Zahran et al., <span>2020</span>), lead to highly elevated levels of lead in children's blood. All of this resulted from the entanglement of economic, political, and structural inequities that led to a state-level decision to save money by changing the city's water support from treated Huron River water to untreated Flint River water (Pauli, <span>2019</span>). The health and safety impacts of the decision to prioritize saving money over people's well-being only became known because of the <i>collective work of residents</i>.</p><p>The Flint water crisis is just one of many science-related issues that affect the well-being of communities that could have had a more positive outcome if governmental and scientific institutions took everyday people's observations seriously. Health care, food, the environment, climate, energy production, digital surveillance, genetically modified organisms, and disease transmission are just a handful of areas of study that all demand cooperation between science and society. Recent events such as the COVID-19 pandemic illustrate that not only has distrust in science increased, science itself has become politicized. Partisan divisions mark almost all aspects of the pandemic, from how seriously the threat to public health was treated, to the uptake of misinformation about the virus' origin, possible treatments, and the safety of vaccines. People and communities can play a vital role in helping to define the problems that are worth investigating, in generating sources and forms of data, and in offering interpretations for the future of this planet. But for this to happen, scientists need to acknowledge and better understand the needs, interests, and knowledge of people and communities. Even further, most scientists have not necessarily been educated or encouraged to support community engagement as part of their efforts.</p><p>At the same time, many different communities may not understand, trust, or engage with the scientific enterprise, for historicized and self-protecting reasons. We noted above that communities of color, and low-income communities, such as the people of Flint, MI, have powerful historical reasons for this distrust (Ramirez-Andreotta, <span>2019</span>), as these communities have been often ignored or silenced by the scientific community in dehumanizing and harmful ways. The field of science education is both partly responsible for these problems, but is also key to addressing them. So while some progress has been made in scientists and government agencies listening to local community science observations and expertise (e.g., Dosemagen &amp; Parker, <span>2019</span>), and conceptual discussions of the relationship of citizen science, ecojustice, and science education (e.g., Mueller &amp; Tippins, <span>2012</span>), there is a gap in explicitly examining, with empirical research, science education as part of the problem and solution through community-driven science.</p><p>How the field of science education grapples with these equity- and justice-related concerns around community participation in science is a central concern for the field, and a variety of approaches have been introduced both within and outside the field of science education. From the professional scientist's perspective, there has been some focus on community participation in science, but primarily a broader push toward “public engagement in science.” Historically, this has meant “intentional, meaningful interactions that provide opportunities for mutual learning between scientists and members of the public” (AAAS, <span>2018</span>). This approach has been heralded as a way to decrease the tension between science and society. However, while a good first step, current efforts to promote public engagement have also been critiqued for (1) lacking more authentic and substantive forms of engagement by <i>communities</i> themselves, particularly communities historically marginalized by science and society or (2) limited efforts to have such engagement transform the processes and outcomes of science (Jadallah et al., <span>in Review</span>, Stilgoe et al., <span>2014</span>). Additionally, approaches focused on “public participation in scientific research” (Shirk et al., <span>2012</span>) and “citizen science” (Bonney et al., <span>2014</span>) do go farther in inviting members of the public into scientific research through participation in data collection and the generation of new scientific knowledge, but these are still focused primarily on projects driven by professional scientists and often lack roles in the decision-making for community members. Community science, typically defined as more community-driven and focused on community needs (Dosemagen &amp; Parker, <span>2019</span>), gets closer to the equitable cogeneration of knowledge that benefits local communities, but nevertheless as a term has been more recently muddied to include scientist-driven efforts (Cooper et al., <span>2021</span>).</p><p>The goal of the special issue on community-driven science is to develop deeper understandings of the variations in and possibilities for community-driven science, and to produce new understandings of and discourses on the role and possibilities for community-driven science within science education contexts: what it is, what it looks like, what people learn, how it is practiced, and its implications for democratizing the knowledge, practice, and discourses of science and science education.</p><p>For us, community-driven science is more than engagement; it is about tangible and intangible relationships between knowledge and skills produced by science for the benefit of the community. Relationality is central to community-driven science because it situates people, place, and the environment (politics, history, and culture) at the heart of doing and knowing science, rather than at a distance to suffice presumed notions of objectivity. Additionally, one of the foci of community-driven science is that science, in all its forms, is contributory to the community wellbeing rather than extractive.</p><p>The idea of community-driven science is not new to the field of science education, even if it has been marginal to research, development, and reform efforts. Indeed, powerful previous work has focused on everything from preservice science teachers learning to use local environmental justice issues as contexts for learning (Varelas et al., <span>2018</span>), to young people in a summer program collecting water quality data at their local creek and presenting to their city council (Ballard et al., <span>2017</span>), to “fence-line” organizations using their own air monitoring samples to fight a chemical plant (Ottinger, <span>2010</span>), to youth organizing through STEM investigations to transform local injustices through place-based scientific inquiry (Birmingham et al., <span>2017</span>; Morales-Doyle, <span>2017</span>; Upadhyay et al., <span>2020</span>) and engineering design (Nazar et al., <span>2019</span>).</p><p>We seek to build on and expand this work to develop a framework for what <i>community-driven science</i> might be with respect to science teaching and learning. We use this overarching term to frame how people, collectively, engage with science, in their local contexts, and in ways that position them as critical stakeholders and decision-makers in the processes and outcomes of science, in ways that are consequential to their own learning and for broader social change. We view community-driven science as involving community members in the scientific process early on as co-owners of a research agenda that is for the <i>wellbeing</i> and <i>social futures</i> of the community and its members. This stands in contrast to more traditional citizen science approaches typically studied in science education contexts, where the agenda is created and owned by professional scientists (e.g., Brossard et al., <span>2005</span>, Phillips et al., <span>2018</span>), though many scholars discuss the conceptual potential for more co-created participatory to promote science learning (Bonney et al., <span>2016</span>; Roche et al., <span>2020</span>). Our conceptualization links closely to the long and rich history of community-based participatory research in public health (Israel et al., <span>2013</span>) and environmental justice (Bacon et al., <span>2013</span>), as well as community science approaches that also foreground community questions and leadership in primarily air and water quality monitoring (Dosemagen &amp; Parker, <span>2019</span>; Wilson et al., <span>2018</span>). However, we focus on community-driven science not only to steer away from the debate around terminology in the citizen science and community sciences fields (Cooper et al., <span>2021</span>; Eitzel et al., <span>2017</span>), but also to emphasize the particular decision-making roles of community members with respect to science <i>and</i> science learning, and to focus on the ways that the work benefits the community and its members, not just benefits from their participation.</p><p>In the remainder of this special issue introduction, we map the terrain of community-driven science using the manuscripts of this issue, delving into three key themes that help us reveal the tensions and contradictions inherent in this often-fraught work. This mapping then allows us to examine the ways community-driven science seems to offer a space in the borderlands between science and communities such that working in “the edges” between worlds increases the possibilities for fostering equity and justice even as it fosters new roles in doing better science. Lastly, we offer the implications these studies have for both research and design in science education.</p><p>As we move forward as a field, we must consider how we are responsible and accountable to the varied and powerful forms of community-driven science that exist already, and also how we might design for widespread opportunities to unfold. In this special issue, scholars offer new and different insights into how the field may define community-driven science in support of equity and justice-oriented teaching, learning, and design work. In this last section, we dig more deeply into <i>how and why</i> community-driven science offers a unique space, or set of conditions and drivers, for new forms of science teaching and learning. Consider the concept of “edge effects” in the field of conservation biology. In the locations where two habitats come together, a forest and a grassland, for example, each habitat has its own different temperature, moisture and even soil conditions, as well as different biodiversity of flora and fauna. Rather than a hard boundary, a third kind of habitat with a gradient across each of those conditions exists as a kind of blurring from one habitat to the other; this space is a habitat <i>edge</i> (Ries et al., <span>2004</span>). In conservation, typically we are concerned with conserving the biodiversity and ecosystem services of each of those “interior” habitats, such that extensive research has been done on how far the negative edge effects penetrate into the interior, threatening the total area covered by rainforest at a landscape scale, for example. But looking closely at the edges themselves, researchers also find positive edge effects, where new ecological communities emerge near habitat edges (Ries et al., <span>2004</span>); edges actually may often increase biodiversity, because the conditions across the gradient allow for plant and animal species from both kinds of habitats to occupy the same space at the margins of their preferred conditions.</p><p>We suggest that community-driven science serves the same role for science learning, by bridging and blurring the boundaries between science and communities. Community-driven science creates new spaces and conditions for community members and scientists to develop new and different roles and relationalities in the work of knowledge building about the world. Taking on these new roles and relationalities can foster identity development in ways that allow people to not only see themselves in command of Western science tools and practices, but also to be seen as experts on their own terms. It can also help to create new legitimized roles in Western science that did not exist before, that reshape the cultural norms of science and science learning to reflect a diversity of knowledge sources and ways of knowing. Rather than focusing only on conserving the conditions and inhabitants of each separate sphere of what is valuable for science learning, standardized tests on one side and lived experiences on the other, for example, community-driven science creates the conditions for negotiation, complementarity, and collective knowledge-building as part of doing and learning science. These negotiations between scientific rigor and community relevance are extensively discussed by scholars of participatory action research (Bradbury &amp; Reason, <span>2003</span>), a kind of community-driven science, and taken up explicitly by Tan &amp; Faircloth in this issue. These negotiations could be considered a key mechanism through which community-driven science can foster more just science learning experiences.</p><p>The manuscripts in this special issue take up provocative, unusual, or previously ignored or marginalized perspectives on what it means to do science, and where science happens. Drawing from Black Feminist Theory: “The margin should not be seen only as a peripheral space, a space of loss and deprivation, but rather as a space of resistance and possibility. The margin is configured as a space of radical opening” (Hooks, <span>1989</span>, p. 149) and creativity, where new critical discourses take place. These positive edge effects of community-driven science reflect Gutierrez's (<span>2008</span>) notion of a collective Third Space or hybrid space, describing a blending and bridging between learning environments that can allow for and foster a more expansive learning, and where “students begin to reconceive who they are and what they might be able to accomplish.” Within the work of community-driven science, the edges and margins are complex sites of political struggle where the challenges of doing science unfold in different ways from the mainstream, and also where particular science/community ecologies and original territories might emerge and thrive. Working in the edges, community-driven science is constantly questioning how barriers to participation in science get erected and policed in science discourse. What are the “borders” of science and community-driven science? What do these borders call attention to? What's “inside” and “outside” the edges? What makes up the liminal space in-between?</p><p><i>A</i>cross articles in this issue, we see how authors grapple with the edges of community-driven science as powerful spaces of negotiation and science co-production. We see this in O'Neill et al.'s and Tan and Faircloth's description of how educators and youth coconstructed new, third spaces through people and place and incubating epistemologies. Such work is fraught, however, as such work involves, as Tan and Faircloth note, “grappling with ambiguity from existing on borderlands.” In cases where youth minoritized by dominant white settler-colonial society, which includes the very culture and practice of science, it takes time and space for youth and educators to figure out how to engage ethically and responsibly in science in ways that acknowledge, value, and legitimize their humanity. Community-driven science work provided that time and space. Each paper in this issue critically notes how expanding views of science and of community actively disrupts and transforms the dominant narratives and cultural practices that, as Tan and Faircloth describe, build and amplify alienating messaging built into the spaces and social structures of science/science education.</p><p>Working in the edges, community-driven science requires attention to how connections across landscapes that link areas of habitat, called “corridors” in conservation biology (Hilty et al. <span>2019</span>), are created, and the inherent tensions therein. Such corridors in community-driven science are important because they make visible the powered relationalities—including the inherent risks—across the landscapes. Figuring out what the edge distance is or could be, how wide corridors may need to be to provide enough of the right kind of habitat of the “interior” habitat type that allows wildlife (and all the associated organisms) to cross and live within that corridor, are all questions related to power, vulnerability, and the possibilities for thriving and well-being.</p><p>For example, Tofel-Grehl (this issue) uses the construct of the margin to make visible that which western science erases, shifting the terrain that can make possible authentic constructions of self and community within community-driven science. She explores how one Indigenous Hawaiian youth, Leilani, navigates her own disconnect with STEM while serving as a land protector on the Mauna Kea volcano, the home of the Thirty Meter Telescope being built over the objection of the local Indigenous community. Using the construct of silenced margins, such as when schools avoid controversial socioscientific issues, which in this case involved avoiding any discussion of the Mauna Kea due to the controversy and thus of Leilani and her community, Tofel-Grehl, shows how it was the explicit avoidance of conflict that reinforced the disengagement of Hawaiian students and community from meaningful participation in science learning. She further shows how it is within these “silenced margins” that youth and communities form their opinions and perspectives on the value of science and the scientific community. This is what can result from keeping borders rigid and ignoring the potentiality of corridors that allow for working in the edges.</p><p>Likewise, Vakil et al. illustrate the agency that youth, educators and communities have in authoring real and symbolic corridors toward engaging and critiquing science/technology in response to the power dynamics that frame participation—especially when participation requires sociopolitical solidarity toward jamming power widely held societal norms. What could it mean to the field of science education when collaboratively designing for edge work becomes central? Here, we see community-driven science as cultivating corridors for powerful learning and agency that is just and equitable between the interior figured worlds of dominant science and local communities.</p><p>In this special issue, we aim to shine light on how and why the field of science education can and should be concerned with understanding equity-centered approaches to communities’ participation in science, especially in communities historically silenced, and its impact on people's learning and participation. This includes highlighting the intersections of community-driven science with the potential possibilities and historically embedded vulnerabilities of the communities in which this work may take place. We hope our collective work here contributes to the knowledge base for the field by making sense of how the work of community-driven science in marginalized communities recognizes their vulnerabilities with, toward, and of, science, while also mobilizing knowledge inherent in those communities.</p><p>Thus, undergirding this special issue are a set of commitments that shape this collective inquiry that we hope pushes the work of science teaching and learning forward. First and foremost, community-driven science is of and for the <i>wellbeing</i> of communities and their members. It involves a wide range of people—youth, adults, and/or combinations—working on questions and problems that are authentic to both the disciplines of science and to communities, where data generation and analysis can potentially lead to answering those questions or problems (Morales-Doyle, <span>2017</span>). Science participation is of, within, and for communities (Calabrese Barton &amp; Tan, <span>2010</span>). Second, community-driven science supports participants in learning–about science and community and the ways in which they intersect through the concerns at hand (Birmingham, et al., <span>2017</span>; van Wart et al., <span>2020</span>). We suggest that when these commitments are met, community-driven science will foster and support science teaching and learning practices that open up, rather than shut down, just and equitable futures for ALL members of society, especially those that have been historically shut out or harmed by dominant science.</p>","PeriodicalId":48369,"journal":{"name":"Journal of Research in Science Teaching","volume":"60 8","pages":"1613-1626"},"PeriodicalIF":3.6000,"publicationDate":"2023-06-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/tea.21880","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Research in Science Teaching","FirstCategoryId":"95","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/tea.21880","RegionNum":1,"RegionCategory":"教育学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"EDUCATION & EDUCATIONAL RESEARCH","Score":null,"Total":0}
引用次数: 0

Abstract

Profound equity and justice-related challenges persist in promoting community engagement with science. The intersecting effects of multiple pandemics—racial and economic injustice, COVID-19, gun violence, and climate change, among others—have all shaped when, how and why people engage with, or even have access to, science. There is also a growing public distrust in science, with broad-reaching implications. The antivaccination movement, one manifestation of the distrust of science, has substantively shaped the course of the COVID-19 pandemic (Tsipursky, 2018). From “alternative facts” to climate change denial, there is increasing public rhetoric, driven by corporate and political interests, that any empirical position can be denied because it does not fit with one's wishes or desires.

In the face of inequitable access to science, distrust, and debate on what can even be considered verifiable information, many look to science education to rescue society from this destructive spiral. Surely, we just need to find better ways of engaging people in science? Yet, the culture and practice of dominant science has been used to justify racism, and to position particular ways of knowing, doing, and being as outside the realm of science. By “dominant science,” we mean the particular forms of Western science that have become dominant to the point that “other ways of knowing, doing, and being are deemed illegitimate or are erased” (Liboiron, 2021; p. 21). The historical lack of inclusion of multiple voices and perspectives in decision-making around scientific issues and in the production of scientific understandings, a lack of transparency of how science is done, including insights into who controls the agenda, whose knowledge counts, and who benefits, all shape how and why communities may—or may not—engage in science. Consequently, a significant divide exists between the scientific community and many members of local communities. Among these tensions emerges the notion of community-driven science.

Consider Flint, MI, a city home to primarily African American families, where 40% of residents live in poverty. In 2014, residents of the city began complaining of discolored and foul smelling and tasting water. However, the city and state were slow to respond. It took a resident-organized effort in collaboration with outside researchers at Virginia Tech University to document what was to become known as one of the “most significant” environmental injustice events of “recent history” (Pauli, 2019). They documented low levels of chlorine in the city's water that led to high levels of the bacteria that causes Legionnaires' disease, and the heavy metals leaching into the water supply at levels in violation of the Safe Drinking Water Act (Zahran et al., 2020), lead to highly elevated levels of lead in children's blood. All of this resulted from the entanglement of economic, political, and structural inequities that led to a state-level decision to save money by changing the city's water support from treated Huron River water to untreated Flint River water (Pauli, 2019). The health and safety impacts of the decision to prioritize saving money over people's well-being only became known because of the collective work of residents.

The Flint water crisis is just one of many science-related issues that affect the well-being of communities that could have had a more positive outcome if governmental and scientific institutions took everyday people's observations seriously. Health care, food, the environment, climate, energy production, digital surveillance, genetically modified organisms, and disease transmission are just a handful of areas of study that all demand cooperation between science and society. Recent events such as the COVID-19 pandemic illustrate that not only has distrust in science increased, science itself has become politicized. Partisan divisions mark almost all aspects of the pandemic, from how seriously the threat to public health was treated, to the uptake of misinformation about the virus' origin, possible treatments, and the safety of vaccines. People and communities can play a vital role in helping to define the problems that are worth investigating, in generating sources and forms of data, and in offering interpretations for the future of this planet. But for this to happen, scientists need to acknowledge and better understand the needs, interests, and knowledge of people and communities. Even further, most scientists have not necessarily been educated or encouraged to support community engagement as part of their efforts.

At the same time, many different communities may not understand, trust, or engage with the scientific enterprise, for historicized and self-protecting reasons. We noted above that communities of color, and low-income communities, such as the people of Flint, MI, have powerful historical reasons for this distrust (Ramirez-Andreotta, 2019), as these communities have been often ignored or silenced by the scientific community in dehumanizing and harmful ways. The field of science education is both partly responsible for these problems, but is also key to addressing them. So while some progress has been made in scientists and government agencies listening to local community science observations and expertise (e.g., Dosemagen & Parker, 2019), and conceptual discussions of the relationship of citizen science, ecojustice, and science education (e.g., Mueller & Tippins, 2012), there is a gap in explicitly examining, with empirical research, science education as part of the problem and solution through community-driven science.

How the field of science education grapples with these equity- and justice-related concerns around community participation in science is a central concern for the field, and a variety of approaches have been introduced both within and outside the field of science education. From the professional scientist's perspective, there has been some focus on community participation in science, but primarily a broader push toward “public engagement in science.” Historically, this has meant “intentional, meaningful interactions that provide opportunities for mutual learning between scientists and members of the public” (AAAS, 2018). This approach has been heralded as a way to decrease the tension between science and society. However, while a good first step, current efforts to promote public engagement have also been critiqued for (1) lacking more authentic and substantive forms of engagement by communities themselves, particularly communities historically marginalized by science and society or (2) limited efforts to have such engagement transform the processes and outcomes of science (Jadallah et al., in Review, Stilgoe et al., 2014). Additionally, approaches focused on “public participation in scientific research” (Shirk et al., 2012) and “citizen science” (Bonney et al., 2014) do go farther in inviting members of the public into scientific research through participation in data collection and the generation of new scientific knowledge, but these are still focused primarily on projects driven by professional scientists and often lack roles in the decision-making for community members. Community science, typically defined as more community-driven and focused on community needs (Dosemagen & Parker, 2019), gets closer to the equitable cogeneration of knowledge that benefits local communities, but nevertheless as a term has been more recently muddied to include scientist-driven efforts (Cooper et al., 2021).

The goal of the special issue on community-driven science is to develop deeper understandings of the variations in and possibilities for community-driven science, and to produce new understandings of and discourses on the role and possibilities for community-driven science within science education contexts: what it is, what it looks like, what people learn, how it is practiced, and its implications for democratizing the knowledge, practice, and discourses of science and science education.

For us, community-driven science is more than engagement; it is about tangible and intangible relationships between knowledge and skills produced by science for the benefit of the community. Relationality is central to community-driven science because it situates people, place, and the environment (politics, history, and culture) at the heart of doing and knowing science, rather than at a distance to suffice presumed notions of objectivity. Additionally, one of the foci of community-driven science is that science, in all its forms, is contributory to the community wellbeing rather than extractive.

The idea of community-driven science is not new to the field of science education, even if it has been marginal to research, development, and reform efforts. Indeed, powerful previous work has focused on everything from preservice science teachers learning to use local environmental justice issues as contexts for learning (Varelas et al., 2018), to young people in a summer program collecting water quality data at their local creek and presenting to their city council (Ballard et al., 2017), to “fence-line” organizations using their own air monitoring samples to fight a chemical plant (Ottinger, 2010), to youth organizing through STEM investigations to transform local injustices through place-based scientific inquiry (Birmingham et al., 2017; Morales-Doyle, 2017; Upadhyay et al., 2020) and engineering design (Nazar et al., 2019).

We seek to build on and expand this work to develop a framework for what community-driven science might be with respect to science teaching and learning. We use this overarching term to frame how people, collectively, engage with science, in their local contexts, and in ways that position them as critical stakeholders and decision-makers in the processes and outcomes of science, in ways that are consequential to their own learning and for broader social change. We view community-driven science as involving community members in the scientific process early on as co-owners of a research agenda that is for the wellbeing and social futures of the community and its members. This stands in contrast to more traditional citizen science approaches typically studied in science education contexts, where the agenda is created and owned by professional scientists (e.g., Brossard et al., 2005, Phillips et al., 2018), though many scholars discuss the conceptual potential for more co-created participatory to promote science learning (Bonney et al., 2016; Roche et al., 2020). Our conceptualization links closely to the long and rich history of community-based participatory research in public health (Israel et al., 2013) and environmental justice (Bacon et al., 2013), as well as community science approaches that also foreground community questions and leadership in primarily air and water quality monitoring (Dosemagen & Parker, 2019; Wilson et al., 2018). However, we focus on community-driven science not only to steer away from the debate around terminology in the citizen science and community sciences fields (Cooper et al., 2021; Eitzel et al., 2017), but also to emphasize the particular decision-making roles of community members with respect to science and science learning, and to focus on the ways that the work benefits the community and its members, not just benefits from their participation.

In the remainder of this special issue introduction, we map the terrain of community-driven science using the manuscripts of this issue, delving into three key themes that help us reveal the tensions and contradictions inherent in this often-fraught work. This mapping then allows us to examine the ways community-driven science seems to offer a space in the borderlands between science and communities such that working in “the edges” between worlds increases the possibilities for fostering equity and justice even as it fosters new roles in doing better science. Lastly, we offer the implications these studies have for both research and design in science education.

As we move forward as a field, we must consider how we are responsible and accountable to the varied and powerful forms of community-driven science that exist already, and also how we might design for widespread opportunities to unfold. In this special issue, scholars offer new and different insights into how the field may define community-driven science in support of equity and justice-oriented teaching, learning, and design work. In this last section, we dig more deeply into how and why community-driven science offers a unique space, or set of conditions and drivers, for new forms of science teaching and learning. Consider the concept of “edge effects” in the field of conservation biology. In the locations where two habitats come together, a forest and a grassland, for example, each habitat has its own different temperature, moisture and even soil conditions, as well as different biodiversity of flora and fauna. Rather than a hard boundary, a third kind of habitat with a gradient across each of those conditions exists as a kind of blurring from one habitat to the other; this space is a habitat edge (Ries et al., 2004). In conservation, typically we are concerned with conserving the biodiversity and ecosystem services of each of those “interior” habitats, such that extensive research has been done on how far the negative edge effects penetrate into the interior, threatening the total area covered by rainforest at a landscape scale, for example. But looking closely at the edges themselves, researchers also find positive edge effects, where new ecological communities emerge near habitat edges (Ries et al., 2004); edges actually may often increase biodiversity, because the conditions across the gradient allow for plant and animal species from both kinds of habitats to occupy the same space at the margins of their preferred conditions.

We suggest that community-driven science serves the same role for science learning, by bridging and blurring the boundaries between science and communities. Community-driven science creates new spaces and conditions for community members and scientists to develop new and different roles and relationalities in the work of knowledge building about the world. Taking on these new roles and relationalities can foster identity development in ways that allow people to not only see themselves in command of Western science tools and practices, but also to be seen as experts on their own terms. It can also help to create new legitimized roles in Western science that did not exist before, that reshape the cultural norms of science and science learning to reflect a diversity of knowledge sources and ways of knowing. Rather than focusing only on conserving the conditions and inhabitants of each separate sphere of what is valuable for science learning, standardized tests on one side and lived experiences on the other, for example, community-driven science creates the conditions for negotiation, complementarity, and collective knowledge-building as part of doing and learning science. These negotiations between scientific rigor and community relevance are extensively discussed by scholars of participatory action research (Bradbury & Reason, 2003), a kind of community-driven science, and taken up explicitly by Tan & Faircloth in this issue. These negotiations could be considered a key mechanism through which community-driven science can foster more just science learning experiences.

The manuscripts in this special issue take up provocative, unusual, or previously ignored or marginalized perspectives on what it means to do science, and where science happens. Drawing from Black Feminist Theory: “The margin should not be seen only as a peripheral space, a space of loss and deprivation, but rather as a space of resistance and possibility. The margin is configured as a space of radical opening” (Hooks, 1989, p. 149) and creativity, where new critical discourses take place. These positive edge effects of community-driven science reflect Gutierrez's (2008) notion of a collective Third Space or hybrid space, describing a blending and bridging between learning environments that can allow for and foster a more expansive learning, and where “students begin to reconceive who they are and what they might be able to accomplish.” Within the work of community-driven science, the edges and margins are complex sites of political struggle where the challenges of doing science unfold in different ways from the mainstream, and also where particular science/community ecologies and original territories might emerge and thrive. Working in the edges, community-driven science is constantly questioning how barriers to participation in science get erected and policed in science discourse. What are the “borders” of science and community-driven science? What do these borders call attention to? What's “inside” and “outside” the edges? What makes up the liminal space in-between?

Across articles in this issue, we see how authors grapple with the edges of community-driven science as powerful spaces of negotiation and science co-production. We see this in O'Neill et al.'s and Tan and Faircloth's description of how educators and youth coconstructed new, third spaces through people and place and incubating epistemologies. Such work is fraught, however, as such work involves, as Tan and Faircloth note, “grappling with ambiguity from existing on borderlands.” In cases where youth minoritized by dominant white settler-colonial society, which includes the very culture and practice of science, it takes time and space for youth and educators to figure out how to engage ethically and responsibly in science in ways that acknowledge, value, and legitimize their humanity. Community-driven science work provided that time and space. Each paper in this issue critically notes how expanding views of science and of community actively disrupts and transforms the dominant narratives and cultural practices that, as Tan and Faircloth describe, build and amplify alienating messaging built into the spaces and social structures of science/science education.

Working in the edges, community-driven science requires attention to how connections across landscapes that link areas of habitat, called “corridors” in conservation biology (Hilty et al. 2019), are created, and the inherent tensions therein. Such corridors in community-driven science are important because they make visible the powered relationalities—including the inherent risks—across the landscapes. Figuring out what the edge distance is or could be, how wide corridors may need to be to provide enough of the right kind of habitat of the “interior” habitat type that allows wildlife (and all the associated organisms) to cross and live within that corridor, are all questions related to power, vulnerability, and the possibilities for thriving and well-being.

For example, Tofel-Grehl (this issue) uses the construct of the margin to make visible that which western science erases, shifting the terrain that can make possible authentic constructions of self and community within community-driven science. She explores how one Indigenous Hawaiian youth, Leilani, navigates her own disconnect with STEM while serving as a land protector on the Mauna Kea volcano, the home of the Thirty Meter Telescope being built over the objection of the local Indigenous community. Using the construct of silenced margins, such as when schools avoid controversial socioscientific issues, which in this case involved avoiding any discussion of the Mauna Kea due to the controversy and thus of Leilani and her community, Tofel-Grehl, shows how it was the explicit avoidance of conflict that reinforced the disengagement of Hawaiian students and community from meaningful participation in science learning. She further shows how it is within these “silenced margins” that youth and communities form their opinions and perspectives on the value of science and the scientific community. This is what can result from keeping borders rigid and ignoring the potentiality of corridors that allow for working in the edges.

Likewise, Vakil et al. illustrate the agency that youth, educators and communities have in authoring real and symbolic corridors toward engaging and critiquing science/technology in response to the power dynamics that frame participation—especially when participation requires sociopolitical solidarity toward jamming power widely held societal norms. What could it mean to the field of science education when collaboratively designing for edge work becomes central? Here, we see community-driven science as cultivating corridors for powerful learning and agency that is just and equitable between the interior figured worlds of dominant science and local communities.

In this special issue, we aim to shine light on how and why the field of science education can and should be concerned with understanding equity-centered approaches to communities’ participation in science, especially in communities historically silenced, and its impact on people's learning and participation. This includes highlighting the intersections of community-driven science with the potential possibilities and historically embedded vulnerabilities of the communities in which this work may take place. We hope our collective work here contributes to the knowledge base for the field by making sense of how the work of community-driven science in marginalized communities recognizes their vulnerabilities with, toward, and of, science, while also mobilizing knowledge inherent in those communities.

Thus, undergirding this special issue are a set of commitments that shape this collective inquiry that we hope pushes the work of science teaching and learning forward. First and foremost, community-driven science is of and for the wellbeing of communities and their members. It involves a wide range of people—youth, adults, and/or combinations—working on questions and problems that are authentic to both the disciplines of science and to communities, where data generation and analysis can potentially lead to answering those questions or problems (Morales-Doyle, 2017). Science participation is of, within, and for communities (Calabrese Barton & Tan, 2010). Second, community-driven science supports participants in learning–about science and community and the ways in which they intersect through the concerns at hand (Birmingham, et al., 2017; van Wart et al., 2020). We suggest that when these commitments are met, community-driven science will foster and support science teaching and learning practices that open up, rather than shut down, just and equitable futures for ALL members of society, especially those that have been historically shut out or harmed by dominant science.

社区驱动的科学和科学教育:生活在公平、正义和科学学习的边缘并在其中导航
在促进社区参与科学方面,与公平和正义有关的深刻挑战仍然存在。多种流行病——种族和经济不公正、2019冠状病毒病、枪支暴力和气候变化等——的交叉影响都影响了人们何时、如何以及为什么参与科学,甚至有机会接触科学。公众对科学的不信任也在增加,这具有广泛的影响。反疫苗运动是不信任科学的一种表现,它在很大程度上影响了COVID-19大流行的进程(Tsipursky, 2018)。从“另类事实”到否认气候变化,在企业和政治利益的驱动下,越来越多的公众言论认为,任何经验性立场都可以被否认,因为它不符合个人的愿望或愿望。面对获取科学的不公平、不信任感以及关于什么可以被视为可验证信息的争论,许多人指望科学教育将社会从这种破坏性的螺旋中拯救出来。当然,我们只需要找到更好的方法让人们参与科学?然而,主流科学的文化和实践被用来为种族主义辩护,并将特定的认知、行为和存在方式定位在科学领域之外。所谓“主导科学”,我们指的是西方科学的特定形式,它们已经占据主导地位,以至于“其他认识、行动和存在的方式被认为是非法的或被抹去了”(Liboiron, 2021;21页)。在围绕科学问题的决策和科学理解的产生过程中,历史上缺乏多种声音和观点的包容,科学如何进行缺乏透明度,包括对谁控制议程、谁的知识重要、谁受益的洞察,所有这些都影响了社区如何以及为什么可能或可能不参与科学。因此,科学界和当地社区的许多成员之间存在着重大分歧。在这些紧张关系中出现了社区驱动科学的概念。以密歇根州弗林特为例,这座城市主要居住着非洲裔美国家庭,40%的居民生活在贫困中。2014年,该市居民开始抱怨水变色、难闻、有味道。然而,纽约市和纽约州反应迟缓。居民组织的努力与弗吉尼亚理工大学的外部研究人员合作,记录了后来被称为“近代史”中“最重要”的环境不公正事件之一(泡利,2019年)。他们记录了该市水中氯含量低,导致导致军团病的细菌含量高,而重金属浸入供水的水平违反了《安全饮用水法》(Zahran etal ., 2020),导致儿童血液中的铅含量高。所有这一切都是由于经济、政治和结构性不平等的纠缠,导致州一级决定通过将城市的水支持从处理过的休伦河水改为未经处理的弗林特河水来节省资金(泡利,2019)。将省钱置于人民福祉之上的决定对健康和安全的影响,只是在居民的集体努力下才为人所知。弗林特水危机只是众多影响社区福祉的科学相关问题之一,如果政府和科学机构认真对待人们的日常观察,这些问题本可以产生更积极的结果。医疗保健、食品、环境、气候、能源生产、数字监控、转基因生物和疾病传播只是少数几个需要科学与社会合作的研究领域。最近发生的事件,如COVID-19大流行表明,不仅对科学的不信任增加,科学本身也变得政治化。党派分歧几乎标志着大流行的所有方面,从对公共卫生威胁的严重程度,到对有关病毒来源、可能的治疗方法和疫苗安全性的错误信息的接受。在帮助确定值得调查的问题、生成数据的来源和形式以及为这个星球的未来提供解释方面,人们和社区可以发挥至关重要的作用。但是要做到这一点,科学家需要承认并更好地理解人们和社区的需求、兴趣和知识。更重要的是,大多数科学家并没有被教育或鼓励支持社区参与作为他们工作的一部分。与此同时,出于历史和自我保护的原因,许多不同的社区可能不理解、信任或参与科学事业。 我们在上面指出,有色人种社区和低收入社区,如密歇根州弗林特市的人们,有强大的历史原因造成这种不信任(Ramirez-Andreotta, 2019),因为这些社区经常被科学界以非人性化和有害的方式忽视或沉默。科学教育领域对这些问题负有部分责任,但也是解决这些问题的关键。因此,尽管科学家和政府机构在听取当地社区科学观察和专业知识方面取得了一些进展(例如,Dosemagen &Parker, 2019),以及对公民科学、生态正义和科学教育之间关系的概念性讨论(例如,Mueller &Tippins, 2012),在通过实证研究明确检查科学教育作为问题的一部分和通过社区驱动的科学解决方案方面存在差距。科学教育领域如何应对这些与社区参与科学相关的公平和正义问题是该领域关注的中心问题,科学教育领域内外已经引入了各种方法。从专业科学家的角度来看,有一些关注于社区参与科学,但主要是更广泛地推动“公众参与科学”。从历史上看,这意味着“有意的、有意义的互动,为科学家和公众之间的相互学习提供机会”(美国科学促进会,2018)。这种方法被认为是减少科学与社会之间紧张关系的一种方法。然而,虽然迈出了良好的第一步,但目前促进公众参与的努力也受到了批评,因为(1)社区本身缺乏更真实和实质性的参与形式,特别是历史上被科学和社会边缘化的社区;(2)让这种参与改变科学过程和结果的努力有限(Jadallah等人,在Review中,Stilgoe等人,2014)。此外,侧重于“公众参与科学研究”(Shirk et al., 2012)和“公民科学”(Bonney et al., 2014)的方法确实在通过参与数据收集和产生新的科学知识来邀请公众成员参与科学研究方面走得更远,但这些方法仍然主要集中在由专业科学家推动的项目上,往往缺乏社区成员在决策中的作用。社区科学,通常被定义为更多的社区驱动和关注社区需求。Parker, 2019),更接近有利于当地社区的知识的公平热电联产,但作为一个术语,最近被混淆为包括科学家驱动的努力(Cooper et al., 2021)。社区驱动科学特刊的目标是对社区驱动科学的变化和可能性进行更深入的理解,并对社区驱动科学在科学教育背景下的作用和可能性产生新的理解和话语:它是什么,它是什么样子的,人们学什么,如何实践,以及它对科学和科学教育的知识、实践和话语民主化的影响。对我们来说,社区驱动的科学不仅仅是参与;它是关于科学为造福社会而产生的知识和技能之间的有形和无形关系。关系是社区驱动科学的核心,因为它将人、地点和环境(政治、历史和文化)置于从事和了解科学的核心,而不是与假定的客观性概念保持距离。此外,社区驱动科学的焦点之一是,所有形式的科学都是对社区福祉的贡献,而不是榨取。社区驱动科学的概念在科学教育领域并不新鲜,即使它在研究、发展和改革努力中处于边缘地位。事实上,之前的大量工作都集中在从职前科学教师学习将当地环境正义问题作为学习背景(Varelas et al., 2018)到年轻人在夏季项目中收集当地小溪的水质数据并向市议会提交(Ballard et al., 2017),再到“围栏”组织使用自己的空气监测样本来对抗化工厂(Ottinger, 2010),通过STEM调查组织青年,通过基于地点的科学探究改变当地的不公正现象(Birmingham et al., 2017;Morales-Doyle, 2017;Upadhyay等人,2020)和工程设计(Nazar等人,2019)。我们寻求建立和扩展这项工作,以开发一个框架,说明社区驱动的科学在科学教学方面可能是什么。 我们使用这一总体术语来描述人们如何在当地环境中共同参与科学,并以将他们定位为科学过程和结果的关键利益相关者和决策者的方式,以对他们自己的学习和更广泛的社会变革产生影响的方式。我们把社区驱动的科学看作是让社区成员尽早参与科学过程,作为研究议程的共同所有者,这是为了社区及其成员的福祉和社会未来。这与通常在科学教育背景下研究的更传统的公民科学方法形成鲜明对比,在科学教育背景下,议程是由专业科学家创建和拥有的(例如,Brossard等人,2005,Phillips等人,2018),尽管许多学者讨论了更多共同创造参与性以促进科学学习的概念潜力(Bonney等人,2016;Roche et al., 2020)。我们的概念与社区参与公共卫生研究(Israel等人,2013年)和环境正义(Bacon等人,2013年)的悠久而丰富的历史密切相关,以及社区科学方法,这些方法也突出了社区问题和主要空气和水质监测方面的领导作用(Dosemagen &帕克,2019;Wilson et al., 2018)。然而,我们关注社区驱动的科学不仅是为了避开围绕公民科学和社区科学领域术语的辩论(Cooper等人,2021;Eitzel et al., 2017),还要强调社区成员在科学和科学学习方面的特定决策作用,并关注工作使社区及其成员受益的方式,而不仅仅是从他们的参与中受益。在本期特刊介绍的其余部分,我们利用本期的手稿绘制了社区驱动科学的地形,深入研究了三个关键主题,帮助我们揭示了这项经常令人担忧的工作中固有的紧张和矛盾。然后,这种映射使我们能够检查社区驱动的科学似乎在科学和社区之间的边界地带提供了一个空间的方式,这样,在世界之间的“边缘”工作增加了促进公平和正义的可能性,即使它在做更好的科学方面培养了新的角色。最后,我们提出了这些研究对科学教育研究和设计的启示。当我们作为一个领域向前发展时,我们必须考虑我们如何对已经存在的各种强大的社区驱动科学形式负责和负责,以及我们如何设计广泛的发展机会。在本期特刊中,学者们对该领域如何定义社区驱动的科学以支持以公平和正义为导向的教学、学习和设计工作提供了新的和不同的见解。在最后一节中,我们将更深入地探讨社区驱动的科学如何以及为什么为新形式的科学教学提供了一个独特的空间,或一组条件和驱动因素。考虑到保护生物学领域的“边缘效应”概念。例如,在森林和草原两个栖息地交汇的地方,每个栖息地都有自己不同的温度、湿度甚至土壤条件,以及不同的动植物生物多样性。而不是一个硬边界,第三种栖息地的梯度跨越这些条件,作为一种从一个栖息地到另一个栖息地的模糊存在;这个空间是一个栖息地边缘(Ries et al., 2004)。在保护方面,我们通常关心的是保护生物多样性和生态系统服务,例如,在景观尺度上,我们对负面边缘效应在多大程度上渗透到内部进行了广泛的研究,威胁到雨林覆盖的总面积。但仔细观察边缘本身,研究人员也发现了积极的边缘效应,新的生态群落在栖息地边缘附近出现(Ries et al., 2004);边缘实际上可能经常增加生物多样性,因为在整个梯度上的条件允许来自两种栖息地的植物和动物物种在它们喜欢的条件的边缘占据相同的空间。我们建议,社区驱动的科学通过弥合和模糊科学与社区之间的界限,在科学学习中发挥同样的作用。社区驱动的科学为社区成员和科学家在建立关于世界的知识的工作中发展新的和不同的角色和关系创造了新的空间和条件。承担这些新的角色和关系可以促进身份的发展,使人们不仅认为自己掌握了西方的科学工具和实践,而且还被视为自己的专家。 它还可以帮助在西方科学中创造以前不存在的新的合法角色,重塑科学和科学学习的文化规范,以反映知识来源和认识方式的多样性。例如,社区驱动的科学不是只注重保护对科学学习有价值的每个单独领域的条件和居民,一方面是标准化测试,另一方面是生活经验,而是为谈判、互补性和集体知识建设创造条件,作为科学研究和学习的一部分。这些科学严谨性和社区相关性之间的谈判被参与行动研究的学者广泛讨论(Bradbury &《理性》(Reason, 2003)是一种社区驱动的科学,Tan &在这期节目中。这些谈判可以被认为是一个关键机制,通过它,社区驱动的科学可以促进更公正的科学学习经验。这期特刊中的手稿对科学的意义和科学发生的地方提出了具有挑衅性的、不寻常的或以前被忽视或边缘化的观点。借鉴黑人女性主义理论:“边缘不应被视为一个边缘空间,一个失去和剥夺的空间,而应被视为一个抵抗和可能性的空间。边缘被配置为一个激进开放的空间”(Hooks, 1989, p. 149)和创造力,在那里发生了新的批评话语。社区驱动科学的这些积极的边缘效应反映了Gutierrez(2008)关于集体第三空间或混合空间的概念,描述了学习环境之间的混合和桥梁,可以允许和促进更广泛的学习,并且“学生开始重新认识他们是谁以及他们可能能够完成的事情。”在社区驱动的科学工作中,边缘和边缘是政治斗争的复杂场所,在那里,科学研究的挑战以不同于主流的方式展开,也在那里,特定的科学/社区生态和原始领土可能会出现和繁荣。在边缘工作,社区驱动的科学不断质疑参与科学的障碍是如何在科学话语中建立和管理的。科学和社区驱动的科学的“边界”是什么?这些边界引起了什么注意?什么是“内”和“外”的边缘?是什么构成了中间的有限空间?在本期的文章中,我们看到了作者如何将社区驱动的科学作为强大的谈判和科学合作空间的边缘。我们在O' neill等人、Tan和Faircloth对教育者和青年如何通过人、地点和孵化认识论共同构建新的第三空间的描述中看到了这一点。然而,这样的工作充满了忧虑,正如谭和费尔布所指出的那样,这些工作涉及到“与存在于边界地带的模糊性作斗争”。在白人移民-殖民社会(包括科学的文化和实践)占主导地位的情况下,青年和教育工作者需要时间和空间来弄清楚如何以承认、重视和合法化他们的人性的方式,以道德和负责任的方式参与科学。社区驱动的科学工作提供了这样的时间和空间。本期的每篇论文都批判性地指出,不断扩大的科学和社区观是如何积极地破坏和改变主流叙事和文化实践的,正如Tan和Faircloth所描述的那样,这些叙事和文化实践构建并放大了嵌入科学/科学教育的空间和社会结构中的异化信息。在边缘工作,社区驱动的科学需要关注如何建立连接栖息地区域的景观之间的联系,在保护生物学中称为“走廊”(Hilty et al. 2019),以及其中固有的紧张关系。在社区驱动的科学中,这样的走廊很重要,因为它们使跨领域的动力关系——包括固有风险——变得可见。弄清楚边缘距离是多少或可能是多少,走廊可能需要多宽才能提供足够的“内部”栖息地类型的合适栖息地,允许野生动物(以及所有相关生物)穿过并在走廊内生活,这些都是与权力、脆弱性以及繁荣和福祉的可能性有关的问题。例如,tofell - grehl(本期)使用边缘的结构使西方科学所抹去的东西变得可见,从而改变了可以在社区驱动的科学中实现自我和社区的真实构建的地形。她探讨了夏威夷土著青年Leilani如何在莫纳克亚火山(Mauna Kea volcano)担任土地保护者的同时,处理自己与STEM的脱节,莫纳克亚火山是30米望远镜的所在地,该望远镜是在当地土著社区的反对下建造的。 使用沉默边缘的结构,例如当学校避免有争议的社会科学问题时,在这种情况下,由于争议,包括Leilani和她的社区,tofell - grehl,避免任何关于莫纳克亚山的讨论,表明了如何明确避免冲突,加强了夏威夷学生和社区脱离有意义的参与科学学习。她进一步展示了青年和社区如何在这些“沉默的边缘”中形成他们对科学和科学界价值的意见和观点。这就是保持边界僵化和忽视允许在边缘工作的走廊的潜力所导致的结果。同样地,Vakil等人说明了青年、教育工作者和社区在创建参与和批评科学/技术的真实和象征性走廊方面的作用,以回应构成参与框架的权力动态——特别是当参与需要社会政治团结来干扰权力广泛持有的社会规范时。当为边缘工作进行协作设计成为核心时,这对科学教育领域意味着什么?在这里,我们看到社区驱动的科学作为培养强大的学习和机构的走廊,在主导科学的内部世界和当地社区之间是公正和公平的。在这期特刊中,我们的目标是阐明科学教育领域如何以及为什么能够而且应该关注理解以公平为中心的方法来促进社区参与科学,特别是在历史上沉默的社区,以及它对人们的学习和参与的影响。这包括强调社区驱动的科学与可能开展这项工作的社区的潜在可能性和历史上嵌入的脆弱性的交叉点。我们希望我们在这里的集体工作能够为该领域的知识库做出贡献,通过理解边缘化社区中社区驱动的科学工作如何认识到他们对科学的脆弱性、对科学的脆弱性和对科学的脆弱性,同时也调动这些社区固有的知识。因此,在这个特别问题的基础上,一系列的承诺塑造了我们希望推动科学教学和学习工作向前发展的集体探究。首先,社区驱动的科学是为了社区及其成员的福祉。它涉及范围广泛的人-青年,成年人和/或组合-研究对科学学科和社区都真实的问题和问题,其中数据生成和分析可能导致回答这些问题或问题(莫拉莱斯-多伊尔,2017)。科学参与是社区的,社区内部的,也是社区的(卡拉布雷斯·巴顿&;棕褐色,2010)。其次,社区驱动的科学支持参与者了解科学和社区,以及他们通过手头关注的问题相交的方式(Birmingham等人,2017;van Wart et al., 2020)。我们建议,当这些承诺得到满足时,社区驱动的科学将促进和支持科学教学和学习实践,为所有社会成员,特别是那些历史上被主流科学拒之门外或受到伤害的人,开辟而不是关闭公正和公平的未来。
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来源期刊
Journal of Research in Science Teaching
Journal of Research in Science Teaching EDUCATION & EDUCATIONAL RESEARCH-
CiteScore
8.80
自引率
19.60%
发文量
96
期刊介绍: Journal of Research in Science Teaching, the official journal of NARST: A Worldwide Organization for Improving Science Teaching and Learning Through Research, publishes reports for science education researchers and practitioners on issues of science teaching and learning and science education policy. Scholarly manuscripts within the domain of the Journal of Research in Science Teaching include, but are not limited to, investigations employing qualitative, ethnographic, historical, survey, philosophical, case study research, quantitative, experimental, quasi-experimental, data mining, and data analytics approaches; position papers; policy perspectives; critical reviews of the literature; and comments and criticism.
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