From the era of European empire to the global trades escalated after the World Wars, technological advancement, one of the key underlying conditions of globalization, has been closely linked with the production and reproduction of the colonizer/colonized. The rhetoric of modernity characterized by “salvation,” “rationality,” “development,” and nature-society or nature-culture divides underlies dominant perspectives on Science, Technology, Engineering, and Mathematics (STEM) education that have historically positioned economic development and national security as its core values. Such rhetoric inevitably and implicitly generates the logic of oppression and exploitation. Against the backdrop of nationalist and militaristic discourse representing modernity or coloniality, counter-voices have also arisen to envision a future of STEM education that is more humane and socioecologically just. Such bodies of critiques have interrogated interlocking colonial domains that shape the realm of STEM education: (a) settler colonialism, (b) paternalism, genderism, and coloniality, and (c) militarism and aggression and violence against the geopolitical Other. Our ways of knowing and being with STEM disciplines have been inexorably changed in the midst of the COVID-19 pandemic, which powerfully showed us how we live in the global chain of contagion. What kinds of portrayal can we depict if we dismantle colonial imaginaries of STEM education and instead center decolonial love—love that resists the nature-culture or nature-society divide, love to know our responsibilities and enact them in ways that give back, love that does not neglect historical oppression and violence yet carries us through? STEM education that posits decolonial love at its core will be inevitably and critically transdisciplinary, expanding the epistemological and ontological boundaries to embrace those who had been colonized and disciplined through racialized, gendered, and classist disciplinary practices of STEM.
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“Globalization,” Coloniality, and Decolonial Love in STEM Education
Miwa A. Takeuchi and Ananda Marin
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Multiliteracies in Professional Education
Kathryn Hibbert, Mary Ott, Christopher Eaton, and Lin Sun
Multiliteracies theory is part of a growing and evolving body of research tangled up with multiple, intersecting fields: literacies, technologies, pedagogies, socio-materiality, and semiotics, to name a few. It is a theory that has been taken up largely in the professional practice of teacher education but is rapidly emerging as a useful way to think through the complexities of practice in multiple professions such as medical education, or engineering. As learning has come to be understood and framed in ways that acknowledge the temporal, spatial, material, and embodied layers of understanding, practice-based professions are finding ways to investigate and support knowing in practice.
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Schooling, Educational Technology, and Teachers’ Everyday Practice in Norway
Rune Johan Krumsvik and Øystein Olav Skaar
Research shows that for decades, there have been attempts to implement information and communication technology (ICT) in schools, but it has had a weak uptake among teachers thus far. One of the reasons for this lack of integration is that teachers perceive ICT as an additional load on their everyday practices that would increase the complexity of their roles. Teachers are therefore often cautious and sceptical about ICT implementation because it is often not properly attached to deeply entrenched school structure. Adaptive learning tools have provided new opportunities to facilitate this integration. Adaptive learning tools are expected to contribute to the customization and personalization of pupil learning by continually calibrating and adjusting pupils’ learning activities to their skill and competence levels. However, it is important to discuss whether adaptive learning tools need to be sufficiently anchored in the curriculum, in formative assessment, in adaptive education, and in homework to achieve their potential. In this way, we can obtain an understanding of how a systematic implementation of adaptive learning tools influences the learning outcomes, learning environment, and motivation of pupils in school, when such tools are attached to the deeply entrenched structures in school. In such implementation processes it seems like we need to reconsider the value of homework to achieve, for example, sufficient volume training and root learning with adaptive learning tools, thus freeing up time for practical mathematics and deep learning at school. Importantly, this requires a digital competence among teachers, where the critical factor is the teacher’s ability to create a teaching doctrine in which technology use is justified by didactic choices.
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STEM Education, Economic Productivity, and Social Justice
David E. Drew
Just as the factory assembly line replaced the farmer’s plow as the symbol of economic productivity at the beginning of the 19th century, so the computer and its software have replaced the assembly line at the beginning of the 21st century. In the United States, and in countries around the world, STEM (Science, Technology, Engineering and Mathematics) education has moved front and center in national discussions of both productivity and social justice. This article will include (a) a review of how the world of work has changed, with a special focus on the history and impact of digital technology since ca. 1970; (b) lessons from research about K-12 education—elementary, middle school, and secondary education—and about higher education; and (c) research about how to increase access to education, and facilitate achievement, for those who traditionally have been under-represented in STEM education. Rigorous research has demonstrated how psychological and sociological factors (e.g., self-concepts, instructor expectations, and social support) often make the difference between student success and failure. To fully contextualize consideration of STEM education, many advocate broadening STEM to STEAM by including the arts, or the arts and humanities, in building educational programs.
In today’s world a young person who wishes to secure a better life for himself or herself would be well advised to study STEM. Furthermore, a nation that wishes to advance economically, while reducing the gap between the have’s and the have-not’s, should strengthen its STEM education infrastructure.