More Like this

1. Chapter 7: Education

   Etchemendy, John; Fattorini, Loredana; Gangas, Lili; Gil, Yolanda; Goins, Rachel; Hinton, Laura; Koshy, Sonia; Lundgren, Kirsten; Maslej, Nestor; Cruz_Novohatski, Lisa; et al (April 2025, The AI Index 2025 Annual Report)

   Maslej, Nestor; Fattorini, Loredana; Perrault, Raymond; Gil, Yolanda; Parli, Vanessa; Kariuki, Njenga; Capstick, Emily; Reuel, Anka; Brynjolfsson, Erik; Etchemendy, John (Ed.)

   AI has entered the public consciousness through generative AI’s impact on work—enhancing efficiency and automating tasks—but it has also driven innovation in education and personalized learning. Still, while AI promises benefits, it also poses risks—from hallucinating false outputs to reinforcing biases and diminishing critical thinking. With the AI education market expected to grow substantially, ethical concerns about the technology’s misuse—AI tools have already falsely accused marginalized students of cheating—are mounting, highlighting the need for responsible creation and deployment. Addressing these challenges requires both technical literacy and critical engagement with AI’s societal impact. Expanding AI expertise must begin in K–12 and higher education in order to ensure that students are prepared to be responsible users and developers. AI education cannot exist in isolation—it must align with broader computer science (CS) education efforts. This chapter examines the global state of AI and CS education, access disparities, and policies shaping AI’s role in learning. This chapter was a collaboration prepared by the Kapor Foundation, CSTA, PIT-UN and the AI Index. The Kapor Foundation works at the intersection of racial equity and technology to build equitable and inclusive computing education pathways, advance tech policies that mitigate harms and promote equitable opportunity, and deploy capital to support responsible, ethical, and equitable tech solutions. The CSTA is a global membership organization that unites, supports, and empowers educators to enhance the quality, accessibility, and inclusivity of computer science education. The Public Interest Technology University Network (PIT-UN) fosters collaboration between universities and colleges to build the PIT field and nurture a new generation of civic-minded technologists. 

   more » « less
2. Justice‐centered STEM education with multilingual learners to address societal challenges: A conceptual framework

   https://doi.org/10.1002/tea.21999  

   Lee, Okhee; Grapin, Scott (October 2024, Journal of Research in Science Teaching)

   Abstract We propose a conceptual framework for STEM education that is centered around justice for minoritized groups. Justice‐centered STEM education engages all students in multiple STEM subjects, including data science and computer science, to explain and design solutions to societal challenges disproportionately impacting minoritized groups. We articulate the affordances of justice‐centered STEM education for one minoritized student group that has been traditionally denied meaningful STEM learning: multilingual learners (MLs). Justice‐centered STEM education with MLs leverages the assets they bring to STEM learning, including their transnational experiences and knowledge as well as their rich repertoire of meaning‐making resources. In this position paper, we propose our conceptual framework to chart a new research agenda on justice‐centered STEM education to address societal challenges with all students, especially MLs. Our conceptual framework incorporates four interrelated components by leveraging the convergence of multiple STEM disciplines to promote justice‐centered STEM education with MLs: (a) societal challenges in science education, (b) justice‐centered data science education, (c) justice‐centered computer science education, and (d) justice‐centered engineering education. The article illustrates our conceptual framework using the case of the COVID‐19 pandemic, which has presented an unprecedented societal challenge but also an unprecedented opportunity to cultivate MLs' assets toward promoting justice in STEM education. Finally, we describe how our conceptual framework establishes the foundation for a new research agenda that addresses increasingly complex, prevalent, and intractable societal challenges disproportionately impacting minoritized groups. We also consider broader issues pertinent to our conceptual framework, including the social and emotional impacts of societal challenges; the growth of science denial and misinformation; and factors associated with politics, ideology, and religion. Justice‐centered STEM education contributes to solving societal challenges that K‐12 students currently face while preparing them to shape a more just society. 

   more » « less
3. Improving Computer Science Instruction and Computer Use for African American Secondary School Students: A Focus Group Exploration of Computer Science Identity of African American Teachers

   https://doi.org/10.1145/3322385.3322399  

   Hampton, Lelia; Cummings, Robert; Gosha, Kinnis (January 2019, Proceedings of the ACM SIGMIS ‘19: 2019 on Computers and People Research Conference)

   As the demand for computing careers increases, it is important to implement strategies to broaden the participation in computer science for African Americans. Computer science courses and academic pathways are not always offered in secondary schools. Many teachers are not trained in computer science, yet are pushed to incorporate more computing, computational thinking, and computer usage. A qualitative focus group study was implemented to assess the computer science identities of African American teachers and of their respective urban secondary schools serving African American students. Three major codes were identified: district administration of computer and computing implementation, teacher attitudes towards computer science instruction, and teachers’ recommendations to improve computer science and computational thinking instruction and outreach for African American secondary school students. Findings can be used to improve computer science and technology rollout programs from county and district administrations, teacher instruction with digital tools, and computer science outreach for African American secondary school students. 

   more » « less
4. Implications of Gamification in Learning Environments on Computer Sci-ence Students: A Comprehensive Study

   Zahedi, L. Ross (June 2019, 126th Annual Conference and Exposition of American Society for Engineering Education)

   Computers are used in almost all the fields in our daily life –they are used in various occupations and do the tasks with greater precision and as a result, made the life more comfortable. As such, more than 500,000 computing jobs remain unfulfilled in the US (Reported by app association), and many nations need more computer scientist. Therefore, this urge the need for engineering education community and researchers to focus more on underrepresentation of women in CS due to the fact that women currently comprise only 15.7% of computing degrees awarded ; Computer Science has one of the most considerable gender disparities in science, technology, and engineering and the number of female students choosing computer science as their major remains underrepresented regardless of recent improvements; and the reason behind this statistic is the challenges that lessen students’ motivation in CS majors; Programming courses have always had a negative image among students and usually need more practice. In order to increase the number of female students in CS and ensure the health of the community, there is a need to better understand and discover a mechanism that can improve women’s participation in computer science which leads to attracting more female students in computer science. Researchers have explored various engagements strategies in the fields of computer science. One of the strategies that have seen an increase and garnered attention in the last two decades is the use of video game elements or gamification in different fields such as education. Gamification -which usually refers to using video game mechanics in activities not related to video games - aims to increase participants’ engagement and enjoyment. This notion has been increasing popularity over time especially among especially education researchers because game elements -which provide challenges to the players and motivate them to set goals- can be used in learning environments appropriately to enhance the motivation of learners. While there is a strong body of literature around the implications of gamification on student learning, there are inconsistent results in the literature with regards to the interests or attitudes of women. This review aims to provide a critical evaluation of the use of gamification in the application in the existing literature in 1) education 2) computer science and 3) women in computer science to provide a basis for more targeted learning engagement strategies to motivate and retain more women in computing fields and build on the literature on gamification and gender. 

   more » « less
5. Toward a justice‐centered ambitious teaching framework: Shaping ambitious science teaching to be culturally sustaining and productive in a rural context

   https://doi.org/10.1002/tea.21917  

   Luehmann, April; Zhang, Yang; Boyle, Heather; Tulbert, Eve; Merliss, Gena; Sullivan, Kyle (November 2023, Journal of Research in Science Teaching)

   Abstract We find ourselves at a time when the need for transformation in science education is aligning with opportunity. Significant science education resources, namely the Next Generation Science Standards (NGSS) and the Ambitious Science Teaching (AST) framework, need an intentional aim of centering social justice for minoritized communities and youth as well as practices to enact it. While NGSS and AST provide concrete guidelines to support deep learning, revisions are needed to explicitly promote social justice. In this study, we sought to understand how a commitment to social justice, operationalized through culturally sustaining pedagogy (Paris, Culturally sustaining pedagogies and our futures.The Educational Forum, 2021; 85, pp. 364–376), might shape the AST framework to promote more critical versions of teaching science for equity. Through a qualitative multi‐case study, we observed three preservice teacher teams engaged in planning, teaching, and debriefing a 6‐day summer camp in a rural community. Findings showed that teachers shaped the AST sets of practices in ways that sustained local culture and addressed equity aims: anchoring scientific study in phenomena important to community stakeholders; using legitimizing students' stories by both using them to plan the following lessons and as data for scientific argumentation; introducing local community members as scientific experts, ultimately supporting a new sense of pride and advocacy for their community; and supporting students in publicly communicating their developing scientific expertise to community stakeholders. In shaping the AST framework through culturally sustaining pedagogy, teachers made notable investments: developing local networks; learning about local geography, history, and culture; building relationships with students; adapting lessons to incorporate students' ideas; connecting with community stakeholders to build scientific collaborations; and preparing to share their work publicly with the community. Using these findings, we offer a justice‐centered ambitious science teaching (JuST) framework that can deliver the benefits of a framework of practices while also engaging in the necessarily more critical elements of equity work. 

   more » « less