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1. Investigating Sequencing as a Means to Computational Thinking in Young Children

   https://doi.org/10.21585/ijcses.v6i3.192  

   Tank, Kristina M; Ottenbreit-Leftwich, Anne; Moore, Tamara J; Yang, Sohheon; Wafula, Zarina; Kim, Jiyoung; Fagundes, Bárbara; Chu, Lin (May 2024, International Journal of Computer Science Education in Schools)

   Within the field of K-2 CS education, unplugged computational thinking (CT) activities have been suggested as beneficial for younger students and shown to impact young students’ skills and motivation to learn about CS. This study sought to examine how children demonstrate CT competencies in unplugged sequencing tasks and how children use manipulatives to solve unplugged sequencing tasks. This case study approach examined two unplugged sequencing tasks for six children ranging from ages four to seven (pre-kindergarten to 2nd grade). Children showed evidence of several CT competencies during the sequencing tasks: (1) pattern recognition, (2) algorithms and procedures, (3) problem decomposition, and (4) debugging. The strategies and use of manipulatives to showcase CT competencies seemed to evolve in complexity based on age and developmental levels. Taking into account children’s abilities to demonstrate CT competencies, this study suggests that sequencing is a developmentally appropriate entry point for young children to begin engaging in other CT competencies. In addition, these unplugged sequencing tasks can also be easily integrated into other activities commonly experienced in early childhood classrooms. 

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2. Assessing Computational Thinking Skills in Early Elementary Students: A Focus on Sequencing Tasks

   Wafula, Z; Tank, K; Moore, T; Ottenbreit-Leftwich, A; Fagundes, B; Kim, J (March 2024, Association for the Advancement of Computing in Education (AACE))

   Cohen, J; Solano, G (Ed.)

   The integration of Computational Thinking (CT) into K-12 education has gained significance in recent years as the field of education experiences the need to equip students with essential skills for the 21st century. This case study focused on two sequencing activities, involving plugged and unplugged tasks, conducted with four children aged four to seven, spanning pre-kindergarten to second grade. The central research question guiding the study was: "What computational thinking (CT) skills were demonstrated by K-2 students as they engaged in two different sequencing tasks?" The study identified competencies in sequencing, reverse sequencing, debugging, pattern recognition, and problem decomposition. The findings suggest that both unplugged and plugged sequencing tasks provide age-appropriate entry points for young children to develop various CT competencies. Furthermore, the study highlights the potential for plugged and unplugged sequencing tasks to be integrated into early childhood classroom activities, offering a practical approach to promoting CT skills in young learners. 

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3. Teacher implementation profiles for integrating computational thinking into elementary mathematics and science instruction.

   https://doi.org/10.1007/s10639-020-10115-5  

   Rich, K. M.; Yadav, A.; Larimore, R. (January 2020, Education and information technologies)

   Incorporating computational thinking (CT) ideas into core subjects, such as mathematics and science, is one way of bringing early computer science (CS) education into elementary school. Minimal research has explored how teachers can translate their knowledge of CT into practice to create opportunities for their students to engage in CT during their math and science lessons. Such information can support the creation of quality professional development experiences for teachers. We analyzed how eight elementary teachers created opportunities for their students to engage in four CT practices (abstraction, decomposition, debugging, and patterns) during unplugged mathematics and science activities. We identified three strategies used by these teachers to create CT opportunities for their students: framing, prompting, and inviting reflection. Further, we grouped teachers into four profiles of implementation according to how they used these three strategies. We call the four profiles (1) presenting CT as general problem-solving strategies, (2) using CT to structure lessons, (3) highlighting CT through prompting, and (4) using CT to guide teacher planning. We discuss the implications of these results for professional development and student experiences. 

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4. Preparing special education preservice teachers to teach computational thinking and computer science in mathematics.

   https://doi.org/10.1177/088846421992376376  

   Bouck, E.C. (April 2021, Teacher education and special education)

   null (Ed.)

   Increasingly in K–12 schools, students are gaining access to computational thinking (CT) and computer science (CS). This access, however, is not always extended to students with disabilities. One way to increase CT and CS (CT/CS) exposure for students with disabilities is through preparing special education teachers to do so. In this study, researchers explore exposing special education preservice teachers to the ideas of CT/CS in the context of a mathematics methods course for students with disabilities or those at risk of disability. Through analyzing lesson plans and reflections from 31 preservice special education teachers, the researchers learned that overall emerging promise exists with regard to the limited exposure of preservice special education teachers to CT/CS in mathematics. Specifically, preservice teachers demonstrated the ability to include CT/CS in math lesson plans and showed understanding of how CT/CS might enhance instruction with students with disabilities via reflections on these lessons. The researchers, however, also found a need for increased experiences and opportunities for preservice special education teachers with CT/CS to more positively impact access for students with disabilities. 

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5. Developing Pedagogical Practices That Support Disciplinary Practices When Integrating Computer Science Into Elementary School Curriculum

   Sullivan, Florence; Enrique Suárez; Emrah Pektas; and Lian Duan. (June 2020, Proceedings of the 14th International Conference on the Learning Sciences)

   There is a growing movement seeking to promote Computer Science (CS) and Computational Thinking (CT) across K-8 education. While advantageous for supporting student learning through engaging in complex and interdisciplinary learning, integrating CS/CT into the elementary school curriculum can pose curricular and pedagogical challenges. For one, teachers themselves must understand the concepts and disciplinary practices associated with CS/CT and the other content areas being integrated, as well as develop a related pedagogical repertoire. This study addresses how two 3rd grade teachers made sense of the intersection of disciplinary practices and pedagogical practices to support student learning. We present preliminary findings from a Research-Practice Partnership that worked with elementary teachers to integrate aspects of CS/CT practice into existing content areas. We identified two main disciplinary activities that drove their curriculum design and pedagogical practices: (1) the importance of productive frustration and failure; and (2) the importance of precision 

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