Network Science In Education

1. Front Matter

   Pages i-ix

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2. Creating New Courses

   1. Front Matter

      Pages 1-1

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   2. An Undergraduate Mathematics Course on Networks

      • Mason A. Porter

      Pages 3-21

   3. Leading Edge Learning in Network Science

      • Ralucca Gera

      Pages 23-44

   4. Advances in Nontechnical Network Literacy: Lessons Learned in Tertiary Education

      • Paul van der Cingel

      Pages 45-56

3. Creating New Degree Programs

   1. Front Matter

      Pages 57-57

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   2. Network Science Undergraduate Minor: Building a Foundation

      • Chris Arney

      Pages 59-70

   3. Evaluation of the First US PhD Program in Network Science: Developing Twenty-First-Century Thinkers to Meet the Challenges of a Globalized Society

      • Evelyn Panagakou, Mark Giannini, David Lazer, Alessandro Vespignani, Kathryn Coronges

      Pages 71-85

   4. Europe’s First PhD Program in Network Science

      • János Kertész, Balázs Vedres

      Pages 87-97

4. Education Network Analysis

   1. Front Matter

      Pages 99-99

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   2. Mapping the Curricular Structure and Contents of Network Science Courses

      • Hiroki Sayama

      Pages 101-116

   3. Pay, Position, and Partnership: Exploring Capital Resources Among a School District Leadership Team

      • Alan J. Daly, Yi-Hwa Liou, Peter Bjorklund Jr

      Pages 117-138

5. Tools and Techniques

   1. Front Matter

      Pages 139-139

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   2. Secondary Student Mentorship and Research in Complex Networks: Process and Effects

      • Catherine B. Cramer, Lori Sheetz

      Pages 141-157

   3. The Imaginary Board of Directors Exercise: A Resource for Introducing Social Capital Theory and Practice

      • Brooke Foucault Welles

      Pages 159-167

   4. Network Visualization Literacy: Novel Approaches to Measurement and Instruction

      • Angela Zoss, Adam Maltese, Stephen Miles Uzzo, Katy Börner

      Pages 169-187

   5. Network Science in Your Pocket

      • Toshihiro Tanizawa

      Pages 189-199

6. Back Matter

   Pages 201-205

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Around the globe, there is an increasingly urgent need to provide opportunities for learners to embrace complexity; to develop the many skills and habits of mind that are relevant to today's complex and interconnected world; and to make learning more connected to our rapidly changing workplace and society. This presents an opportunity to (1) leverage new paradigms for understanding the structure and function of teaching and learning communities, and (2) to promote new approaches to developing methods, curricular materials, and resources. Network science - the study of connectivity - can play an important role in these activities, both as an important subject in teaching and learning and as a way to develop interconnected curricula.

Since 2010, an international community of network science researchers and educators has come together to raise the global level of network literacy by applying ideas from network science to teaching and learning. Network Science in Education - which refers to both this community and to its activities - has evolved in response to the escalating activity in the field of network science and the need for people to be able to access the field through education channels.

Network Science In Education: Transformational Approaches in Teaching and Learning appeals to both instructors and professionals, while offering case studies from a wide variety of activities that have been developed around the globe: the creation of entirely new courses and degree programs; tools for K-20 learners, teachers, and the general public; and in-depth analysis of selected programs. As network-based pedagogy and the community of practice continues to grow, we hope that the book's readers will join this vibrant network education community to build on these nascent ideas and help deepen the understanding of networks for all learners.

• teaching network science
• network science as teaching tool
• introducing network theory
• undergraduate network science learning
• network science literacy
• social network analysis education
• STEM teaching and learning
• complexity

• Data Science Institute, Columbia University, New York, USA

  Catherine B. Cramer

• Department of Mathematics, University of California Los Angeles, Los Angeles, USA

  Mason A. Porter

• Department of Systems Science and Industrial Engineering, Binghamton University, State University of New York, Binghamton, USA

  Hiroki Sayama

• Center for Leadership and Diversity in STEM, Department of Mathematical Sciences, United States Military Academy, West Point, USA

  Lori Sheetz

• New York Hall of Science, Corona, USA

  Stephen Miles Uzzo

Catherine B. Cramer works at the intersection of data-driven science, learning and workforce development, specifically as it pertains to the understanding of complexity. She is currently managing industry engagement at the Columbia University Data Science Institute, working with faculty and students with a focus on applying data- driven interdisciplinary research to society’s most complex problems through innovation and collaboration with industry and government.

Mason A. Porter is a professor in the Department of Mathematics at UCLA. His research interests include a plethora of topics in complex systems, networks, nonlinear systems, and their applications. He is a Fellow of both the American Mathematical Society and the American Physical Society.

Hiroki Sayama is a Professor of Systems Science and Industrial Engineering and the Director of the Center for Collective Dynamics of Complex Systems at Binghamton University, State University of New York. His research interests include complex systems, dynamical networks, human and social dynamics, artificial life/chemistry, interactive systems, and other computer/information science related topics.

Lori Sheetz is the Director of the United States Military Academy's Center for Leadership and Diversity in STEM and a collaborator with the Network Science Center at West Point. Her research interests include effective STEM education and outreach within diverse populations traditionally underrepresented in STEM fields, bridging the STEM skills gap between standards-based curriculum and projected workplace skills, and introducing a network approach to teaching and learning to pre-college students and teachers.

Stephen Miles Uzzo is Chief Scientist for the New York Hall of Science where he does research and development of public programs and experiences on complex science and instructional development for pre-service teacher education. His background includes teaching and learning in data driven science, computer graphics systems, engineering and environmental science.