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Journal of Science Education and Technology

Erschienen in:

01.10.2014

Interest-Driven Learning Among Middle School Youth in an Out-of-School STEM Studio

verfasst von: Michael A. Evans, Megan Lopez, Donna Maddox, Tiffany Drape, Rebekah Duke

Erschienen in: Journal of Science Education and Technology | Ausgabe 5/2014

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Abstract

The concept of connected learning proposes that youth leverage individual interest and social media to drive learning with an academic focus. To illustrate, we present in-depth case studies of Ryan and Sam, two middle-school-age youth, to document an out-of-school intervention intended to direct toward intentional learning in STEM that taps interest and motivation. The investigation focused on how Ryan and Sam interacted with the designed elements of Studio STEM and whether they became more engaged to gain deeper learning about science concepts related to energy sustainability. The investigation focused on the roles of the engineering design process, peer interaction, and social media to influence youth interest and motivation. Research questions were based on principles of connected learning (e.g., self-expression, lower barriers to expertise, socio-technical supports) with data analyzed within a framework suggested by discursive psychology. Analyzing videotaped excerpts of interactions in the studio, field notes, interview responses, and artifacts created during the program resulted in the following findings: problem solving, new media, and peer interaction as designed features of Studio STEM elicited evidence of stimulating interest in STEM for deeper learning. Further research could investigate individual interest-driven niches that are formed inside the larger educational setting, identifying areas of informal learning practice that could be adopted in formal settings. Moreover, aspects of youth’s STEM literacy that could promote environmental sustainability through ideation, invention, and creativity should be pursued.

Vorheriger Artikel The Bayer Facts of Science Education XVI: US STEM Workforce Shortage—Myth or Reality? Fortune 1000 Talent Recruiters on the Debate

Nächster Artikel Development of a Short-Form Measure of Science and Technology Self-efficacy Using Rasch Analysis

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Andersen HM, Nielsen BL (2013) Video-based analyses of motivation and interaction in science classrooms. Int J Sci Educ 35(6):906–928.CrossRef

Asghar A, Ellington R, Rice E, Johnson F, Prime GM (2012) Supporting STEM education in secondary science contexts. Interdiscip J Probl Based Learn 6(2):4

Barron B (2000) Achieving coordination in collaborative problem-solving groups. J Learn Sci 9(4):403–436CrossRef

Barrows HS (1998) The essentials of problem-based learning. J Dent Educ 62(9):630–633

Blickenstaff JC (2005) Women and science careers: leaky pipeline or gender filter? Gend Educ 17:4

Brophy S, Klein S, Portsmore M, Rogers C (2008) Advancing engineering education in P-12 classrooms. J Eng Educ 97(3):369–387CrossRef

Charmaz K (2006) Constructing grounded theory. Sage Publications, Thousand Oaks, CA

Cohen C, Kahne J (2012) Participatory politics: new media and youth political action. http://ypp.dmlcentral.net/sites/all/files/publications/YPP_Survey_Report_FULL.pdf

Corbin J, Strauss A (2008) Basics of qualitative research. Sage Publications Inc, Thousand Oaks

Crowley K, Jacobs M (2002) Islands of expertise and the development of family scientific literacy. In: Leinhardt G, Crowley K, Knutson K (eds) Learning conversations in museums. Lawrence Erlbaum Associates, Mahwah, NJ

Eccles JS (2005) Studying gender and ethnic differences in participation in math, physical science and information technology. New Dir Child Adolesc Dev 110:7–14CrossRef

Evans MA, Won S, Drape T (2014) Interest-driven learning of STEM concepts among youth interacting through social media. Int J Soc Media Interact Learn Environ 2(1):3–20

Grimes S, Fields D (2012) Kids online: a new research agenda for understanding social networking forums. The Joan Ganz Cooney Center at Sesame Workshop, New York

Hannafin MJ, Hill JR, Land SM, Lee E (2014) Student-centered, open learning environments: research, theory, and practice. In: Spector M, Merrill MD, Elen J, Bishop MJ (eds) Handbook of research on educational communications and technology, 4th edn. Springer, New York, pp 641–651

Honey M, Kanter DE (2013) Design, make, play: growing the next generation of science innovations. Rutledge, London

Ito M, Gutiérrez K, Livingstone S, Penuel B, Rhodes J, Salen K, Schor J, Sefton-Green J, Watkins S (2013) Connected learning: an agenda for research and design. Digital Media and Learning Research Hub, Irvine, CA

Kolodner JL (2004) The learning sciences: past, present, and future. Educ Technol Mag Manag Change Educ 44(3):37–42

Kwan A (2009) Problem-based learning. In: The Routledge International Handbook of Higher Education, pp 91–107

Marcu G, Tassini K, Carlson Q, Goodwyn J, Rivkin G, Schaefer KJ, Kiesler S (2013) Why do they still use paper? Understanding data collection and use in Autism education. In: Proceedings of the SIGCHI conference on human factors in computing systems. ACM, pp 3177–3186

Merchant G (ed) (2012) Virtual literacies: interactive spaces for children and young people, vol 84. Routledge

Patton MQ (2002) Qualitative research and evaluation methods. Sage Publications, Thousand Oaks, CA

Pellegrino JW (2012) Education for life and work: developing transferable knowledge and skills in the 21st century. The National Academies Press, Washington, DC

Schmidt HG, Rotgans JI, Yew EH (2011) The process of problem-based learning: what works and why. Med Educ 45(8):792–806. doi:10.1111/j.1365-2923.2011.04035.x CrossRef

Schnittka CG, Bell RL (2011) Engineering design and conceptual change in the middle school science classroom. Int J Sci Educ 33(13):1861–1887CrossRef

Schnittka CG, Brandt C, Jones B, Evans MA (2012) Informal engineering education after school: a studio model for middle school girls and boys. Adv Eng Educ 3(2):1–31

Siegel M, Derry S, Kim JB, Steinkuehler C, Street J, Canty N, Fassnacht C, Hewson K, Hmelo C, Spiro R (2000) Promoting teachers’ flexible use of the learning sciences through case-based problem solving on the WWW: a theoretical design approach. In: Fishman B, O’Connor-Divelbiss S (eds) Fourth international conference of the learning sciences. Erlbaum, Mahwah, NJ, pp 273–279

Subramaniam MM (2012) Reimagining the role of school libraries in STEM education: creating hybrid spaces for exploration. Libr Q (Chicago) 82(2):161–182. doi:10.1086/664578 CrossRef

Swarat S, Ortony A, Revelle W (2012) Activity matters: understanding student interest in school science. J Res Sci Teach 49(4):515–537CrossRef

Torp L, Sage S (2002) Problems as possibilities problem-based learning for K-16 education. Association for Supervision and Curriculum Development, Alexandria, VA

United States National Science Foundation: Office of the Director—Committee on Equal Opportunities in Science and Engineering (CEOSE) (nd) (2004) National Science Foundation. http://www.nsf.gov/od/iia/activities/ceose/. Accessed July 3 2013

Walther JB, Loh T, Granka L (2005) Let me count the ways: the interchange of verbal and nonverbal cues in computer-mediated and face-to-face affinity. J Lang Soc Psychol 24–36

Yin RK (2009) Case study research design and methods, vol 5, 4th edn. Sage Inc, Thousand Oaks

Titel: Interest-Driven Learning Among Middle School Youth in an Out-of-School STEM Studio
verfasst von: Michael A. Evans
Megan Lopez
Donna Maddox
Tiffany Drape
Rebekah Duke
Publikationsdatum: 01.10.2014
Verlag: Springer Netherlands
Erschienen in: Journal of Science Education and Technology / Ausgabe 5/2014
Print ISSN: 1059-0145
Elektronische ISSN: 1573-1839
DOI: https://doi.org/10.1007/s10956-014-9490-z

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