Science, Technology, Engineering, and Math (STEM) teaching strategies that engage students and create an atmosphere of community are desperately needed to recruit, retain, and best prepare students in STEM fields to address challenges facing the 21st Century. Research shows that student performance and persistence in a STEM degree is associated primarily with three aspects of their experience: intellectual engagement and achievement, motivation (e.g., having role models), and identification with a STEM field (e.g., developing meaningful relationships, being part of the community). While there is a large body of work about pedagogies and strategies that address these needs (e.g., active learning, experiential learning, service learning, flipped classrooms, etc.), the majority of university instructors are slow to adopt new teaching strategies. Most STEM faculty were never trained to be teachers, and there are many well documented reasons that faculty are slow to change teaching habits (e.g., Frederick, 1986). According to Sarason and Banbury (2004), “many faculty accept the premises of active learning but do not have adequate tools to bring active learning techniques into the classroom.”
Games and game-based learning have been used in many classrooms as an active learning strategy. Game-based learning is a well-documented method to engage and motivate students with course material in order to improve student-learning outcomes. One very successful and popular game is Clarkson University’s Energy Choices board game (see box on p. 3). This award-winning board game teaches concepts of energy; research shows that when game play was integrated into the curriculum, this game was shown to increase desired cognitive (e.g., documented improvements to math and science achievement scores) and affective (e.g., student interest and confidence in STEM) outcomes. In addition, the Energy Choices board game is widespread. Using Energy Choices as inspiration, we are developing a framework for integrating game design into civil engineering and construction management curriculum that makes it easier to develop and publish games like Energy Choices.
We are developing a set of game design approaches for use in the classroom that promote high levels of student engagement, create a sense of community, improve student metacognition, increase student retention in STEM, all the while being easily transferable and scalable. This poster describes how we have piloted game design in our courses and elucidates characteristics of successful approaches to game design and game play in civil engineering and construction courses. By involving students in game play and game design, we not only better engage students, we also create community and drive students to higher levels of metacognition. We have also found that following game play with game design easily moves students up the cognitive dimension of Bloom’s taxonomy, from merely understanding, to reflection, creation, and evaluation. Board games and role-playing games are formats that create community; students interact with one another over intellectual, enjoyable, and memorable shared experiences. We have found that board game play engages 100% of students in our classroom compared to other types of active learning strategies. And finally, board games and role-playing games are an ideal format because any faculty or student can easily modify them. This poster presents our project results to date and provides recommendations and resources to adopt game design in civil engineering and construction courses nationwide.
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