An official website of the United States government
Faculty professional development is an important lever for change in supporting instructors to adopt research-based instructional strategies that engage students intellectually, foster learning-supportive attitudes and habits of mind, and strengthen their persistence in mathematics. Yet the literature contains few well-rationalized models for faculty development in higher education. We describe the rationale and design for a model for discipline-based faculty development to support instructional change, and we detail our implementation of this model as applied to intensive workshops on inquiry-based learning (IBL) in college mathematics. These workshops seek to foster post-secondary mathematics instructors’ adoption of IBL, to help them adapt inquiry approaches for their classrooms, and ultimately to increase student learning and persistence in science and mathematics. Based on observed faculty needs, four strands of activity help instructors develop a mental model for an IBL classroom, adapt that model to their teaching context, develop facilitation and task-design skills, and plan an IBL mathematics course. Evaluation data from surveys and observations illustrate participant responses to the workshop and its components. The model has been robust across 15 years of workshops implemented by three generations of workshop leaders and its features make it adaptive, strategic, and practical for other faculty developers.
more »
« less
Teaching faculty the art of modelling in biology
While a standard calculus course may include some neatly-packaged applications of rate of change or Riemann sums to problems of kinematics, majors from biology and medicine are in urgent need of mathematics taught from a modeling perspective. Yet, the art of modeling is scarce in tertiary mathematics classrooms in part because, much like in schools, many mathematicians may lack (a) the relevant real-world concepts (beyond simple physics and engineering) (b) knowledge of the mathematics from a modeling perspective or (c) confidence to change their classroom practices. To remedy this, we trialed a professional development workshop for faculty to learn to mathematically model biological contexts with dynamical systems. The workshop enacted the field’s recommendations for professional development with teachers. We observed gains in faculty’s self-reported comfort with mathematics and biology concepts and teaching mathematics with a modeling perspective.
more »
« less
- Award ID(s):
- 1750813
- PAR ID:
- 10511000
- Publisher / Repository:
- ICME
- Date Published:
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
More Like this
-
-
The University of Southern California’s (USC) Joint Educational Project’s STEM Education Programs hosted a three-day summer workshop focused on marine microbiology and coastal deoxygenation for high school educators. To increase ocean literacy in high school students from Title I schools, topical marine science research was translated into four lesson plans appropriate for classrooms that teach biology and environmental science. The lesson plans focus on how marine microbes affect and are affected by the dissolved oxygen content of seawater but covered diverse oceanography topics including microbial ecology, nutrient cycling, physical ocean dynamics, and climate change. This education framework was designed to promote and facilitate hands on discovery-based learning and making observations about the natural world. The workshop and lesson plan development were executed in partnership with faculty and graduate students researching marine microbes and oceanography from USC’s Marine and Environmental Biology department to provide scientific expertise on the subject matter. At the workshop, educators were guided through each lesson plan and given classroom sets of materials to complete each of the experiments in their own classrooms. Educators also had the opportunity to experience the academic research process at both USC and the Wrigley Institute of Environmental Studies on Catalina Island, California. Teachers valued this interactive experience to learn from professional scientists and STEM educators. They left the workshop equipped with the knowledge and confidence to teach these marine microbiology and biogeochemistry concepts in their classrooms.more » « less
-
Integrated STEM (science, technology, engineering, and mathematics) education is becoming increasingly common in K–12 classrooms. However, various definitions of STEM education exist that make it challenging for teachers to know what to implement and how to do so in their classrooms. In this article, we describe a series of activities used in a week- long professional development workshop designed to elicit K–12 teachers’ conceptions of STEM and the roles that science, technology, engineering, and mathematics play in STEM education. These activities not only engage teachers in conversations with peers and colleagues in a professional development setting but also enable teachers to reflect on their learning related to STEM education in the context of creating lesson plans and considering future teaching. In addition to describing these activities, we share suggestions related to how these activities may be used in venues outside of professional development.more » « less
-
Kong, S.C. (Ed.)This work aims to help high school STEM teachers integrate computational thinking (CT) into their classrooms by engaging teachers as curriculum co-designers. K-12 teachers who are not trained in computer science may not see the value of CT in STEM classrooms and how to engage their students in computational practices that reflect the practices of STEM professionals. To this end, we developed a 4-week professional development workshop for eight science and mathematics high school teachers to co-design computationally enhanced curriculum with our team of researchers. The workshop first provided an introduction to computational practices and tools for STEM education. Then, teachers engaged in co-design to enhance their science and mathematics curricula with computational practices in STEM. Data from surveys and interviews showed that teachers learned about computational thinking, computational tools, coding, and the value of collaboration after the professional development. Further, they were able to integrate multiple computational tools that engage their students in CT-STEM practices. These findings suggest that teachers can learn to use computational practices and tools through workshops, and that teachers collaborating with researchers in co-design to develop computational enhanced STEM curriculum may be a powerful way to engage students and teachers with CT in K-12 classrooms.more » « less
-
We developed an interdisciplinary course in computational neuroscience to address the need for students trained in both biological/psychological and quantitative sciences. Increasingly, exposure to advanced math and physics is important to stay on the cutting edge of developments and research in neuroscience. Additionally, the ability to work in multidisciplinary teams will continue to be an asset as the field develops. This course brings together students from biology, psychology, biochemistry, engineering, physics, and mathematics. The course was designed to highlight the importance of math in understanding fundamental neuroscience concepts and to prepare students for professional careers in neuroscience. They learn neurobiology, via a ‘biology to model and back again’ approach involving wet- and software/modeling-labs, with the latter being the focus of this papermore » « less
- Free Publicly Accessible Full Text
-
Accepted Manuscript1.0
- Conference Proceeding:
- The DOI is not currently available.
