More Like this

1. Responding to incorrect ideas: science graduate teaching assistants’ operationalization of error framing and undergraduate students’ perception

   https://doi.org/10.1186/s40594-023-00398-8  

   Wan, Tong; Doty, Constance M.; Geraets, Ashley A.; Saitta, Erin K. H.; Chini, Jacquelyn J. (January 2023, International Journal of STEM Education)

   Abstract BackgroundIn college science laboratory and discussion sections, student-centered active learning strategies have been implemented to improve student learning outcomes and experiences. Research has shown that active learning activities can increase student anxiety if students fear that they could be negatively evaluated by their peers. Error framing (i.e., to frame errors as natural and beneficial to learning) is proposed in the literature as a pedagogical tool to reduce student anxiety. However, little research empirically explores how an instructor can operationalize error framing and how error framing is perceived by undergraduate students. To bridge the gap in the literature, we conducted a two-stage study that involved science graduate teaching assistants (GTAs) and undergraduate students. In stage one, we introduced cold calling (i.e., calling on non-volunteering students) and error framing to 12 chemistry and 11 physics GTAs. Cold calling can increase student participation but may increase student anxiety. Error framing has the potential to mitigate student anxiety when paired with cold calling. GTAs were then tasked to rehearse cold calling paired with error framing in a mixed-reality classroom simulator. We identified GTA statements that aligned with the definition of error framing. In stage two, we selected a few example GTA error framing statements and interviewed 13 undergraduate students about their perception of those statements. ResultsIn the simulator, all the GTAs rehearsed cold calling multiple times while only a few GTAs made error framing statements. A thematic analysis of GTAs’ error framing statements identified ways of error indication (i.e., explicit and implicit) and framing (i.e., natural, beneficial, and positive acknowledgement). Undergraduate student interviews revealed specific framing and tone that are perceived as increasing or decreasing student comfort in participating in classroom discourse. Both undergraduate students and some GTAs expressed negative opinions toward responses that explicitly indicate student mistakes. Undergraduate students’ perspectives also suggest that error framing should be implemented differently depending on whether errors have already occurred. ConclusionError framing is challenging for science GTAs to implement. GTAs’ operationalizations of error framing in the simulator and undergraduate students’ perceptions contribute to defining and operationalizing error framing for instructional practice. To increase undergraduate student comfort in science classroom discourse, GTAs can use implicit error indication. In response to students’ incorrect answers, GTAs can positively frame students’ specific ideas rather than discussing broadly how errors are natural or beneficial. 

   more » « less
2. Characterizing graduate teaching assistants’ teaching practices in physics “mini-studios”

   https://doi.org/10.1119/perc.2019.pr.Wan  

   Wan, Tong; Doty, Constance M.; Geraets, Ashley A.; Saitta, Erin K.; Chini, Jacquelyn J. (January 2020, 2019 Physics Education Research Conference Proceedings)

   In this study, we characterized GTAs’ teaching practices in algebra-based introductory physics “mini-studios,” which combine student-centered recitation and inquiry-based labs. We documented both GTA and student actions using an observation protocol adapted from the Laboratory Observation Protocol for Undergraduate STEM (LOPUS). We observed 72 mini-studio sessions led by 11 GTAs over two semesters. We used an agglomerative hierarchical cluster analysis and identified three clusters that described the similarities and differences between individual sessions. Two clusters contained sessions characterized by more interactive GTAs but they varied in the amount of feedback, lecture and whole class questioning the GTA provided. In the third cluster, GTAs tended to wait for students to call on them before engaging. Student behaviors also varied between the clusters, suggesting correlations between student behaviors and GTA instructional styles, in contrast to previous findings with LOPUS in other contexts. We discuss implications of these findings for future research. 

   more » « less
3. Where’s My Whiteboard? The Challenge of Moving Active-learning Mathematics Classes Online

   Nelson, Jill K.; Rosenberg, Jessica; Fernandez, Kathryn; Shank, Julie (July 2021, 2021 ASEE Virtual Annual Conference)

   null (Ed.)

   This research paper studies the challenges that mathematics faculty and graduate teaching assistants (GTAs) faced when moving active and collaborative calculus courses from in-person to virtual instruction. As part of a larger pedagogical change project (described below), the math department at a public Research-1 university began transitioning pre-calculus and calculus courses to an active and collaborative learning (ACL) format in Fall 2019. The change began with the introduction of collaborative worksheets in recitations which were led by GTAs and supported by undergraduate learning assistants (LAs). Students recitation periods collaboratively solving the worksheet problems on whiteboards. When COVID-19 forced the rapid transition to online teaching, these ACL efforts faced an array of challenges. Faculty and GTA reflections on the changes to teaching and learning provide insight into how instructional staff can be supported in implementing ACL across various modes of instruction. The calculus teaching change efforts discussed in this paper are part of an NSF-supported project that aims to make ACL the default method of instruction in highly enrolled gateway STEM courses across the institution. The theoretical framework for the project builds on existing work on grassroots change in higher education (Kezar and Lester, 2011) to study the effect of communities of practice on changing teaching culture. The project uses course-based communities of practice (Wenger, 1999) that include instructors, GTAs, and LAs working together to design and enact teaching change in the targeted courses alongside ongoing professional development for GTAs and LAs. Six faculty and five GTAs involved in the teaching change effort in mathematics were interviewed after the Spring 2020 semester ended. Interview questions focused on faculty and GTA experiences implementing active learning after the rapid transition to online teaching. A grounded coding scheme was used to identify common themes in the challenges faced by instructors and GTAs as they moved online and in the impacts of technology, LA support, and the department community of practice on the move to online teaching. Technology, including both access and capabilities, emerged as a common barrier to student engagement. A particular barrier was students’ reluctance to share video or participate orally in sessions that were being recorded, making group work more difficult than it had been in a physical classroom. In addition, most students lacked access to a tablet for freehand writing, presenting a significant hurdle for sharing mathematical notation when physical whiteboards were no longer an option. These challenges point to the importance of incorporating flexibility in active learning implementation and in the professional development that supports teaching changes toward active learning, since what is conceived for a collaborative physical classroom may be implemented in a much different environment. The full paper will present a detailed analysis of the data to better understand how faculty and GTA experiences in the transition to online delivery can inform planning and professional development as the larger institutional change effort moves forward both in mathematics and in other STEM fields. 

   more » « less
4. GTAs’ Conceptualization of Active Learning in Undergraduate Mathematical Sciences Courses

   Houston, Scotty; Gomez, Josias; Webb, Jessica; Harrell-Williams, Leigh (January 2020, 23rd Annual Conference on Research in Undergraduate Mathematics Education Conference (RUME))

   Karunakaran, Shiv Smith; Reed, Zackery; Higgins, Abigail (Ed.)

   Throughout the past few decades, the term active learning has been used to describe a variety of classroom instructional techniques and pedagogy. In this poster, we explore the conceptualization and implementation of active learning strategies for graduate teaching assistants (GTAs) in three Departments of Mathematical Sciences at the start of a funded project evaluating a multifaceted GTA training model. 

   more » « less
5. Student perspective of GTA strategies to reduce feelings of anxiousness with cold-calling

   https://doi.org/10.1119/perc.2019.pr.Doty  

   Doty, Constance M.; Geraets, Ashley A.; Wan, Tong; Saitta, Erin K.; Chini, Jacquelyn J. (January 2020, 2019 Physics Education Research Conference Proceedings)

   We investigated student perceptions of cold calling on their feelings of anxiousness and how graduate teaching assistants (GTAs) alleviated these feelings when students shared their ideas publicly in the context of tutorial and laboratory sessions. Physics and chemistry GTAs who led active-learning tutorials and labs practiced cold calling paired with error framing with avatar-students in a mixed-reality simulator at the beginning of the semester. Then, we observed the GTAs teaching real students in their actual classroom. We recruited eleven students from sections led by GTAs who were observed to use cold calling in their classroom to participate in semi-structured interviews. Several students reported that cold calling increased their feelings of anxiousness. However, students also reported that GTAs used strategies paired with cold calling that reduced their feelings of anxiousness, such as acknowledging student responses as valuable and remembering student names. We discuss implications for professional development on active learning strategies. 

   more » « less