Search for: All records

Background:Engineering's introduction into K–12 classrooms has been purported to support meaningful and inclusive learning environments. However, teachers must contend with dominant discourses embedded in US schooling that justify inequitable distributions of resources. Purpose:Drawing on Gee's notion of discourses, we examine how teachers incorporate language legitimizing socially and culturally constructed values and beliefs. In particular, we focus on the discourse of ability hierarchy—reflecting dominant values of sorting and ranking students based on perceived academic abilities—and the discourse of individual blame—reflecting dominant framings of educational problems as solely the responsibility of individual students or families. We aim to understand how these discourses surface in teachers' reasoning about teaching engineering. Method:We interviewed 15 teachers enrolled in an online graduate program in engineering education. Utilizing critical discourse analysis, we analyzed how teachers drew on discourses of blame and ability hierarchy when reasoning about problems of practice in engineering. Results:Teachers drew on engineering education concepts to reinforce dominant discourses (echoing specific language and preserving given roles) as well as to disrupt (utilizing different language or roles that [implicitly] challenge) dominant discourses. Importantly, teachers could also retool discourses of ability hierarchy (arguing for a more equitable distribution of resources but problematically preserving the values of ranking and sorting students). Conclusions:K–12 schooling's sociohistorical context can shape how teachers make sense of engineering in ways that implicate race, gender, disability, and language, suggesting a need to grapple with how discourses from schooling—and engineering culture—maintain marginalizing environments for students. 

Despite the prevalence and potential of K–12 engineering outreach programs, the moment‐to‐moment dynamics of outreach educators' facilitation of engineering learning experiences are understudied. There is a need to identify outreach educators' teaching moves and to explore the implications of these moves.

We offer a preliminary framework for characterizing engineering outreach educators' teaching moves in relation to principles of ambitious instruction. This study describes outreach educators' teaching moves and identifies learning opportunities afforded by these moves.

Through discourse analysis of video recordings of a university‐led engineering outreach program, we identified teaching moves of novice engineering outreach educators in interaction with elementary student design teams. We considered 18 outreach educators' teaching moves through a lens of ambitious instruction.

In small group interactions, outreach educators used ambitious, conservative, and inclusive teaching moves. These novice educators utilized talk moves that centered students' ideas and agency. Ambitious moves included two novel teaching moves: design check‐ins and revoicing tangible manifestations of students' ideas. Ambitious moves offered students opportunities to engage in engineering design. Conservative moves provided opportunities for students to make technical and affective progress, and to experience engineering norms.

Our work is formative in describing engineering outreach educators' teaching moves and points to outreach educators' capability in using ambitious moves. Ambitious engineering instruction may be a useful framework for designing engineering outreach to support students' participation and progress in engineering design. Additionally, conservative teaching moves, typically considered constraining, may support productive student affect and engagement in engineering design.

 

As K-12 engineering education becomes more ubiquitous in the U.S, increased attention has been paid to preparing the heterogeneous group of in-service teachers who have taken on the challenge of teaching engineering. Standards have emerged for professional development along with research on teacher learning in engineering that call for teachers to facilitate and support engineering learning environments. Given that many teachers may not have experienced engineering practice calls have been made to engage teaches K-12 teachers in the “doing” of engineering as part of their preparation. However, there is a need for research studying more specific nature of the “doing” and the instructional implications for engaging teachers in “doing” engineering. In general, to date, limited time and constrained resources necessitate that many professional development programs for K-12 teachers to engage participants in the same engineering activities they will enact with their students. While this approach supports teachers’ familiarity with curriculum and ability to anticipate students’ ideas, there is reason to believe that these experiences may not be authentic enough to support teachers in developing a rich understanding of the “doing” of engineering. K-12 teachers are often familiar with the materials and curricular solutions, given their experiences as adults, which means that engaging in the same tasks as their students may not be challenging enough to develop their understandings about engineering. This can then be consequential for their pedagogy: In our prior work, we found that teachers’ linear conceptions of the engineering design process can limit them from recognizing and supporting student engagement in productive design practices. Research on the development of engineering design practices with adults in undergraduate and professional engineering settings has shown significant differences in how adults approach and understand problems. Therefore, we conjectured that engaging teachers in more rigorous engineering challenges designed for adult engineering novices would more readily support their developing rich understandings of the ways in which professional engineers move through the design process. We term this approach meaningful engineering for teachers, and it is informed by work in science education that highlights the importance of learning environments creating a need for learners to develop and engage in disciplinary practices. We explored this approach to teachers’ professional learning experiences in doing engineering in an online graduate program for in-service teachers in engineering education at Tufts University entitled the Teacher Engineering Education Program (teep.tufts.edu). In this exploratory study, we asked: 1. How did teachers respond to engaging in meaningful engineering for teachers in the TEEP program? 2. What did teachers identify as important things they learned about engineering content and pedagogy? This paper focuses on one theme that emerged from teachers’ reflections. Our analysis found that teachers reported that meaningful engineering supported their development of epistemic empathy (“the act of understanding and appreciating someone's cognitive and emotional experience within an epistemic activity”) as a result of their own affective experiences in doing engineering that required significant iteration as well as using novel robotic materials. We consider how epistemic empathy may be an important aspect of teacher learning in K-12 engineering education and the potential implications for designing engineering teacher education. 

Developing a strong engineering identity, or sense of belonging in engineering, is essential to pursuing and persisting in the field. Participating in an engineering outreach program is widely seen as an opportunity for youth to ignite and increase an identity as an engineer. As early as elementary school, youth evaluate their experiences, interests, and successes to make choices about possible futures. Although these early experiences and choices influence future participation in, pursuit of, and persistence in engineering, studies of engineering identity development have concentrated on undergraduate and high school learners. This study examines engineering identity development in elementary school students participating in an engineering education outreach program, expanding understanding of early influences on engineering identity formation. This study asks: How do students’ descriptions of their engineering experiences indicate the influence their experiences have on their engineering identity development? This study is embedded in an NSF-funded study of a university-led engineering education outreach program. In this program, pairs of university students facilitated weekly hour-long engineering design challenges in elementary classrooms throughout the school year. At the end of the academic year, we conducted semi-structured interviews with 76 fourth- and fifth-grade students who had participated in the outreach program. The interviewers asked students to rate their enjoyment of and skills in engineering within the context of the program. Iterative qualitative coding was used to elicit emergent patterns in students’ responses and examine them in the context of the Godwin et al (2016) engineering identity framework, using the constructs of interest, performance/competence, and recognition. Responses were then analyzed based on participants’ gender to understand and identify potential differences in influences on engineering identity development. Findings indicate that student talk around interest tended to be more positive, while student talk around performance/competence tended to be more negative, indicating the type of relationships students had with their interest in engineering compared to their perceived skills in doing engineering. However, within the construct of performance/competence, girls used negative language at a higher frequency than boys. Within this construct-based code, there were categories with large variations in positive and negative talk by gender. These gendered patterns provide insight into the differing ways girls and boys interact with engineering and how they start to develop engineering identities. 

BioBlitzes, typically one-day citizen science (CS) events, provide opportunities for the public to participate in data collection for research and conservation, potentially promoting deeper engagement with science. We observed 81 youth at 15 BioBlitzes in the U.S. and U.K., identifying five steps participants use to create a biological record (Exploring, Observing, Identifying, Documenting and Recording). We found 67 youth engaged in at least one of the steps, but seldom in all, with rare participation in Recording which is crucial for contributing data to CS. These findings suggest BioBlitzes should reduce barriers to Recording for youth to increase engagement with science. 

This work-in-progress papers shares the results of the qualitative analysis of the way in which eleven elementary teachers’ understanding and stance toward engineering design changed as a result of engaging in adult-level engineering design projects. Identified themes showed that many teachers had more expansive conceptions of the engineering design process models and steps and that these understanding had connections to their pedagogical thinking about engineering with children. Implications of these findings and themes for teacher professional development standards, professional development design, and interactions between content knowledge and pedagogical knowledge are discussed. 

Elementary educators are increasingly asked to teach engineering design, motivating study of how they learn to teach this discipline. In particular, there is a need to examine how teachers reason about pedagogical situations and dilemmas in engineering—how they draw on their disciplinary understandings, attention to students' thinking, and pedagogical practices to support students' learning.

The purpose of our qualitative study was to examine elementary teachers' pedagogical reasoning in an online graduate program. We asked: What stances do teachers take toward learning and teaching engineering design? How do these stances shift over the course of the program?

We identified two teachers, Alma and Margaret, who exhibited productive shifts in their pedagogical reasoning during the program. Drawing on interviews and videos of their teaching, we developed case studies characterizing their stances toward teaching and learning engineering.

Alma shifted in her reasoning about teaching the design process, from treating it as linear, discrete steps to recognizing the dynamic, overlapping nature of design practices. Similarly, Margaret shifted in how she reasoned about failure and iteration, recognizing the need to help students analyze unexpected design performances to learn from and iterate on their designs. For both teachers, these shifts were dynamic and nonlinear, reflecting both context‐sensitivity and growing stability in their reasoning.

Engineering teacher educators should provide opportunities for teachers to reason about the specific pedagogical dilemmas in engineering and consider how teachers integrate disciplinary understandings with attention to students' reasoning and actions and pedagogical practices.

 

This research paper describes a study of elementary teacher learning in an online graduate program in engineering education for in-service teachers. While the existing research on teachers in engineering focuses on their disciplinary understandings and beliefs (Hsu, Cardella, & Purzer, 2011; Martin, et al., 2015; Nadelson, et al., 2015; Van Haneghan, et al., 2015), there is increasing attention to teachers' pedagogy in engineering (Capobianco, Delisi, & Radloff, 2018). In our work, we study teachers' pedagogical sense-making and reflection, which, we argue, is critical for teaching engineering design. This study takes place in [blinded] program, in which teachers take four graduate courses over fifteen months. The program was designed to help teachers not only learn engineering content, but also shift their thinking and practice to be more responsive to their students. Two courses focus on pedagogy, including what it means to learn engineering and instructional approaches to support this learning. These courses consist of four main elements, in which teachers: 1) Read data-rich engineering education articles to reflect on learning engineering; 2) Participate in online video clubs, looking at classroom videos of students’ engineering and commenting on what they notice; 3) Conduct interviews with learners about the mechanism of a pull-back car; and 4) Plan and teach engineering lessons, collecting and analyzing video from their classrooms. In the context of this program, we ask: what stances do teachers take toward learning and teaching engineering design? What shifts do we observe in their stances? We interviewed teachers at the start of the program and after each course. In addition to reflecting on their learning and teaching, teachers watched videos of students’ engineering and discussed what they saw as relevant for teaching engineering. We informally compared summaries from previous interviews to get a sense of changes in how participants talked about engineering, how they approached teaching engineering, and what they noticed in classroom videos. Through this process, we identified one teacher to focus on for this paper: Alma is a veteran 3rd-5th grade science teacher in a rural, racially-diverse public school in the southeastern region of the US. We then developed content logs of Alma's interviews and identified emergent themes. To refine these themes, we looked for confirming and disconfirming evidence in the interviews and in her coursework in the program. We coded each interview for these themes and developed analytic memos, highlighting where we saw variability and stability in her stances and comparing across interviews to describe shifts in Alma's reasoning. It was at this stage that we narrowed our focus to her stances toward the engineering design process (EDP). In this paper, we describe and illustrate shifts we observed in Alma's reasoning, arguing that she exhibited dramatic shifts in her stances toward teaching and learning the EDP. At the start of the program, she was stable in treating the EDP as a series of linear steps that students and engineers progress through. After engaging and reflecting on her own engineering in the first course, she started to express a more fluid stance when talking more abstractly about the EDP but continued to take it up as a linear process in her classroom teaching. By the end of the program, Alma exhibited a growing stability across contexts in her stance toward the EDP as a fluid set of overlapping practices that students and engineers could engage in.