Argument-Driven Engineering in Middle School Science: An Exploratory Study of Changes in Engineering Identity Over an Academic Year

Chu, Lawrence; Sampson, Victor; Hutner, Todd L.; Rivale, Stephanie; Crawford, Richard H.; Baze, Christina L.; Brooks, Hannah Smith

doi:10.7771/2157-9288.1249

Cited by 11 publications

(5 citation statements)

References 32 publications

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“…A model that allows these design tasks to be completed in a few weeks is suggested. The EDP comprises eight stages: introducing the problem, concept generation, concept selection, design argumentation, design testing, evaluation argumentation, report development, and reflection and discussion (Chu et al, 2019).…”

Section: Engineering Design Process (Edp)mentioning

confidence: 99%

Grade-7 Students’ Negotiation during the Engineering Design Processes Regarding the Status of Their Argumentation Training

Tuğ,

Namdar

2024

Sci Insights Educ Front

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This study aimed to investigate grade-7 students’ negotiation during the engineering design process regarding the students’ status of argumentation training. The participants were 33 students studying at a public urban middle school in Turkey. They worked in small groups on four engineering design tasks about electricity and light. Data were collected through small group audio recordings, student worksheets, and the observation. The data were analyzed by using content analysis. The results indicated that negotiation patterns were similar across all groups. However, differences were found between the group that received argumentation training and the one that did not receive in terms of proposing ideas for material design, using justifications when in agreement with others, counter proposing and acquiring information for better planning and altering the design, and critiquing for design advantages and disadvantages.

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Section: Engineering Design Process (Edp)mentioning

confidence: 99%

Grade-7 Students’ Negotiation during the Engineering Design Processes Regarding the Status of Their Argumentation Training

Tuğ,

Namdar

2024

Sci Insights Educ Front

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“…Researchers have documented the various barriers within school environments that are likely to limit children's identity as an engineer. These barriers include lack of preparation and knowledge of prospective and practicing teachers (Banilower et al, 2018; Chu et al, 2019), lack of time for planning and implementing engineering lessons (Hammack & Ivy, 2019), lack of administrative support (Hammack & Ivy, 2019), difficulty in including student‐centered lessons that incorporate an engineering design cycle (Nadelson et al, 2016), the pressure around high‐stakes testing in reading and mathematics (Chu et al, 2019), and an overall misconception and stereotypical view of engineers (Hammack & Ivey, 2017). Alternatively, others advocate for out‐of‐school learning environments as places that support children's identity in STEM (e.g., Bell et al, 2017; Calabrese Barton et al, 2021; S. A. Pattison et al, 2018; Simpson & Knox, 2022).…”

Section: Relevant Literaturementioning

confidence: 99%

Children's engineering identities‐in‐practice: An exploration of child–adult interactions in an out‐of‐school context

Simpson,

Knox,

Yang

2023

J of Engineering Edu

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BackgroundResearch points to family talk and interactions involving STEM concepts as one of the most influential informal learning experiences that shape an individual's STEM identity development and encourage their pursuit of a STEM career. However, a recent literature review uncovers limited research regarding the development of engineering identity in young children.PurposeThe purpose of this study was to add to this scant literature by exploring how children position themselves as engineers and how children are positioned as engineers through interactions with parents and other adults within a program focused on family engagement within an engineering design process.MethodsThis study includes two parent–child dyads. We collected and analyzed approximately 19.5 h of video data of the two child–parent dyads interacting with one another throughout an engineering design process as part of an out‐of‐school program.ResultsResults highlight three ways in which the two children enacted various engineering identities through their positioning, negotiation, and acceptance and/or rejection of positionalities as they engaged in an engineering design process with a parent. These identity enactments included (a) possessing knowledge and authority to make decisions regarding the development of their self‐identified engineering problem and prototype; (b) questioning and challenging adult ideas, solutions, and construction of prototypes; and (c) documenting and communicating their thinking regarding the engineering design through sketches and notes.ConclusionsThe significance of this study lies in its potential to change the landscape of those who pursue an engineering career and to contribute to the limited research and ongoing conversations about how to foster environments that support families in creative and collaborative learning specific to the engineering discipline.

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“…He concluded that scaffolded questions need to be embedded in design‐oriented tasks if science learning is a goal. Chu et al (2019) implemented an instructional model that enabled students to engage in engineering design challenges in an eighth‐grade science classroom over an academic year and reported no changes in students' engineering identity and a decrease in their interest in engineering. They argued that the findings could be partially attributed to the difficulty and complexity of the design tasks.…”

Section: Literature Reviewmentioning

confidence: 99%

“…While some studies show that incorporating engineering design can facilitate the learning of STEM concepts (Hmelo et al, 2000; Kolodner et al, 2003; Mehalik et al, 2008; Sneider & Ravel, 2021), increase STEM interest and motivation (Sneider & Ravel, 2021), and reduce achievement gaps for underrepresented populations (Cantrell et al, 2006; Mehalik et al, 2008), other studies emphasize the challenges with integrating engineering into science learning. Examples of these challenges include the complexity and difficulty of design tasks (Chu et al, 2019), students' difficulties in making connections between the design activities and the underlying science concepts (Kanter, 2010; Silk et al, 2009; Vattam & Kolodner, 2008), and a lack of experience and exposure to engineering among science teachers (Bamberger & Cahill, 2013).…”

Section: Introductionmentioning

confidence: 99%

Incorporating an engineering context into science learning: The effects of task context and response structuring on science understanding and investigation behaviors in a simulation

2022

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The interrelationship of science and engineering and the recent inclusion of engineering in K‐12 science standards have promoted the incorporation of engineering design in science classrooms. However, empirical studies on the impacts of engineering design on science learning show mixed findings and indicate that factors such as the complexity of design tasks, a lack of connections between design tasks and the underlying science concepts, and the limited experience with engineering among science teachers can influence learning gains from design activities. One useful approach for addressing these challenges is through the use of technologies such as interactive simulations, which have become increasingly prevalent in STEM education. In the present study, we used a simulation to investigate the effects of task context (science vs. engineering) on students' investigation behaviors and their understanding of science concepts. Furthermore, considering the relative novelty and complexity of an engineering context to many students, we examined how structuring students' responses in the engineering context affects their behaviors and learning. A total of 349 high school students were randomly assigned to one of three conditions: science, structured engineering, and unstructured engineering. In the science condition, students used the simulation to investigate the effects of four variables on the saturation concentration of solutions. Using the same simulation, students in the structured and unstructured engineering conditions were directed to recommend the optimal variable values that meet a set of given constraints and maximize the saturation concentration for a commercial product. The only difference between the two engineering conditions was whether structuring was provided in the response fields presented to students as they entered responses for the target variables. Results suggested that the engineering context stimulated students to engage in more comprehensive investigation behaviors as compared to the science context. In contrast, students in the science condition exhibited more systematic behaviors. However, the increased comprehensiveness of behaviors in the engineering conditions did not translate into significantly greater learning of the science content in these conditions, indicating that students might have focused on the surface features associated with the engineering goal without making deep connections between the two domains. Furthermore, structuring students' responses within an engineering context as used in the current study did not lead to significant differences in investigation behaviors or learning outcomes.

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Argument-Driven Engineering in Middle School Science: An Exploratory Study of Changes in Engineering Identity Over an Academic Year

Cited by 11 publications

References 32 publications

Grade-7 Students’ Negotiation during the Engineering Design Processes Regarding the Status of Their Argumentation Training

Grade-7 Students’ Negotiation during the Engineering Design Processes Regarding the Status of Their Argumentation Training

Children's engineering identities‐in‐practice: An exploration of child–adult interactions in an out‐of‐school context

Incorporating an engineering context into science learning: The effects of task context and response structuring on science understanding and investigation behaviors in a simulation

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