Preservice Elementary Teachers Conceptions and Self-Efficacy for Integrated STEM
Abstract
:1. Introduction
2. Theoretical Underpinnings and Background Literature
2.1. Self-Efficacy in Teacher Preparation
2.2. STEM Education
2.3. Preservice STEM Education
3. Focus of This Study and Research Questions
- How does preservice elementary teachers’ integrated STEM teaching self-efficacy change after participating in the STEM semester?
- How do preservice elementary teachers conceptualize integrated STEM instruction at the beginning and end of the STEM semester?
4. Methodology
4.1. Research Design
4.2. Research Context
4.3. STEM-Themed Pathways
4.3.1. Sustainability
4.3.2. Robotics and Coding
4.3.3. Participants
4.4. Data Collection
4.5. Quantitative Data Sources
4.6. Qualitative Data Sources
4.7. Data Analysis
4.7.1. Quantitative Data Analysis
4.7.2. Qualitative Data Analysis
4.7.3. Findings
4.8. Changes in Self-Efficacy for Integrated STEM
4.9. Qualitative Themes
4.10. Beginning of the Semester Themes
4.10.1. Low Affinity for STEM
I would say that my personal definition of science is boring, confusing, difficult, and time-consuming. Since I have not had very positive experiences with science in the past years, I would say this has definitely affected my definition of science…I think that when teaching STEM, it is easy for students to give up because the material is too hard or confusing for them. This causes them to lose confidence in their STEM abilities and feel as though math, science, or technology is too hard.(IL, Participant 12)
4.10.2. STEM Stereotypes
As a future science teacher, I want to break the stigma. Anyone can be a part of STEM, especially if you work hard and put your mind to it. When teaching elementary students about STEM, I want them to know that if they enjoy STEM, they are good enough to go for it. STEM is for anybody, and I really want to stress that to kids. It’s damaging to say that STEM isn’t for everyone to impressionable kids.(IL, Participant 4)
4.10.3. STEM Is New and Complicated
When it comes to teaching STEM in grade school, I think it is a relatively “new” concept. I know elementary students have been learning math and science for ages and that they themselves are not new, but the idea that technology, math, and science are now an integral part of succeeding in the world after school is newer in schools.(IL, Participant 12)
4.11. End of the Semester: Themes
4.11.1. Positive Attitudes about STEM
“First, I thought STEM was just science, technology, engineering, and math as a separate but as the semester went on that changed quickly. STEM is a curriculum based on an interdisciplinary and applied approach rather than teaching the four disciplines as separate and discrete subjects. STEM integrates them into one cohesive learning model based on real-world applications, so they are intertwined, they aren’t their own separate”.(GR, Participant 8)
4.11.2. Increased Confidence in Planning and Designing Integrated STEM Lessons
Before this semester, STEM classes were individual and lived on their own, separately. Math was math, and science was science, and they just stayed that way. This semester really taught me that these classes can join forces to create a really successful lesson. I feel confident in my ability to integrate all of these subjects into one lesson effectively, more so than before”.(GR, Participant 13)
4.11.3. Importance of Integrated STEM for ALL Learners
Considering I am a woman and women make up the minority in STEM, it is important to emphasize, even for girls who doubt due to societal norms, STEM isn’t a scary thought that should turn you away but a fun challenge, easy to implement into a classroom.(Participant 4)
5. Discussions
6. Limitations
7. Conclusions and Implications
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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Science Methods | Mathematics Methods | ILT Methods | |
---|---|---|---|
Course Description | Role, trends, content, and materials of science in childhood education. Development of science experiences for use with children. | Scope, content, and organization of the mathematics curriculum; development, use, and sources of instructional materials; teaching procedures. | Development of strategies for using technology to support K-12 classroom instruction. Internet resources, applications software, and authoring programs. |
Focus Topics | 5E lesson planning [7], Engineering Design Process [78], Science and engineering practices and sense-making [79]. | Principles and teaching practices for teaching mathematics aligned with Principles to Actions [80]. | Overview of technology education standards [81,82]. Introduction to online math and science tools and applications, educational robotics, and AI, and their potential uses in elementary education. |
STEM Identity Letters | Integrated STEM Project | STEM Growth Reflections | |
---|---|---|---|
Time of the Semester | Beginning of the semester (first week) | Mid-semester, developed over a course of four classes in each methods course (a total of 12 classes), spread over a month | End of the semester (introduced two weeks before the conclusion of the semester) |
Format and Structure | Individual story writing, online submission to the course site | Poster/slide making, poster/slide presentation, creating a prototype/model, collaborative group project (3–4 PSTs per group) | Individual story writing, offline, pictures of artifacts to show growth, online submission to the course site |
Connection to Integrated STEM Self-efficacy | Analyze, reflect, and write about identity as a learner of science and mathematics (and experiences with engineering and technology), perceptions about STEM teaching | Work in collaborative teams, engage in engineering design to create a solution to the problem, use scientific content and mathematical and technological tools to build prototypes and testing solutions, and enhance creativity by making a poster. | Builds on reflective practice, reflect on perceptions about integrated STEM teaching and draws on examples from the three methods coursework to illustrate their learning. |
Age (Years) | No. of Science Courses Taken in High School | Gender | Year (in 4-Year Program) | Race |
---|---|---|---|---|
19–21 (n = 109) | Two (n = 5) | Male (n = 9) | Year 2 (n = 45), | African American/Black (n = 2) |
22–25 (n = 18) | Three (n = 38) | Female (n = 120) | Year 3 (n = 83) | White/Caucasian (n = 112) |
>25 (n = 5) | Four (n = 57) | Prefer to not say (3) | Year 4 (n = 4) | Asian (n = 4) |
Five (n = 19) | Hispanic (n = 11) | |||
Six (n = 11) | Prefer to not say (3) | |||
Eight (n = 2) |
Meaningful Unit (Sample Excerpt) | Initial Code | Category/ Subcategory | Themes |
---|---|---|---|
At the beginning of the semester | |||
I do not recall much about science in the classroom. | No recollection of science | Negative dispositions | Low affinity for STEM |
I think about how STEM is only for guys or how rare it is to see a woman in STEM. | Only guys Scarcity of woman in STEM | Gender differences in STEM | STEM stereotypes |
The idea of STEM scares me. I never took a STEM class in my high school because I thought it was complicated. | Scary, complicated, no STEM class in high school | STEM seems scary Lack of prior knowledge in STEM | STEM is new and complicated |
At the end of the semester | |||
I learned so much and have realized that I also have so much more to learn. So, I am now open-minded to new technology, and new ways of teaching science. | Open-minded, new ways to teach science, more to learn—technology | Positive change after the semester | Positive attitudes about STEM |
I wasn’t so sure about how I would incorporate so many different components into one lesson. After completing my integrated STEM lesson plan, I realized how easy it can be. | Easy, Incorporate STEM components | More confidence for STEM integration | Increased confidence in planning and designing integrated STEM lessons |
STEM is critical for all students, not just left-brain individuals and males | Critical for all students | Importance of STEM for students | Importance of Integrated STEM for all K-5 learners |
Variable | Mean | SD | Min | Max | Skewness | Kurtosis |
---|---|---|---|---|---|---|
SETIS | ||||||
Pre-Survey | 88.77 | 13.96 | 48 | 120 | −0.39 | 0.38 |
Post-Survey | 105.12 | 10.14 | 82 | 120 | −0.22 | −1.01 |
Mean | Std. Deviation | Std. Error Mean | t | df | Sig. (2-Tailed) | |
---|---|---|---|---|---|---|
Pair 1 | ||||||
Pre-Survey—Post-Survey | 16.350 | 16.899 | 1.470 | 11.2 * | 131 | 0.000 |
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Menon, D.; Shorman, D.A.A.; Cox, D.; Thomas, A. Preservice Elementary Teachers Conceptions and Self-Efficacy for Integrated STEM. Educ. Sci. 2023, 13, 529. https://doi.org/10.3390/educsci13050529
Menon D, Shorman DAA, Cox D, Thomas A. Preservice Elementary Teachers Conceptions and Self-Efficacy for Integrated STEM. Education Sciences. 2023; 13(5):529. https://doi.org/10.3390/educsci13050529
Chicago/Turabian StyleMenon, Deepika, Deef A. A. Shorman, Derek Cox, and Amanda Thomas. 2023. "Preservice Elementary Teachers Conceptions and Self-Efficacy for Integrated STEM" Education Sciences 13, no. 5: 529. https://doi.org/10.3390/educsci13050529
APA StyleMenon, D., Shorman, D. A. A., Cox, D., & Thomas, A. (2023). Preservice Elementary Teachers Conceptions and Self-Efficacy for Integrated STEM. Education Sciences, 13(5), 529. https://doi.org/10.3390/educsci13050529