Barrett, The Honors College Thesis/Creative Project Collection
Barrett, The Honors College at Arizona State University proudly showcases the work of undergraduate honors students by sharing this collection exclusively with the ASU community.
Barrett accepts high performing, academically engaged undergraduate students and works with them in collaboration with all of the other academic units at Arizona State University. All Barrett students complete a thesis or creative project which is an opportunity to explore an intellectual interest and produce an original piece of scholarly research. The thesis or creative project is supervised and defended in front of a faculty committee. Students are able to engage with professors who are nationally recognized in their fields and committed to working with honors students. Completing a Barrett thesis or creative project is an opportunity for undergraduate honors students to contribute to the ASU academic community in a meaningful way.
Displaying 1 - 10 of 18
Filtering by
- All Subjects: Education
- Creators: The Design School
- Creators: Kashiwagi, Jacob
Description
In response to the modern discussion of secondary education reform, a design is proposed for a decentralized high school composed of hybridized learning centers which respond to a pedagogy of Resource Based Learning and appropriate the Valley Metro Light Rail Line as the site network. In pursuit of symbiotic public/private relationships, the project offers a broad avenue of access to a diverse array of students and resources. The working design ultimately visualizes a radical potential for the classroom of the 21st century.
ContributorsLufkin, Angela Marie (Author) / Horton, Phil (Thesis director) / Hejduk, Renata (Committee member) / Barrett, The Honors College (Contributor) / The Design School (Contributor)
Created2015-05
Description
This century has brought about incredible advancements in technology and academia, changing the workforce and the future leaders that will drive it: students. However, the integration of digital literacy and digital tools in many United States K\u201412 schools is often overlooked. Through "Exploring the Digital World," students, parents, and teachers can follow the creatures of this story-driven program as they learn the importance of digital literacy in the 21st century.
ContributorsRaiton, Joseph Michael (Author) / Fehler, Michelle (Thesis director) / Heywood, William (Committee member) / Barrett, The Honors College (Contributor) / The Design School (Contributor)
Created2015-05
Description
The two authors completed the entirety of their schooling within the United States, from preschool to university. Both authors experienced loss of interest towards their education each successive year and assumed the nature of learning and education was to blame. The two students took a class on the Kashiwagi Information Measurement Theory their second years at Arizona State University and applied the concepts taught in that class to past experiences in the United States education system to determine the cause behind their waning interest in their education. Using KSM principles the authors identified that the environment produced by and ineffectual and inefficient educational system is what resulted in their, and the majority of their peers, growing dissatisfaction in their education. A negative correlation was found between GPA and control. As the control in a students environment increased, their GPA decreased. The data collected in this thesis also supports the conclusions that as a student is exposed to a high stress environment, their GPA and average amount of sleep per night decrease.
ContributorsKulanathan, Shivaan (Co-author) / Westlake, Kyle (Co-author) / Kashiwagi, Dean (Thesis director) / Kashiwagi, Jacob (Committee member) / Gunnoe, Jake (Committee member) / Computer Science and Engineering Program (Contributor) / Chemical Engineering Program (Contributor) / Barrett, The Honors College (Contributor)
Created2016-05
Description
Education is a very sensitive topic when it comes to implementing the right policies. From professionals well-versed in the topic, to the very students who are being taught, feedback for reform is constantly being addressed. Nonetheless, there remains a large gap between the performance of some of the most advanced countries in the world and the United States of America. As it stands today, USA is arguably the most technologically advanced country and the outright leader of the free market. For over a century this nation has been exceeding expectations in nearly every industry known to man and aiding the rest of the world in their endeavors for a higher standard of living. Yet, there seems to be something critically wrong with the way a large majority of the younger generation are growing up. How can a country so respected in the world fall so far behind in what is considered the basics of human education: math and science? The Trends in International Mathematics and Science Study (TIMSS) is a series of assessments taken by countries all around the world to determine the strength of their youth's knowledge. Since its inception in 1995, TIMSS has been conducted every four years with an increasing number of participating countries and students each time. In 1999 U.S. eighth-graders placed #19 in the world for mathematics and #18 for science (Appendix Fig. 1). In the years following, and further detailed in the thesis, the U.S. managed to improve the overall performance by a small margin but still remained a leg behind countries like Singapore, Hong Kong, Japan, Russia, and more. Clearly these countries were doing something right as they consistently managed to rank in the top tier. Over the course of this paper we will observe and analyze why and how Singapore has topped the TIMSS list for both math and science nearly every time it has been administered over the last two decades. What is it that they are teaching their youth that enables them to perform exceptionally above the norm? Why is it that we cannot use their techniques as a guideline to increase the capabilities of our future generations? We look to uncover the teaching methods of what is known as Singapore Math and how it has helped students all over the world. By researching current U.S. schools that have already implemented the system and learning about their success stories, we hope to not only educate but also persuade the local school districts on why integrating Singapore Math into their curriculum will lead to the betterment of the lives of thousands of children and the educational threshold of this great nation.
ContributorsKichloo, Parth (Co-author) / Leverenz, Michael (Co-author) / Kashiwagi, Dean (Thesis director) / Kashiwagi, Jacob (Committee member) / Rivera, Alfredo (Committee member) / Department of Management (Contributor) / Department of Marketing (Contributor) / Department of Finance (Contributor) / Department of Information Systems (Contributor) / Barrett, The Honors College (Contributor)
Created2016-05
Description
The purpose of this creative thesis project is to create the framework of an educational class package based off of a course offered at Arizona State University. The course chosen for this project is an honors course titled Deductive Logic: Leadership and Management Techniques and is taught by Dean Kashiwagi, PhD. The class package is designed to be published over an online platform so students and professors from various institutions can access the material. Currently the platform is in its final stages of development and is slated to go live on July of 2014. The future development of the package will be geared towards facilitating interdisciplinary collaboration between institutions based off of course concepts.
ContributorsGunnoe, Jake Alan (Author) / Kashiwagi, Dean (Thesis director) / Kashiwagi, Jacob (Committee member) / Barrett, The Honors College (Contributor) / Mechanical and Aerospace Engineering Program (Contributor) / Del E. Webb Construction (Contributor)
Created2014-05
Description
An exploration of how architecture can react to American hyper-consumption of clothing products. With the goal to raise public awareness and create systemic, sustainable change in the fashion industry, this project synthesizes each part of manufacturing, including production, consumption, and post consumption, into one local campus. By bringing manufacturing back into the daily rhythms of an urban context and combining a prototypical mix of fashion related programs, ethically minded consumers are formed.
ContributorsMarshall, Jordan (Author) / Murff, Warren (Thesis director) / Smith, Brie (Committee member) / Hejduk, Renata (Committee member) / School of Sustainability (Contributor) / The Design School (Contributor, Contributor) / Barrett, The Honors College (Contributor)
Created2021-05
Description
When we examine the word “dignity” regarding the built environment, we must look at how the building creates a sense of respect and honor. Buildings placed into communities without thoughtful consideration in how they will make occupants feel is undignified design. Design decisions that place the form of a building over its function allows aesthetics to become the primary criteria for judgement. When it comes to well-designed spaces, they should not just be a matter of aesthetics since they can shape our ideas about who we are and what we deserve. We need design that addresses the inhabitants needs, enhancing their overall experience. This is dignified design. We can ensure good design is a fundamental right by understanding the impact that the education system has on architects, and on shaping design to meet people’s needs. In this paper, I will address how a shift in the Architectural Education system could lead to more dignified design
ContributorsWilson, Mckenzi Lucille (Co-author) / N/A, N/A (Co-author) / Spellman, Catherine (Thesis director) / Rico Mesa, Juan Felipe (Committee member) / Valderrama, Ana (Committee member) / School of Sustainable Engineering & Built Envirnmt (Contributor) / The Design School (Contributor) / Barrett, The Honors College (Contributor)
Created2021-05
Description
“STEAM = Science & Technology interpreted through
Engineering & the Arts, all based in Mathematical elements” (STEAM edu, 2015).
“The latest round of international standardized test results showed American students are lagging behind the rest of the developed world not just in math, science and reading, but in problem solving as well. The 2012 Program for International Student Assessment (PISA) test examined 44 countries’ students’ problem-solving abilities — American students landed just above the average, but they still scored below many other developed countries, including Britain, Singapore, Korea, Japan, China and Canada” (Bertram, 2015).
Lack of quality education, busy households, and limited time and money can all be factors of why children are not academically supported. What would it look like if children had access to a tool that helped them catch up if they fall behind? A tool that empowers children to solve academic and real-world world problems will help strengthen different cognitive and behavioral skills as well as create a more personalized educational experience, inside the classroom and out. This tool can be applied to the way we look at our formal academic education to help build new, creative problem solving strategies that are tailored to each student’s preferred ways of learning.
Proposed Research
My research is driven by the following question:
How do we create a tool for students that will help them maneuver busy and over-populated classrooms to help them learn better?
I am interested in studying the ways in which children in the age range of 11-14 play, specifically through video gaming, and using this influence to promote learning. By using children’s gaming interests to inspire education, they will be more inclined to participate in learning activities in the classroom. By exploring and observing how children problem solve in gaming, I will be able to pull techniques and methods from play in order to enhance critical learning. This project will begin in mid-May, and will continue after my thesis defense when I take this project into the workforce and am applying for jobs.
Methods
I will be taking a mixed methods approach to my research by using a combination of:
Qualitative methods: Observational data will be collected in many ways including but not limited to sketches, photography, writing, and film. After gathering base-level observational data I plan to use this, as well as my prototypes from the early phases of my product’s life to create a study to better understand users’ preferences with my product. This will include different colors, ergonomic shapes, part lines, and more to allow for a large range of feedback.
Surveys and interviews: I wish to interview and survey policymakers, educators, students, and other stakeholders invested in education to better understand their needs, in order to ensure that my product is feasible in the eyes of policymakers. It is important that my specific product not only serve as a tool for students, but also for teachers to learn as well. Making this product as something practical and scalable is important in terms of feasibility.
Thematic groups: Observing user groups interacting with my product/project will help me adjust to my general end goals.
Actionable Insights
After gathering data from interviews, surveys, observations, and product feedback, I plan to analyze this data and make sufficient changes to my project in order to better serve the community in which I am trying to benefit. Doing this will help my project be more effective and impactful.
Limitations will depend on rules on photography and interviewing. The timeline of the analysis of the data collected will be similar to the timeline provided for the senior studio class for traditional industrial design students.
Expected Outcomes
The proposed research will strengthen my design skills and expand my knowledge as a design student interested in the user experience, wellbeing, access to arts education, and much more. I will have a final outcome of a physical product that will be used as an initiative to help children studying STEM subjects to find new, creative, and different ways of solving problems.
Timeline
As I will be doing this project in congruency with my senior industrial design studio, my schedule has been roughly predetermined.
April-August
Literature review and preliminary research will be taken care of during this part of my thesis project. I will also be contacting people I would like to see be involved in this project during this time.
August-December
Research
1. Exploration
a. Assign01: Mind map + Visit the world
b. Assign02: Observations + Interviews
2. Making sense of the data + Concepts
a. Assign03: POG + Ideation
b. Assign04: Concept Evaluation + Selection
c. Partner School Determined
3. Concept Direction + Customer Validation + Research Summary
a. Assign05: Hard device and Screen Mock-ups + Customer Feedback
b. Assign06: Mid-term presentation of research + Life-Cycle
Design
1. Form Development + Drivers
a. Assign07: Design Language + Out into the World
b. Assign08: Product Details + Function
c. Wire frames Due
2. Study Models + CAD Model
a. Assign09: Refined 3D Study Model
b. Assign10: CAD Model + Tech Drawings
c. Running Step-Through
3. Design Validation + Refinement
a. Assign11: Persona Check +CMF + Features & Benefits
4. Storyboard Development + Visual Poster
a. Assign12: Storyboard + Life of Product
b. Assign13: Poster + Presentation Outline
c. Assign14: Product Animation
5. Final Presentation
a. Assign15: Process Book
b. Assign16: Public presentation
December-January
This is the time I will use to have my code built out a bit more. I will come back into the next semester with a code that functions in my form that I have decided on.
January-May
This time will be used to run user tests on my product, and make desired changes to it in order to fully iterate and design my concept well and with data-driven desires.
Meetings
I plan to meet with my studio professor, Dosun Shin, once every two weeks to discuss how my project is progressing. My second committee member will be Dean Bacalzo. My committee will be contacted on a monthly basis by way of email with updates on my project’s process. From there I will be able to ask for suggestions and schedule meeting times to further discuss my project.
References
Educational Ecosystems for Societal Transformation
Why STEM? Success Starts With Critical Thinking, Problem-Solving Skills
https://www.wired.com/insights/2014/06/stem-success-starts-critical-thinking-problem-solving-skills/
Unlocking Creativity: Teaching across the Curriculum
How the Founder of All Girls Code Is Shaking Up STEM in the Middle East
https://www.jnj.com/personal-stories/the-road-to-devex-aya-mouallem-discusses-her-stem-program-for-girls
Case Study: A game for conflict-affected youth to learn and grow
https://blogs.unity3d.com/2018/06/13/case-study-a-game-for-conflict-affected-youth-to-learn-and-grow/
Vice Charter School vs Public School
https://www.theatlantic.com/science/archive/2016/10/the-weak-evidence-behind-brain-training-games/502559/
Think brain games make you smarter? Think again, FSU researchers sayhttp:/
ews.fsu.edu
ews/health-medicine/2017/04/17/think-brain-games-make-smarter-think-fsu-researchers-say/
About STEAM Edu
https://steamedu.com/about-us/
Brain Games Don’t Work
http://fortune.com/2017/07/10/brain-games-research-lumosity/
Pip is a portable gaming device that teaches children to codehttps://www.dezeen.com/2017/12/05/pip-portable-gaming-device-teaches-children-coding-technology/
Latest STEM learning kits for kids combine technology and play doughhttps://www.dezeen.com/2017/06/06/stem-learning-kits-kids-combine-technology-play-dough-universe-tech-will-save-us-design/
3 Ways To Design Toys That Boost Kids’ Creativityhttps://www.fastcodesign.com/1669691/3-ways-to-design-toys-that-boost-kids-creativity
Plobot for STEAM
https://www.behance.net/gallery/45476023/Plobot
Global Education Futures Report
http://futuref.org/educationfutures
Xbox Adaptive Controllerhttps://www.xbox.com/en-US/xbox-one/accessories/controllers/xbox-adaptive-controller
2018 US Video Game Market Predictionshttps://www.npd.com/wps/portal
pd/us/blog/2018/2018-us-video-game-market-predictions/
Kids and Violence in the Media
https://www.parenting.com/article/media-violence-children
YouTubers Talk About Their Favorite Games
https://www.youtube.com/watch?v=D3wFuqzzwdk
https://www.ideo.com/case-study/giving-ed-tech-entrepreneurs-a-window-into-the-classroom
https://www.ideo.com/case-study/for-kids-a-new-tactile-way-to-learn-coding
https://www.youtube.com/watch?v=uwskPyYEH2I&feature=youtu.be
https://www.kerbalspaceprogram.com/en/?page_id=11
Engineering & the Arts, all based in Mathematical elements” (STEAM edu, 2015).
“The latest round of international standardized test results showed American students are lagging behind the rest of the developed world not just in math, science and reading, but in problem solving as well. The 2012 Program for International Student Assessment (PISA) test examined 44 countries’ students’ problem-solving abilities — American students landed just above the average, but they still scored below many other developed countries, including Britain, Singapore, Korea, Japan, China and Canada” (Bertram, 2015).
Lack of quality education, busy households, and limited time and money can all be factors of why children are not academically supported. What would it look like if children had access to a tool that helped them catch up if they fall behind? A tool that empowers children to solve academic and real-world world problems will help strengthen different cognitive and behavioral skills as well as create a more personalized educational experience, inside the classroom and out. This tool can be applied to the way we look at our formal academic education to help build new, creative problem solving strategies that are tailored to each student’s preferred ways of learning.
Proposed Research
My research is driven by the following question:
How do we create a tool for students that will help them maneuver busy and over-populated classrooms to help them learn better?
I am interested in studying the ways in which children in the age range of 11-14 play, specifically through video gaming, and using this influence to promote learning. By using children’s gaming interests to inspire education, they will be more inclined to participate in learning activities in the classroom. By exploring and observing how children problem solve in gaming, I will be able to pull techniques and methods from play in order to enhance critical learning. This project will begin in mid-May, and will continue after my thesis defense when I take this project into the workforce and am applying for jobs.
Methods
I will be taking a mixed methods approach to my research by using a combination of:
Qualitative methods: Observational data will be collected in many ways including but not limited to sketches, photography, writing, and film. After gathering base-level observational data I plan to use this, as well as my prototypes from the early phases of my product’s life to create a study to better understand users’ preferences with my product. This will include different colors, ergonomic shapes, part lines, and more to allow for a large range of feedback.
Surveys and interviews: I wish to interview and survey policymakers, educators, students, and other stakeholders invested in education to better understand their needs, in order to ensure that my product is feasible in the eyes of policymakers. It is important that my specific product not only serve as a tool for students, but also for teachers to learn as well. Making this product as something practical and scalable is important in terms of feasibility.
Thematic groups: Observing user groups interacting with my product/project will help me adjust to my general end goals.
Actionable Insights
After gathering data from interviews, surveys, observations, and product feedback, I plan to analyze this data and make sufficient changes to my project in order to better serve the community in which I am trying to benefit. Doing this will help my project be more effective and impactful.
Limitations will depend on rules on photography and interviewing. The timeline of the analysis of the data collected will be similar to the timeline provided for the senior studio class for traditional industrial design students.
Expected Outcomes
The proposed research will strengthen my design skills and expand my knowledge as a design student interested in the user experience, wellbeing, access to arts education, and much more. I will have a final outcome of a physical product that will be used as an initiative to help children studying STEM subjects to find new, creative, and different ways of solving problems.
Timeline
As I will be doing this project in congruency with my senior industrial design studio, my schedule has been roughly predetermined.
April-August
Literature review and preliminary research will be taken care of during this part of my thesis project. I will also be contacting people I would like to see be involved in this project during this time.
August-December
Research
1. Exploration
a. Assign01: Mind map + Visit the world
b. Assign02: Observations + Interviews
2. Making sense of the data + Concepts
a. Assign03: POG + Ideation
b. Assign04: Concept Evaluation + Selection
c. Partner School Determined
3. Concept Direction + Customer Validation + Research Summary
a. Assign05: Hard device and Screen Mock-ups + Customer Feedback
b. Assign06: Mid-term presentation of research + Life-Cycle
Design
1. Form Development + Drivers
a. Assign07: Design Language + Out into the World
b. Assign08: Product Details + Function
c. Wire frames Due
2. Study Models + CAD Model
a. Assign09: Refined 3D Study Model
b. Assign10: CAD Model + Tech Drawings
c. Running Step-Through
3. Design Validation + Refinement
a. Assign11: Persona Check +CMF + Features & Benefits
4. Storyboard Development + Visual Poster
a. Assign12: Storyboard + Life of Product
b. Assign13: Poster + Presentation Outline
c. Assign14: Product Animation
5. Final Presentation
a. Assign15: Process Book
b. Assign16: Public presentation
December-January
This is the time I will use to have my code built out a bit more. I will come back into the next semester with a code that functions in my form that I have decided on.
January-May
This time will be used to run user tests on my product, and make desired changes to it in order to fully iterate and design my concept well and with data-driven desires.
Meetings
I plan to meet with my studio professor, Dosun Shin, once every two weeks to discuss how my project is progressing. My second committee member will be Dean Bacalzo. My committee will be contacted on a monthly basis by way of email with updates on my project’s process. From there I will be able to ask for suggestions and schedule meeting times to further discuss my project.
References
Educational Ecosystems for Societal Transformation
Why STEM? Success Starts With Critical Thinking, Problem-Solving Skills
https://www.wired.com/insights/2014/06/stem-success-starts-critical-thinking-problem-solving-skills/
Unlocking Creativity: Teaching across the Curriculum
How the Founder of All Girls Code Is Shaking Up STEM in the Middle East
https://www.jnj.com/personal-stories/the-road-to-devex-aya-mouallem-discusses-her-stem-program-for-girls
Case Study: A game for conflict-affected youth to learn and grow
https://blogs.unity3d.com/2018/06/13/case-study-a-game-for-conflict-affected-youth-to-learn-and-grow/
Vice Charter School vs Public School
https://www.theatlantic.com/science/archive/2016/10/the-weak-evidence-behind-brain-training-games/502559/
Think brain games make you smarter? Think again, FSU researchers sayhttp:/
ews.fsu.edu
ews/health-medicine/2017/04/17/think-brain-games-make-smarter-think-fsu-researchers-say/
About STEAM Edu
https://steamedu.com/about-us/
Brain Games Don’t Work
http://fortune.com/2017/07/10/brain-games-research-lumosity/
Pip is a portable gaming device that teaches children to codehttps://www.dezeen.com/2017/12/05/pip-portable-gaming-device-teaches-children-coding-technology/
Latest STEM learning kits for kids combine technology and play doughhttps://www.dezeen.com/2017/06/06/stem-learning-kits-kids-combine-technology-play-dough-universe-tech-will-save-us-design/
3 Ways To Design Toys That Boost Kids’ Creativityhttps://www.fastcodesign.com/1669691/3-ways-to-design-toys-that-boost-kids-creativity
Plobot for STEAM
https://www.behance.net/gallery/45476023/Plobot
Global Education Futures Report
http://futuref.org/educationfutures
Xbox Adaptive Controllerhttps://www.xbox.com/en-US/xbox-one/accessories/controllers/xbox-adaptive-controller
2018 US Video Game Market Predictionshttps://www.npd.com/wps/portal
pd/us/blog/2018/2018-us-video-game-market-predictions/
Kids and Violence in the Media
https://www.parenting.com/article/media-violence-children
YouTubers Talk About Their Favorite Games
https://www.youtube.com/watch?v=D3wFuqzzwdk
https://www.ideo.com/case-study/giving-ed-tech-entrepreneurs-a-window-into-the-classroom
https://www.ideo.com/case-study/for-kids-a-new-tactile-way-to-learn-coding
https://www.youtube.com/watch?v=uwskPyYEH2I&feature=youtu.be
https://www.kerbalspaceprogram.com/en/?page_id=11
ContributorsStrasser, Grace Bailey (Author) / Wilkymacky, Abby (Thesis director) / Shin, Dosun (Committee member) / School of Sustainability (Contributor) / The Design School (Contributor) / Barrett, The Honors College (Contributor)
Created2019-05
Description
Traditional educational infrastructures and their corresponding architectures have degenerated to work in opposition to today's scholastic objectives. In consideration of the necessity of formal education and academic success in modern society, a re-imagination of the ideal educational model and its architectural equivalent is long overdue. Fortunately, the constituents of a successful instructional method exist just outside our windows. This thesis, completed in conjunction with the ADE422 architectural studio, seeks to identify the qualities of a new educational paradigm and its architectural manifestation through an exploration of nature and biophilic design. Architectural Studio IV was challenged to develop a new academic model and corresponding architectural integration for the Herberger Young Scholars Academy, an educational institution for exceptionally gifted junior high and high school students, located on the West Campus of Arizona State University. A commencing investigation of pre-established educational methods and practices evaluated compulsory academic values, concepts, theories, and principles. External examination of scientific studies and literature regarding the functions of nature within a scholastic setting assisted in the process of developing a novel educational paradigm. A study of game play and its relation to the learning process also proved integral to the development of a new archetype. A hypothesis was developed, asserting that a nature-centric educational model was ideal. Architectural case studies were assessed to determine applicable qualities for a new nature-architecture integration. An architectural manifestation was tested within the program of the Herberger Young Scholars Academy and through the ideal functions of nature within an academic context.
ContributorsTate, Caroline Elizabeth (Author) / Underwood, Max (Thesis director) / Hejduk, Renata (Committee member) / De Jarnett, Mitchell (Committee member) / The Design School (Contributor) / W. P. Carey School of Business (Contributor) / School of Sustainability (Contributor) / Barrett, The Honors College (Contributor)
Created2016-05
Description
In today's world, critical thinking and using a systems approach to problem solving are skills that are far too rare. In the age of information, the truth has become muddled by "fake news" and a constant barrage of exaggerations or blatant falsehoods. Without critical thinking skills, "many members of our society do not command the scientific literacy necessary to address important societal issues and concerns" (NCES 2012, p.11). Additionally, far too many people are incapable of thinking long term and understanding how their actions affect others. Because of this shortsightedness our world is facing one of its biggest ecological crises \u2014 global warming confounded by overpopulation and overconsumption. Now, more than ever, it is critical "for our young people to have a basic understanding of the relevant scientific ideas, technologies and ethical issues and powers of reasoning, to be prepared to face these issues" (Harlen et al., 2015). I believe that investigating innovative ways to teach ecology could be an important step to accomplishing this. Learning to think like a scientist forces people to rely on facts, follow similar protocols to deduce these facts, and be able to think critically about misleading events. More specifically, ecology education will allow people to develop those skills while also learning about team work, open-mindedness, and their environment. Ecology is defined as "the branch of biology that deals with the relations of organisms to one another and to their physical surroundings" (Dictionary.com, 2018). It is clear that this subcategory of science could act as a powerful introduction to the scientific world and how we relate to it. Its introduction at a young age has the potential to create a generation of conscientious and curious lifelong learners. In an attempt to support effective ways to teach ecology, I developed an educational unit and applied it in different educational contexts. My target audience was elementary aged students and I tested this unit with children in Phoenix Metropolitan Area afterschool programs. I taught core concepts of ecology \u2014 the water cycle, the sun's energy, plants and photosynthesis, and food webs \u2014in a sequence of lesson plans that build upon each other. Finally, I determined the appropriate age group and setting for these lesson plans through research and in-class observations. In this document, I explain the process I went through in developing my lesson plans, why I felt compelled to make them, and my experiences in implementing them.
ContributorsVotaw, Alexandra Lindsay (Author) / Larson, Kelli (Thesis director) / Herrmann, Lisa (Committee member) / York, Abigail (Committee member) / School of Art (Contributor) / The Design School (Contributor) / School of Life Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05