This Innovations in Development project aims to foster the development of STEM identity among a diverse group of middle school students and, in turn, motivate them to pursue in STEM interests and careers. Vegas STEM Lab, led by a team of investigators from the University of Nevada, Las Vegas, will employ a mix of online and on-site activities to introduce students to engineering methods in the context of the entertainment and hospitality (E&H) industry that is the lifeblood of Las Vegas. Investigators will collaborate with local resorts, multimedia designers, and arts institutions to offer field experiences for students to interview, interact with, and learn from local experts. The Lab will help youth overcome prevailing beliefs of STEM as boring and difficult, boost their confidence as STEM-capable individuals, and expose them to the exciting STEM careers available in their hometown. UNLV engineering undergrads will serve as near-peer mentors to the middle school students, guiding them through Lab activities and acting as role models. Investigators will measure student learning and engagement over the course of the Vegas STEM Lab experience with the aim of understanding how the Lab model—with its rich set of activities and interpersonal interactions set in the local E&H industry—can cultivate STEM identity development and encourage students to pursue STEM pathways. Despite the project’s hyperlocal focus on the Las Vegas community, if successful, other cities and towns may learn from and adapt the Lab model for use in their youth development programs.
Vegas STEM Lab will provide online materials for students’ STEM learning during the academic year followed by on-site visits and hands-on project development during a three-week summer experience. The Lab will run for three years with cohorts of 40 students each (N=120) with the aim of iteratively improving its activities and outcomes from year to year. The local school district will help recruit middle school students who have demonstrated low interest in STEM to participate in the Lab, ensuring that participants reflect the demographic makeup of the Las Vegas community in terms of race and ethnicity, socio-economic status, and gender. Summer activities will take students behind the scenes of the city’s major E&H venues; investigate the workings of large-scale displays, light shows, and “smart hospitality” systems; and then build their own smaller scale engineering projects. Investigators will employ the Dynamic Systems Model of Role Identity (DSMRI) framework to study how intentionally designed Lab experiences shape students’ understanding of themselves, their future aspirations, and their grasp of the scientific enterprise. Summer activities will be integrated into the online learning platform at the end of each year of Vegas STEM Lab, and in the final year of the project, workshops will train local educators to use the platform in either formal or informal learning settings. Materials and research findings produced through this work will be disseminated to middle school teachers and afterschool care providers, and shared with researchers through academic publications and conferences.
This Innovations in Development project is funded by the Advancing Informal STEM Learning (AISL) program.
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TEAM MEMBERS:
Emma RegentovaVenkatesan MuthukumarJonathan HilpertSi Jung Kim
This project will scale up fully virtual or face-to-face STEM professional development to afterschool educators in both urban and rural settings. Given that many afterschool educators have little or no background in STEM education, there is demand for professional development that is effective, inexpensive, and accessible. This project will build national capacity in STEM education by developing the STEM skills of over 1,500 educators across multiple states and will ultimately impact over 31,000 under-represented youth in these areas. The project will also deliver robust materials through a free open-source mechanism, for use by educators anywhere and anytime. The project will broaden participation in STEM by engaging community educators in the rural parts of the nation, a critically under-represented group in STEM. It will also reach educators from low-income urban communities across three states and seven cities, targeted through strategic networks and partnerships, including organizations such as the YMCA, 4-H, and the National Afterschool Association.
This collaborative project is scaling the ACRES model (Afterschool Coaching for Reflective Educators in STEM). The model humanizes the virtual experience, making it social and engaging, and allows educators to learn, share, and practice essential STEM facilitation skills with a focus on making STEM relevant and introducing STEM careers to youth. In addition to enhancing the professional STEM skills of rural and urban educators, the project will create a national cohort of coaches with deep expertise in (i) converting in-person activities for youth into a highly engaging, choice-rich online format, (ii) engaging isolated informal educators in supportive professional learning communities, and (iii) coaching foundational research-based STEM facilitation skills that ensure these activities are pedagogically sound. A key part of this broad implementation project involves studying how to integrate an effective professional development program into afterschool organizations, including the ways afterschool programs adapt the materials to be culturally responsive to their local communities. The researchers will also study factors contributing to the longer-term sustainability of the program. The research will use surveys, interviews, direct observations, and case studies of participants to provide the field with valuable insights into scaling a program in the afterschool world.
This project is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for extending access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants.
This project investigates long-term human-robot interaction outside of controlled laboratory settings to better understand how the introduction of robots and the development of socially-aware behaviors work to transform the spaces of everyday life, including how spaces are planned and managed, used, and experienced. Focusing on tour-guiding robots in two museums, the research will produce nuanced insights into the challenges and opportunities that arise as social robots are integrated into new spaces to better inform future design, planning, and decision-making. It brings together researchers from human geography, robotics, and art to think beyond disciplinary boundaries about the possible futures of human-robot co-existence, sociality, and collaboration. Broader impacts of the project will include increased accessibility and engagement at two partner museums, interdisciplinary research opportunities for both undergraduate and graduate students, a short video series about the current state of robotic technology to be offered as a free educational resource, and public art exhibitions reflecting on human-robot interactions. This project will be of interest to scholars of Science and Technology Studies, Human Robotics Interaction (HRI), and human geography as well as museum administrators, educators and the general public.
This interdisciplinary project brings together Science and Technology Studies, Human Robotics Interaction (HRI), and human geography to explore the production of social space through emerging forms of HRI. The project broadly asks: How does the deployment of social robots influence the production of social space—including the functions, meanings, practices, and experiences of particular spaces? The project is based on long-term ethnographic observation of the development and deployment of tour-guiding robots in an art museum and an earth science museum. A social roboticist will develop a socially-aware navigation system to add nuance to the robots’ socio-spatial behavior. A digital artist will produce digital representations of the interactions that take place in the museum, using the robot’s own sensor data and other forms of motion capture. A human geographer will conduct interviews with museum visitors and staff as well as ethnographic observation of the tour-guiding robots and of the roboticists as they develop the navigation system. They will produce an ethnographic analysis of the robots’ roles in the organization of the museums, everyday practices of museum staff and visitors, and the differential experiences of the museum space. The intellectual merits of the project consist of contributions at the intersections of STS, robotics, and human geography examining the value of ethnographic research for HRI, the development of socially-aware navigation systems, the value of a socio-spatial analytic for understanding emerging forms of robotics, and the role of robots within evolving digital geographies.
This project is jointly funded by the Science and Technology Studies program in SBE and Advancing Informal STEM Learning (AISL) Program in EHR.
This Innovations in Development project is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to (a) advance new approaches to and evidence-based understanding of the design and development of STEM learning in informal environments; (b) provide multiple pathways for broadening access to and engagement in STEM learning experiences; (c) advance innovative research on and assessment of STEM learning in informal environments; and (d) engage the public of all ages in learning STEM in informal environments.
Increasing greater diversity, equity, and inclusion in science not only presents a social justice goal, but is also vital to the financial and social success of the nation. The stereotype of the older white male scientist has obscured the contributions of women and people of color. This project seeks to remedy these perceptions which are barriers to entry into STEM fields. The project will create a large-scale hub for STEM themed video content on YouTube and other social media platforms, featuring 100+ original STEM videos produced by PBS partners. This hub and accompanying research seeks to identify the characteristics of online STEM content that attract (or fail to attract) underrepresented groups, specifically Black and Hispanic communities as well as women of all races. The objectives of this project are to 1) provide a unified online science-themed hub, PBS Terra, on YouTube and other platforms for hosting, sharing, and distributing digital STEM series from diverse producers from across the PBS system; 2) conduct surveys and focus groups to examine and understand the needs and expectations of women, Black and Hispanic communities and their consumption of STEM video content online and 3) test hypotheses about the communicative strategies of STEM videos that feature Black and Hispanic female scientists. Project collaborators include PBS, researchers at the University of Utah and the University of Georgia, and consultants and advisors with expertise in broadening participation and inclusion in STEM.
Little is known about how or why adult Americans seek science content on YouTube, especially the motivations of adults from underrepresented minorities and females. The key research questions in this project are: 1) Why do Black and Hispanic audiences and women of all races seek science video content online? 2) How does showing Black and Hispanic female scientists in science video content on YouTube impact viewers’ identification with and sense of belonging in STEM? 3) How does the use of humor by Black and Hispanic scientists in YouTube science content affect viewers’ perceptions of the communicator and their engagement with STEM content? 4) How does the appearance and manner of dress of Black and Hispanic scientists in YouTube science content affect viewers’ perceptions in the aforementioned areas? A nationally representative baseline survey will be conducted. A probability sample of 2000 respondents will be obtained including oversampling of Black and Hispanic audiences. To complement findings from the survey, focus groups will be conducted in eight different regions of the country to learn why these targeted audiences do or do not seek science content on YouTube and what motivates them to share the content with their social media network. In addition, an experiment embedded in an online survey will test the hypothesis that greater on-screen representation of women and scientists of color will broaden existing perceptions about scientists. The experiment will consist of a 3 (scientist’s race: Black/Hispanic/White) × 2 (science issue: controversial/non-controversial) × 2 (style: casual/professional) between-subjects design. Survey participants will be randomly assigned to the experimental conditions. These factors (science issue and host appearance) can be altered by content producers to better reach and engage the targeted audiences. The project not only investigates theoretical questions at the intersection of STEM stereotypes and race, but findings related to these experimental conditions will offer practical insight into strategies that can be used by science communication practitioners.
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TEAM MEMBERS:
Adam DylewskiSara YeoMichael Cacciatore
This Innovations in Development project is funded by the Advancing Informal STEM Learning program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants.
Quantum information science (QIS) is an emergent cross-disciplinary field at the interface of physics, computer science, materials science, and engineering. Yet, there are few educational programs that encourage young people to explore QIS and understand its applications and societal benefits. Such programs are critical for supporting the growth of a quantum-ready workforce. Building intuition is a foundational first step but this is challenging because quantum effects are neither visible to the naked eye, nor experienced in everyday life. This project will create a suite of accessible, engaging digital games for middle schoolers, and study their effectiveness in cultivating intuition around QIS. Relating QIS concepts to common game mechanics is designed to increase students’ confidence in their QIS knowledge, reduce their fear of tackling such a subject, and consider pursuing a career in this field or another STEM area. The game-driven design appeals to a broad population beyond the age groups studied. Moreover, the deliverables will be freely available online, which allows anyone with a phone or computer and internet access a way to learn about QIS in an engaging, play-based environment. The program will partner with teacher organizations and other community groups to share the games, maximizing the project’s impact.
The project is guided by the QIS Key Concepts developed in 2020, as well as research and best practices on gamification of learning. The games will be designed for 6th-8th grade students in an informal setting, focusing on the concepts of probability, superposition, and role of measurement. A game world titled "Quander" will include videos that explicitly tie game experiences to QIS concepts and applications. The project will evaluate students' understanding after playing the games and watching the videos, how they engage with aspects of the games, and how the game impacted their interest in QIS. The project data will advance understanding of how to facilitate QIS informal learning experiences in ways that engage young audiences in QIS and similar abstract emerging areas of technology where current research is scant. This project represents one of the first efforts to teach QIS concepts in ways that connect directly to young learners’ play-based experiences. Data gathered from the project will help future program designers understand the ability of young learners to reason about QIS concepts such as measurement, superposition and probabilities in game contexts, providing insights to the ages at which students are ready for more technical content.
This award is funded in whole or in part under the American Rescue Plan Act of 2021 (Public Law 117-2).
Math is everywhere in the world, but youth may see math as disconnected from their everyday experiences and wonder how math is relevant to their lives. There is evidence that informal math done by children is highly effective, involving efficiency, flexibility, and socializing. Yet, more is needed to understand how educators can support math engagement outside of school, and the role these out-of-school experiences can play relative to the classroom and lifelong STEM learning. This Innovations and Development Project seeks to conduct research on a location-based mobile app for informal mathematics learning. This research takes place at 9 informal learning sites and involves iteratively designing an app in which learners can view and contribute to an interactive map of math walk “stops” at these sites. Learners will be able to select locations and watch short videos or view pictures with text that describe how mathematical principles are present in their surroundings. For example, learners could use the app to discover how a painting by a local Latino artist uses ratio and scale, or how a ramp in downtown was designed with a specific slope to accommodate wheelchairs. Research studies will examine the affordances of augmented reality (AR) overlays where learners can hold up the camera of their mobile device, and see mathematical representations (e.g., lines, squares) layered over real-world objects in their camera feed. Research studies will also examine the impact of having learners create their own math walk stops at local informal learning sites, uploading pictures, descriptions, and linking audio they narrate, where they make observations about how math appears in their surroundings and pose interesting questions about STEM ideas and connections they wonder about.
This project draws on research on informal math learning, problem-posing, and culturally-sustaining pedagogies to conduct cycles of participatory design-based research on technology-supported math walks. The research questions are: How does posing mathematical scenarios in community-imbedded math walks impact learners’ attitudes about mathematics? How can experiencing AR overlays on real world objects highlight mathematical principles and allow learners to see math in the world around them? How can learners and informal educators be engaged as disseminators of content they create and as reviewers of mathematical content created by others? To answer these questions, five studies will be conducted where learners create math walk stops: without technology (Study 1), with a prototype version of the app (Study 2), and with or without AR overlays (Study 3). Studies will also compare children's experiences receiving math walk stops vs. creating their own stops (Study 4) and explore learners reviewing math walk stops made by their peers (Study 5). Using a community ethnography approach with qualitative and quantitative process data of how youth engage with the app and with each other, the project will determine how the development of math interest can be facilitated, how learner-driven problem generation can be scaffolded, and under what circumstances app-based math walks are most effective. The results will contribute to research on the development of interest, problem-posing, informal mathematics learning, and digital supports for STEM learning such as AR. This project will promote innovation and have strategic impact through a digital infrastructure that could be scaled up to support STEM walks anywhere in the world, while also building a local STEM learning ecosystem among informal learning sites focused on informal mathematics. This project is a partnership between Southern Methodist University, a nonprofit, talkSTEM that facilitates the creation of community math walks, and 9 informal learning providers. The project will directly serve approximately 500 grades 4-8 learners and 30-60 informal educators. The project will build capacity at 9 informal learning sites, which serve hundreds of thousands of students per year in their programming.
This Innovations in Development project is supported by the Advancing Informal STEM Learning (AISL) program, which seeks to (a) advance new approaches to and evidence-based understanding of the design and development of STEM learning in informal environments; (b) provide multiple pathways for broadening access to and engagement in STEM learning experiences; (c) advance innovative research on and assessment of STEM learning in informal environments; and (d) engage the public of all ages in learning STEM in informal environments.
This Pilot and Feasibility study will build foundational knowledge about basic aspects of STEM webcams in the United States (US) from the perspectives of both practitioners and viewers. Thousands of webcams available to the public are operated by STEM organizations, such as zoos, museums, and government agencies. Learning theory suggests that STEM webcams, especially those with accompanying interpretive tools, have the potential to offer rich informal learning opportunities. However, yet no research has quantified any aspect (cognitive, behavioral, or emotional) of viewer outcomes. This study will be the first to develop baseline data regarding cognitive, behavioral, and emotional aspects of perceived viewer experience. Project activities include:
An inventory of STEM webcams that exist in the US, the STEM disciplines they represent, learning and engagement tools they employ, the number of viewers they reach, and the resources required for their operation
A survey of webcam operators, their STEM education goals, implementation strategies, and evaluation results; and
Surveys and interviews gathering data on viewers demographics and potential increase in curiosity, interest, knowledge, and behavior toward the STEM subject. This research will provide foundational knowledge for the STEM-education and research community that quantifies and describes many facets of the population of STEM webcams in the inventory.
Research activities will take place in three distinct phases, with Phase 1 laying the groundwork for Phases 2 and 3. Phase 1: The project team will conduct a systematic internet search for all identifiable STEM related webcams. Phase 2 (operator-focused): An online survey of practitioners of webcams operated by US-based STEM organizations will be conducted using Qualtrics software. Likert scales will be used. Various hypotheses will be tested regarding webcam program objectives, operations, and evaluations from the perspective of program operators or practitioners. Phase 3 (viewer-focused): Surveys and interviews with likely viewers of STEM webcams. Using the webcam inventory built in Phase 1, the team will collaborate with 20 informal STEM institutions that agree to survey their constituents to test hypotheses regarding webcam viewing practices, such as why and how viewers watch, and perceived outcomes of viewing, such as perceived influence on their interest, attitudes, knowledge, or behavior. The findings from this study will be widely shared with informal STEM institutions and webcam operators. It will provide foundational data for future experimental studies.
This collaborative research project between KQED, a public media organization serving the San Francisco Bay Area, Texas Tech University and Rockman et al conducted research to study how best to provide effective COVID-19 science news and social media content for young adult audiences.
To start the work, four “Knowledge Gap” studies – Twitter Misinformation, Mask Wearing Messaging, Germ Knowledge and Conceptual Mapping – as well as social media testing were conducted to address our first research question: How could COVID-19 coverage be designed to best inform, engage and educate millennials
KQED and Texas Tech advanced professional knowledge in the journalism and science communication fields around crisis reporting and building a media practitioner and academic researcher collaboration for audience research through a study conducted by Scott Burg of Rockman et al. Rockman gathered data between October 2020 - May 2021, interviewed KQED Science staff and participated in virtual observations of KQED project and related staff meetings to answer our second research question:
Can KQED develop a more efficient process of disaster reporting that responds to both constantly updating
This collaborative research project between KQED, a public media organization serving the San Francisco Bay Area, Texas Tech University and Rockman et al conducted research to study how best to provide effective COVID-19 science news and social media content for young adult audiences.
To start the work, four “Knowledge Gap” studies – Twitter Misinformation, Mask Wearing Messaging, Germ Knowledge (A&B) and Conceptual Mapping – as well as social media testing were conducted to address our research question: How could COVID-19 coverage be designed to best inform, engage and educate millennials
This collaborative research project between KQED, a public media organization serving the San Francisco Bay Area, Texas Tech University and Rockman et al conducted research to study how best to provide effective COVID-19 science news and social media content for young adult audiences.
To start the work, four “Knowledge Gap” studies – Twitter Misinformation, Mask Wearing Messaging, Germ Knowledge (A&B) and Conceptual Mapping – as well as social media testing were conducted to address our research question: How could COVID-19 coverage be designed to best inform, engage and educate millennials
This collaborative research project between KQED, a public media organization serving the San Francisco Bay Area, Texas Tech University and Rockman et al conducted research to study how best to provide effective COVID-19 science news and social media content for young adult audiences.
To start the work, four “Knowledge Gap” studies – Twitter Misinformation, Mask Wearing Messaging, Germ Knowledge and Conceptual Mapping – as well as social media testing were conducted to address our research question: How could COVID-19 coverage be designed to best inform, engage and educate millennials and