This report contains findings from a summative evaluation study of a set of four featured elements that comprise the new Nature Research Center of the North Carolina Museum of Natural Sciences. The elements were: 1) an exhibit, Ancient Fossils, New Discoveries; 2) Investigate Labs; 3) Daily Planet Scientist Talks; 4) Science Cafes. Evaluation was conducted as four distinct, multi-method studies to provide targeted understanding of visitor outcomes and experiences at each element. Findings across the four elements indicate that the features of the NRC are enjoyed by visitors and each supports
The National Science Foundation (NSF) awarded an Informal Science Education (ISE) grant, since renamed Advancing Informal STEM Learning (AISL) to a group of institutions led by two of the University of California, Davis’s centers: the Tahoe Environmental Research Center (TERC) and the W.M. Keck Center for Active Visualization in Earth Sciences (KeckCAVES). The purpose of the evaluation was to gather feedback from museum professionals and the general public about the proposed 3D visualization project and its related components. Additionally, the study aimed to assess the current understanding
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University of California, DavisSteven Yalowitz
This project entails the creation of a coordinated colony of robotic bees, RoboBees. Research topics are split between the body, brain, and colony. Each of these research areas is drawn together by the challenges of recreating various functionalities of natural bees. One such example is pollination: Bees coordinate to interact with complex natural systems by using a diversity of sensors, a hierarchy of task delegation, unique communication, and an effective flapping-wing propulsion system. Pollination and other agricultural tasks will serve as challenge thrusts throughout the life of this project. Such tasks require expertise across a broad spectrum of scientific topics. The research team includes experts in biology, computer science, electrical and mechanical engineering, and materials science, assembled to address fundamental challenges in developing RoboBees. An integral part of this program is the development of a museum exhibit, in partnership with the Museum of Science, Boston, which will explore the life of a bee and the technologies required to create RoboBees.
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Robert WoodRadhika NagpalJ. Gregory MorrisettGu-Yeon WeiJoseph Ayers
In 2013 and 2014, the Museum of Science (MOS) partnered with Dr. Rob Wood’s lab at Harvard University’s School of Engineering and Applied Sciences (SEAS) to create an exhibition about Wood’s Robotic Bees (RoboBees) project. The Microrobotics Takes Flight exhibition (referred to in the original grant as the RoboBees exhibition) consists of three interactive components and an introductory section. The three interactive components are modeled on the three different engineering teams working on the RoboBees project: the Brain, the Body, and the Colony teams. The purpose of the evaluation was
Young people's participation in informal STEM learning activities can contribute to their academic and career achievements, but these connections are infrequently explicitly recognized or cultivated. More systemic approaches to STEM education could allow for students' experiences of formal and informal STEM learning to be aligned, coordinated, and supported across learning contexts. This Science Learning+ planning project brings together stakeholders in two digital badge systems--one in the US and one in the UK--to plan for a study to identify the specific structural features of the systems that may allow for the alignment of learning objectives across institutions. Digital badge systems may offer an inventive solution to the challenge of connecting and building on youth's STEM-related experiences in multiple learning contexts. When part of a defined system, badges could be used to represent and communicate evidence of individual learning, as well as provide youth and educators with evidence-supported indicators for other activities in the system that might be interesting or valuable. Properly designed and supported badge systems could transmit critical information within a network of informal STEM programs and schools that (1) recognize context-dependent, interest-driven learning and (2) provide opportunities to explore those interests across multiple settings. This project advances the field of informal STEM learning in two ways. First, the project documents and analyzes the processes by which two small groups of informal science education organizations and schools negotiate the meaning and value of badges, as proxies for learning objectives, and how they decide to recognize badges awarded by other institutions. This process builds capacity within the target systems while also beginning to identify the institutional, cultural, and material capacity issues that facilitate or constrain the alignment process. Second, the project conducts a pilot study with a small number of youth in the US and UK to investigate factors associated with an individual youth's likelihood of: a) identifying badges of interest; b) connecting the activities of various badge systems to each other and to non-badging institutions, such as school or industry; c) determining which badges to pursue; and d) persisting in a particular badge pathway. Findings from this pilot study will help identify institution- and individual-level factors that might be associated with advancing student interest and progression in STEM fields. Deepening and validating the understanding of those factors and their relative impact on student experiences and outcomes will be the focus of investigations in future studies.
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James DiamondNew York City Hive Learning NetworkMOUSEDigitalMeKatherine McMillan
Based on the number of visitors annually, zoos and aquariums are among the most popular venues for informal STEM learning in the United States and the United Kingdom. Most research into the impacts of informal STEM learning experiences at zoos and aquariums has focused on short-term changes in knowledge, attitudes and behaviors. This Science Learning+ project will identify the opportunities for and barriers to researching the long-term impacts of informal STEM learning experiences at zoos and aquariums. The project will address the following overarching research question: What are and how do we measure the long-term impacts of an informal STEM learning experience at a zoo and aquarium? While previous research has documented notable results, understanding the long-term impacts of zoo and aquarium learning experiences will provide a deeper and more nuanced understanding of the impact of these programs on STEM knowledge, skills and application. This study will use a participatory process to identify: (1) the range of potential long-term impacts of informal science learning experiences at zoos and aquariums; (2) particular activities that foster these impacts; and (3) opportunities for and barriers to measuring those impacts. First, an in-depth literature review will document previous research efforts to date within the zoo and aquarium community. Second, a series of consultative workshops (both in-person and online) will gather ideas and input from practitioners, researchers, and other stakeholders in zoo and aquarium education. The consultative workshops will focus on two questions in particular: (1) What are the different types and characteristics of informal science learning experiences that take place at zoos and aquariums? and (2) What are the long-term impacts zoos and aquariums are aiming to have on visitors in relation to knowledge, attitudes, skills and behaviors/actions? Finally, visitor surveys at zoos and aquariums in the US and UK will be conducted to gather input on what visitors believe are the long-term impacts of an informal STEM learning opportunity at a zoo or aquarium. The data gathered through all of these activities will inform the design of a five-year, mixed-methods study to investigate long-term impacts and associated indicators of an informal STEM learning experience at a zoo or aquarium. One of the aims of the five-year study will be to test instruments that could eventually be used by the global zoo and aquarium community to measure the long-term impacts of informal STEM learning programs. Designing tools to better understand the long-term impacts of informal STEM learning at zoos and aquariums will contribute to our ability to measure STEM learning outcomes. Additional benefits include improved science literacy and STEM skills amongst visitors over time and an understanding of how education programs contribute to wildlife conservation worldwide.
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Brian JohnsonStanford UniversityLancaster UniversitySarah ThomasNicole ArdoinMurray Saunders
resourceprojectProfessional Development, Conferences, and Networks
This is a Science Learning+ planning project that will develop a research plan for investigating how applying the principles of embodied cognition to the design of informal learning environments can support young children's (ages 2-6) engagement with, and understanding of, science topics and concepts. While it has been fairly well established that cognition is intertwined with the body's interaction in the physical world, the precise means of applying these ideas to the design of effective learning environments is still emerging. Experimenting with various embodied cognition activities and physical learning configurations to understand what conditions are optimal for informal learning environments for early learners is a major objective of this project. During the planning grant period, the project will identity additional practitioner/research collaborations and will develop research plans for a suite of studies to be enacted by multiple teams of informal learning practitioners and cognitive scientists across the US and UK and that will be submitted as a Phase 2 research. The primary activities of this planning period include organizing a series of workshops that bring together informal learning educators and embodied cognition researchers to engage in deep discussion and design experimentation that will inform the development and refinement of research questions, protocols, and measurement tools. These discussions will be informed by observations of young children as they interact with the River of Grass, an exhibit prototype in which principles of embodied cognition are embedded in its design. The planning period will be led by a collaborative team of informal learning practitioners and cognitive scientists from the US and UK. This group will also oversee plans for the development of a new model for informal STEM research in which a constellation of practitioner/research teams across multiple organizations investigates topics of importance to informal learning practice and research that have the potential to result in a robust body of research that informs the design of informal learning spaces.
This design case explores the affordances of gigapixel image technology for science communication and learning in museum settings through the iterative development of an explorable image viewer to engage visitors in an archaeological exhibit. We reflect on the series of user studies, prototype iterations, and design decisions taken to optimize navigation, annotation and exploration in this zoomable user interface. We highlight a set of design precedents, interaction frameworks, and content structuring approaches, while detailing the development of a media rich digital annotation strategy to
The National Science Foundation (NSF) awarded funding to the Oregon Museum of Science and Industry (OMSI) and Portland State University (PSU) in Portland, Oregon to support a “Connecting Researchers and Public Audiences” (CRPA) project titled ResearchLink: Spotlight on Solar Technologies. The primary goals of CRPA projects are to communicate to the public about specific NSF research projects. This ResearchLink project promoted public awareness of two NSF-funded projects led by Dr. Carl Wamser at PSU, Integrating Green Roofs and Photovoltaic Arrays for Energy Management and Optimization of
Research in experimental and developmental psychology, cognitive science, and neuroscience, suggests that tool fluency depends on the merging of perceptual and motor aspects of its use, an achievement we call perceptuomotor integration. We investigate the development of perceptuomotor integration and its role in mathematical thinking and learning. Just as expertise in playing a piano relies on the interanimation of finger movements and perceived sounds, we argue that mathematical expertise involves the systematic interpenetration of perceptual and motor aspects of playing mathematical
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Ricardo NemirovskyMolly KeltonBohdan Rhodehamel
To better help museum visitors make sense of large data sets, also called “Big Data”, this study focused on the types of visual representations visitors recognize, and how they make meaning (or not) of various visuals. Individual adults and youths were shown five different data visualizations (one from each of five categories), one at a time, and asked if the visualization looked familiar and how it was read. This study found that Context and previous experience matters. Participants of all ages are familiar with a wide variety of visual displays of data. If a participant encounters a visual
To better help museum visitors make sense of large data sets, also called “big data”, this study focuses on what museum visitors felt individual layers of a visual (alone and in combination with other layers) were communicating to them as the visual was constructed or deconstructed layer by layer. A second, smaller study, collected data to better understand how adult visitors would construct large data visualizations. This study was concerned with how people make sense of “big data” in their daily lives and how they engage with reference systems. The primary study used four different “big data