Scientists have long sought to engage public audiences in research through citizen science projects such as biological surveys or distributed data collection. Recent online platforms have expanded the scope of what people-powered research can mean. Science museums are unique cultural institutions that translate scientific discovery for public audiences, often conducting research of their own. This makes museums compelling sites for engaging audiences directly in scientific research, but there are associated challenges as well. This project engages public audiences in contributing to real
DATE:
TEAM MEMBERS:
Mmachi God’sglory ObiorahJames K.L. HammermanWill GrangerHaley Margaret WestLaura TrouilleBecky RotherMichael Horn
An independent evaluator and a group of investigators from three AISL projects focused on public engagement with science (PES) collaborated on a paper about research-practice partnerships for PES. This two-page brief summarizes their key points.
Framing: Broadening participation and achieving equitable outcomes has been a core goal of the science museum field for over two decades. However, how to make progress has proven an intractable problem.
Methods: Focusing on five organizations who officially committed to diversity, equity, access, and inclusion (DEAI) by participating in a national professional development program, the researchers investigate how science museums attempt to enact internally-focused change via a mixed methods case study.
Findings: While these organizations considered a variety of structurally focused change
Community voice, alongside academic voice, is essential to the core community engagement principle of reciprocity—the seeking, recognizing, respecting, and incorporating the knowledge, perspectives, and resources that each partner brings to a collaboration. Increasing the extent to which academic conferences honor reciprocity with community members is important for many reasons. For example, community perspectives often enhance knowledge generation and potentially transform scholarship, practice, and outcomes for all stakeholders. However, community presence and participation at academic
This guide compiles lessons learned by seven Portal to the Public Network (PoPNet) sites as well as remaining challenges and recommendations for organizations planning similar efforts in the future. PoPNet sites used the Portal to the Public Guiding Framework to build relationships with local scientists, prepare them for public engagement using Portal to the Public training materials, and feature them at public programs.
With funding from the NASA Science Activation program, the Space Science Institute (SSI) launched NASA@ My Library in 2016. The vision of NASA@ My Library was to help public libraries and state library agencies increase NASA and STEM learning opportunities for library patrons throughout the U.S., including those in geographic areas and populations currently underserved in STEM education. SSI worked closely with its partners, including the American Library Association (ALA), Cornerstones of Science (CoS), the Lunar and Planetary Institute (LPI), and the Pacific Science Center’s Portal to the
With funding from the NASA Science Activation program, the Space Science Institute (SSI) launched NASA@ My Library in 2016. The vision of NASA@ My Library was to help public libraries and state library agencies increase NASA and STEM learning opportunities for library patrons throughout the U.S., including those in geographic areas and populations currently underserved in STEM education. SSI worked closely with its partners, including the American Library Association (ALA), Cornerstones of Science (CoS), the Lunar and Planetary Institute (LPI), and the Pacific Science Center’s Portal to the
With funding from the NASA Science Activation program, the Space Science Institute (SSI) launched NASA@ My Library in 2016. The vision of NASA@ My Library was to help public libraries and state library agencies increase NASA and STEM learning opportunities for library patrons throughout the U.S., including those in geographic areas and populations currently underserved in STEM education. SSI worked closely with its partners, including the American Library Association (ALA), Cornerstones of Science (CoS), the Lunar and Planetary Institute (LPI), and the Pacific Science Center’s Portal to the
With funding from the NASA Science Activation program, the Space Science Institute (SSI) launched NASA@ My Library in 2016. The vision of NASA@ My Library was to help public libraries and state library agencies increase NASA and STEM learning opportunities for library patrons throughout the U.S., including those in geographic areas and populations currently underserved in STEM education. SSI worked closely with its partners, including the American Library Association (ALA), Cornerstones of Science (CoS), the Lunar and Planetary Institute (LPI), and the Pacific Science Center’s Portal to the
Informal learning environments offer a range of educational observations. Lately, many venues have adopted livestreaming and digital archiving, both as additional access for a wider offsite audience and as alternative ways to engage the onsite audience. Students can observe animals and plants from a different continent through a live camera feed, or they can watch an online recording of a science experiment even if they missed the live demonstration. However, livestreamed or archived observations remain a mostly passive experience, offering limited interactions beyond watching the videos. One way to create more active learning opportunities from these observations is to use sensors such as thermal cameras as additional streaming devices, which transmit real-time images and data that not only reveal more about what is being observed, but also allow the audience to ask deeper questions, find answers by interacting with the data, apply science knowledge in a relevant context, and become an active participant in scientific inquiry.
This project has created Telelab, a cloud platform for livestreaming and archiving interactive observations to promote citizen science. Powered by the Internet of things (IoT), Telelab allows informal science educators to present exhibits, living organisms or ecosystems through the use of sensors and actuators. Audiences both onsite and offsite can visualize biological processes in situ, such as thermoregulation, thermogenesis, metabolism, etc., or they can investigate physics and chemistry experiments by analyzing experimental data in combination with the video stream.
This work 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 opportunities for the public in informal environments; provide multiple pathways for broadening access to and engagement in STEM learning experiences; advance innovative research on and assessment of STEM learning in informal environments; and engage the public of all ages in learning STEM in informal environments.
Imprecise definition of key terms in the "public participation" domain have hindered the conduct of good research and militated against the development and implementation of effective participation practices. In this article, we define key concepts in the domain: public communication, public consultation, and public participation. These concepts are differentiated according to the nature and flow of information between exercise sponsors and participants. According to such an information flow perspective, an exercise's effectiveness may be ascertained by the efficiency with which full, relevant
We characterize the factors that determine who becomes an inventor in the United States, focusing on the role of inventive ability (“nature”) vs. environment (“nurture”). Using deidentified data on 1.2 million inventors from patent records linked to tax records, we first show that children’s chances of becoming inventors vary sharply with characteristics at birth, such as their race, gender, and parents’ socioeconomic class. For example, children from high-income (top 1%) families are ten times as likely to become inventors as those from below-median income families. These gaps persist even
DATE:
TEAM MEMBERS:
Alex BellRaj ChettyXavier JaravelNeviana PetkovaJohn Van Reenen