Doctoral students in science disciplines spend countless hours learning how to conduct cutting-edge research but very little time learning to communicate the nature and significance of their science to people outside their field. To narrow this disparity, we created an unusual course titled Communicating Science for doctoral science trainees at Rutgers University. Our goal was to help students develop an advanced ability to communicate their research clearly and accurately and to emphasize its value and significance to diverse audiences. Course design included classroom instruction
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TEAM MEMBERS:
Nicholas PonzioJanet AlderMary NucciDavid DannenfelserHolly HiltonNikolaos LinardopoulosCarol Lutz
WCS Education is committed to creating a diverse and inclusive movement of conservation advocates. We do this by creating equitable pathways to increased scientific literacy, engagement in conservation advocacy, and lasting connection with animals and nature.
One of the programs that incorporates all of these strategies is Project TRUE (Teens Researching Urban Ecology). Project TRUE is a partnership between WCS and Fordham University that is both a social science research study and a youth development program designed to support youth in STEM career pathways. Teams of high school students
The field of ecology is poised to substantially contribute to the creation of a socially and environmentally equitable urban future. To realize this contribution, the field of ecology must create strategies that ensure inclusion of underrepresented minorities so that a broad array of experiences and ideas collectively address challenges inherent to a sustainable urban future. Despite efforts to recruit and retain underrepresented racial minorities (URM) in the sciences, graduation rates have only slightly increased over the last several decades. While research mentoring programs at the
In November 2016, within an Environmental studies course at the University of Venice, students carried out an experiment aimed at collecting scenarios of the Venetian coast's future starting from lessons learnt during the episode of storm surge 50 years ago (Aqua Granda ‘flood’). The students built scenarios able to anticipate the effect of sea level rise on coastal areas in Venice, based not only on scientific input but also on a methodology called “Futurescape city Tours” (FCT) involving inhabitants of the barrier islands of Lido and Pellestrina. This paper will explore three main questions
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TEAM MEMBERS:
Alba L’AstorinaAlessia GhezziStefano GuerzoniEmanuela Molinaroli
This case study of the development of a cross-cultural museum exhibition illustrates value and difficulties of cross-cultural collaboration. University researchers worked with a class of postgraduate science communication students and designers from the Otago Museum to produce a museum exhibition. ‘Wai ora, Mauri ora’ (‘Healthy environments, Healthy people’) provided visibility and public access to information about Māori work. The exhibition assignment provided an authentic assessment of student work, with a professional output. Working on the exhibition involved cross-cultural communication
This commentary introduces a preliminary conceptual framework for approaching putative effects of scholarly online systems on collaboration inside and outside of academia. The first part outlines a typology of scholarly online systems (SOS), i.e., the triad of specialised portals, specialised information services and scholarly online networks which is developed on the basis of nine German examples. In its second part, the commentary argues that we know little about collaborative scholarly community building by means of SOS. The commentary closes with some remarks on further research questions
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TEAM MEMBERS:
Dirk Hommrich
resourceresearchProfessional Development, Conferences, and Networks
We present an assessment of the Engage program, a graduate-student-created and led training program at the University of Washington. Using a pre-course/post-course study design, we examined student ability to deliver a short presentation appropriate for a public audience. Based on both self-assessments and assessments by external reviewers, we show that Engage trainees had an increase in their ability to employ effective communication techniques.
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TEAM MEMBERS:
Melissa ClarksonJuliana HoughtonWilliam ChenJessica Rodhe
This application requests support to enable a team of experienced science educators and biomedical and behavioral health network scientists to develop and implement the Worlds of Connections curriculum. Most middle school students are familiar with patient care-related health careers (e.g., nurses, dentists, surgeons), but few know about emerging careers in network science that can be leveraged to improve population health. This innovative and research-based science program is strategically designed to increase awareness of, understanding of, and interest in the important role of network science for health. This project will design learning activities that incite interest in network science applications to biomedical and public health research. The long- term goal is to enhance the diversity of the bio-behavioral and biomedical workforce by increasing interest in network science among members of underrepresented minority communities and to promote public understanding of the benefits of NIH-funded research for public health. The goal of this application is to identify and create resources that will overcome barriers to network science uptake among underserved minority middle school youth. The central hypothesis is that the technology-rich field of network science will attract segments of today’s youth who remain uninterested in conventional, bio-centric health fields. Project activities are designed to improve understanding of how informal STEM experiences with network science in health research can increase STEM identities, STEM possible selves, and STEM career aspirations among youth from groups historically underrepresented in STEM disciplines at the center of health science research (Aim 1) and create emerging media resources via augmented reality technologies to stimulate broad interest in and understanding of the role of network science in biomedical and public health research (Aim 2). A team led by University of Nebraska-Lincoln sociologists will partner with the University of Nebraska at Omaha; state museums; centers for math, science, and emerging media arts; NIH-funded network scientists; educators; community learning centers at local public schools; learning researchers; undergraduates; software professionals; artists; augmented reality professionals; storytellers; and evaluation experts to accomplish these goals and ensure out of school learning will reinforce Next Generation Science Standards. The Worlds of Connections project is expected to impact 35,250 youth and 20,570 educators in Lincoln and Omaha, Nebraska by: adding network science modules to ongoing 6th-8th-grade afterschool STEM clubs in community learning centers; adding network science for health resources to a summer graduate course on “activating youth STEM identities” for sixth to twelfth grade STEM teachers; connecting teachers with local network scientists; creating free, downloadable, high-quality emerging media arts-enhanced stories; and publishing peer-reviewed research on the potential of network science to attract youth to health careers. Coupled with the dissemination plan, the project design and activities will be replicable, allowing this project to serve as a model to guide other projects in STEM communication.
PUBLIC HEALTH RELEVANCE:
The lack of public understanding about the role of network science in the basic biological and social health sciences limits career options and support for historically underrepresented groups whose diverse viewpoints and questions will be needed to solve the next generation of health problems. The Worlds of Connections project will combine network science, social science, learning research, biology, computer science, mathematics, emerging media arts, and informal science learning expertise to build a series of monitored and evaluated dissemination experiments for middle school science education in high poverty schools. Broad dissemination of the curriculum and project impacts will employ virtual reality technologies to bring new and younger publics into health-related STEM careers.
The purpose of the proposed project, Community of Bilingual English-Spanish Speakers Exploring Issues in Science and Health (CBESS), is to increase linguistic diversity in science, technology, engineering, and math (STEM)-healthcare fields, including biomedical, behavioral, and clinical research careers. With support of the large group of Spanish-English bilingual (SEB), STEM-healthcare professionals that was formed during this proposal preparation, CBESS will contribute to the pipeline between K–12 and higher education/career.
CBESS will recruit Spanish-English bilingual (SEB) high-school students at the end of tenth grade and implement several language-supported STEM-healthcare interventions during the eleventh and twelfth grade (17 months): family-engaged career exploration; Next Generation Science Standards (NGSS)-aligned, inquiry-based, youth-led summer research residential program; community outreach/dissemination, internships, and mentoring.
Applying methods that are known to be effective with the target population, CBESS will also train undergraduate, near-peer instructor-mentors—STEM-healthcare Leadership Trainees (LT)—in inquiry-based instruction and strategies for positioning K–12 bilingual students as “insiders” in STEM-healthcare, as well as in the responsible conduct of research and mentoring skills, followed by practical application with SR.
CBESS will develop and expand the nascent SEB STEM-healthcare community of practice (CoP) that was created during CBESS proposal preparation. Committed academic, clinical, research, and community partners will contribute to research and evaluation efforts, and support the pipeline between K–12 and higher education/career through Community Based Participatory Research (CBPR), framing priority community health issues to be addressed by each cohort of SR from among issues identified by the SR during the application process. Finally, the CoP will target long-term institutional sustainability for linguistically diverse students in STEM-healthcare education and careers.
This project specifically addresses the SMRB’s imperative that “NIH’s pre-college STEM activities need a rejuvenated integrated focus on biomedical workforce preparedness with special considerations for under-represented minorities.”
Approximately one-third of CityLab’s participants are under-represented minority (URM) students, but we now have a unique opportunity to build a program that will reach many URM students and position them for undergraduate STEM success. We have partnered with urban squash education organizations in Boston (SquashBusters) and New York (CitySquash and StreetSquash) that recruit URM/low SES students to participate in after-school squash training and academic enrichment programs. We have also partnered with the Squash + Education Alliance (previously named the National Urban Squash and Education Association) to disseminate the new program—first from Boston to New York and later through its national network of affiliated squash education programs.
In order to bring this project to fruition, Boston University is joining forces with Fordham University in New York. Fordham is home to CitySquash so these organizations provide an ideal base for the New York activities. The proposed project will enable us to demonstrate feasibility and replicability within the 5-year scope of this grant. Our shared vision is to develop a national model for informal precollege biomedical science education that can be infused into a myriad of similar athletic/academic enrichment programs.
The squash education movement for urban youth has been highly successful in enrolling program graduates in college. Since the academic offerings of the squash education programs focus on English Language Arts and Mathematics, their students struggle with science and rarely recognize the tremendous opportunities for long- term employment in STEM fields.
This project will bring CityLab’s resources to local squash programs in a coordinated and sustained engagement to introduce students to STEM, specifically the biomedical sciences. Together with the urban squash centers, we will build upon the hands-on life science experiences developed and widely disseminated by CityLab to create engaging laboratory-based experiences involving athletics and physiology.
The specific aims of the proposed project are:
To develop, implement, and evaluate a new partnership model for recruiting URM/low SES students and inspiring them to pursue careers in STEM; and
To examine changes in the science learner identities (SLI) of the students who participate in this program and establish this metric as a marker for continued engagement in STEM.
With the involvement of the two urban research universities, three local squash education programs, and SEA, we see this new SEPA initiative as a unique way to pilot, refine, and disseminate an after-school/informal science education program that can have a significant impact on the nation’s production of talented STEM graduates from URM/low SES backgrounds.
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TEAM MEMBERS:
Carl FranzblauDonald DeRosaCarla Romney
The goal of our research is to identify strengths and weaknesses of high school level science fair and improvements that might enhance learning outcomes based on empirical assessment of student experiences. We use the web-based data collection program REDCap to implement anonymous and voluntary surveys about science fair experiences with two independent groups -- high school students who recently competed in the Dallas Regional Science and Engineering Fair and post high school students (undergraduates, 1st year medical students, and 1st year biomedical graduate students) on STEM education
This Research Advanced by Interdisciplinary Science and Engineering (RAISE) project is supported by the Division of Research on Learning in the Education and Human Resources Directorate and by the Division of Computing and Communication Foundations in the Computer and Information Science and Engineering Directorate. This interdisciplinary project integrates historical insights from geometric design principles used to craft classical stringed instruments during the Renaissance era with modern insights drawn from computer science principles. The project applies abstract mathematical concepts toward the making and designing of furniture, buildings, paintings, and instruments through a specific example: the making and designing of classical stringed instruments. The research can help instrument makers employ customized software to facilitate a comparison of historical designs that draws on both geometrical proofs and evidence from art history. The project's impacts include the potential to shift in fundamental ways not only how makers think about design and the process of making but also how computer scientists use foundational concepts from programming languages to inform the representation of physical objects. Furthermore, this project develops an alternate teaching method to help students understand mathematics in creative ways and offers specific guidance to current luthiers in areas such as designing the physical structure of a stringed instrument to improve acoustical effect.
The project develops a domain-specific functional programming language based on straight-edge and compass constructions and applies it in three complementary directions. The first direction develops software tools (compilers) to inform the construction of classical stringed instruments based on geometric design principles applied during the Renaissance era. The second direction develops an analytical and computational understanding of the art history of these instruments and explores extensions to other maker domains. The third direction uses this domain-specific language to design an educational software tool. The tool uses a calculative and constructive method to teach Euclidean geometry at the pre-college level and complements the traditional algebraic, proof-based teaching method. The representation of instrument forms by high-level programming abstractions also facilitates their manufacture, with particular focus on the arching of the front and back carved plates --- of considerable acoustic significance --- through the use of computer numerically controlled (CNC) methods. The project's novelties include the domain-specific language itself, which is a programmable form of synthetic geometry, largely without numbers; its application within the contemporary process of violin making and in other maker domains; its use as a foundation for a computational art history, providing analytical insights into the evolution of classical stringed instrument design and its related material culture; and as a constructional, computational approach to teaching geometry.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.