Citizen science has the potential to provide participants with information about conservation issues and to encourage additional conservation actions. In this case study, we describe the current state of conservation education among butterfly citizen science projects in the United States. To determine the extent to which these citizen science projects are promoting an understanding of, and engagement in, conservation among their participants, we used an online questionnaire to census project leaders and assessed their websites for the presence of educational conservation information. We found
Citizen science has the potential to provide participants with information about conservation issues and to encourage additional conservation actions. In this case study, we describe the current state of conservation education among butterfly citizen science projects in the United States. To determine the extent to which these citizen science projects are promoting an understanding of, and engagement in, conservation among their participants, we used an online questionnaire to census project leaders and assessed their websites for the presence of educational conservation information. We found
The discovery of a class of galaxies called Green Peas provides an example of scientific work done by volunteers. This unique situation arose out of a science crowdsourcing website called Galaxy Zoo. It gave the ability to investigate the research process used by the volunteers. The volunteers’ process was analyzed in terms of three models of scientific research and an iterative work model to show the path to this discovery. As has been illustrated in these models of science, the path was iterative, not predetermined, and driven by empirical data. This paper gives a narrative of the 11-month
This award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5).
Scientists and researchers from fields as diverse as oceanography and ecology, astronomy and classical studies face a common challenge. As computer power and technology improve, the sizes of data sets available to us increase rapidly. The goal of this project is to develop a new methodology for using citizen science to unlock the knowledge discovery potential of modern, large data sets. For example, in a previous project Galaxy Zoo, citizen scientists have already made major contributions, lending their eyes, their pattern recognition skills and their brains to address research questions that need human input, and in so doing, have become part of the computing process. The current Galaxy Zoo project has recruited more than 200,000 participants who have provided more than 100 million classifications of galaxies from the Sloan Digital Sky Survey. This project builds upon early successes to develop a mode of citizen science participation which involves not only simple "clickwork" tasks, but also involves participants in more advanced modes of scientific thought. As part of the project, a symbiotic relationship with machine learning tools and algorithms will be developed, so that results from citizen scientists provide a rich training set for improving algorithms that in turn inform citizen science modes of participation. The first phase of the project will be to develop a portfolio of pilot projects from astrophysics, planetary science, zoology, and classical studies. The second phase of the project will be to develop a framework - called the Zooniverse - to facilitate citizen scientists. In particular, research and machine-learning communities will be engaged to identify suitable projects and data sets to integrate into Zooniverse.
The ultimate goal with the Zooniverse is to create a sustainable future for large-scale, internet-based citizen science as part of every researcher?s toolkit, exemplifying a new paradigm in computational thinking, tapping the mental resources of a community of lay people in an innovative and complex manner that promises a profound impact on our ability to generate new knowledge. The project will engage thousands of citizens in authentic science tasks leading to a better public understanding of science and also, by the engagement of students, leading to interest in scientific careers.
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TEAM MEMBERS:
Geza GyukPamela GayChristopher LintottMichael RaddickLucy FortsonJohn Wallin
The majority of the world’s billions of biodiversity specimens are tucked away in museum cabinets with only minimal, if any, digital records of the information they contain. Global efforts to digitize specimens are underway, yet the scale of the task is daunting. Fortunately, many activities associated with digitization do not require extensive training and could benefit from the involvement of citizen science participants. However, the quality of the data generated in this way is not well understood. With two experiments presented here, we examine the efficacy of citizen science participants
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TEAM MEMBERS:
Elizabeth EllwoodHenry BartMichael DooseyDean JueJustin MannGil NelsonNelson RiosAustin Mast
The increasing number of citizen science projects around the world brings the need to evaluate the effectiveness of these projects and to show the applicability of the data they collect. This research describes the Wabash River Sampling Blitz, a volunteer water-quality monitoring program in Central Indiana developed by the Wabash River Enhancement Corporation (WREC). Results indicate that field test strips for nitrate+nitrite-N read by volunteers generally agree with lab-determined values. Orthophosphate results are less transferable owing to low observed concentrations, although the field
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TEAM MEMBERS:
Rebecca MuenichSara PeelLaura BowlingMegan HaasRonald TurcoJane FrankenbergerIndrajeet Chaubey
The success of citizen science in producing important and unique data is attracting interest from scientists and resource managers. Nonetheless, questions remain about the credibility of citizen science data. Citizen science programs desire to meet the same standards of credibility as academic science, but they usually work within a different context, for example, training and managing significant numbers of volunteers with limited resources. We surveyed the credibility-building strategies of 30 citizen science programs that monitor environmental aspects of the California coast. We identified
The field of citizen science is growing with breathtaking speed. Thousands of citizen science projects are now under way around the world, engaging millions of individuals in the process of scientific discovery. In the US, citizen science has been featured at the White House and the federal government has launched a website to showcase federally funded citizen science projects (citizenscience.gov). The largest research and innovation funding program in the European Union, Horizon 2020, is investing heavily in citizen science to tackle societal problems. The Australian government has published
The lack of diversity in the clinician-scientist workforce is a “very serious concern to the NIH” and to health care professions. Current efforts to broaden participation in STEM fields typically target high school and college-age students. Yet, history and national trends suggest that these efforts alone will not result in rapid or significant change because racial and ethnic disparities are already evident by this time. Children are forming career preferences as early as elementary school, a time when they have little exposure to science and STEM career options. The overall vision of this team is to meet the nation’s workforce goal of developing a diverse, clinician-scientist workforce while meeting the nation’s STEM goals. As a step toward this vision, the goal of This Is How We “Role” is to inspire elementary school students towards careers as clinician-scientists by increasing the number of K-4 students with authentic STEM experiences.
This goal will be attained through two specific aims. The focus of Aim 1 is to distribute and evaluate a K-4 afterschool program across the diverse geographic regions of the US, to support the development of a robust and diverse clinician-scientist workforce. Aim 2 is focused on developing the community resources (afterschool program curriculum, informational books and online certificate program) for promoting health science literacy and encouraging careers in biomedical and clinical research for K-4 students from underserved and underrepresented communities. Combined, these aims will enhance opportunities for young children from underserved communities to have authentic STEM experiences by providing culturally responsive, afterschool educational programs which will be delivered by university student and clinician-scientist role models who are diverse in gender, race, and ethnicity.
Books and an online certificate program about health issues impacting people and their animals (i.e. diabetes, tooth decay) will be developed and distributed to children unable to attend afterschool programs. Further, by engaging veterinary programs and students from across the US, along with practicing veterinarians, this program will examine whether the approaches and curriculum developed are effective across the diverse communities and geographic regions that span the country. Elementary school teachers will serve as consultants to ensure that educational materials are consistent with Next Generation Science Standards, and will assist in training university students and clinician-scientists to better communicate the societal impact of their work to the public.
The program will continue to use the successful model of engaging elementary school students in STEM activities by using examples of health conditions that impact both people and their animals. Ultimately, this project will educate, improve the health of, and attract a diverse pool of elementary school students, particularly those from underserved communities, to careers as clinician-scientists.
San Francisco Health Investigators (SF HI), developed and led by the Science & Health Education Partnership at UC San Francisco, will use a community-based participatory research model to provide authentic research experiences for high school students, the majority from backgrounds underrepresented in the sciences.
SF HI will:
1) Develop a community of high school Student Researchers who will conduct research into health issues in their communities, study how adolescents respond to health messages, create new health messages informed by this research, and study the broader impacts of the materials they develop.
2) Partner with educational researchers to research the effects of SF HI on the high school student participants and the impact of the materials on the broader community.
3) Disseminate those materials shown to have the greatest impact nationally.
4) Publish results on the public understanding and awareness of health issues in peer-reviewed journals and other forums to inform and advance the field of public health.
The SF HI model is designed to leverage students’ cultural and technological knowledge and their social capital in the role of Student Researchers as they study the awareness, knowledge and attitudes about current health issues in their communities. It will have a broad range of impacts. Over the course of the project, 100 urban public high school students will be immersed in research projects that have the potential to directly benefit the health of their communities. These Student Researchers will design health messages informed by their social, cultural, and community knowledge and by their research results. They will collectively survey more than 8,500 community members – their peers, neighbors, and attendees at public gatherings to assess the effectiveness of these materials. Student-developed materials will be distributed broadly via the web, high school and college wellness centers, the NIH SEPA community, and other networks – thus these materials have the potential to reach over 1.5 million adolescents and young adults over the life of the project.
Recruiting more research scientists from rural Appalachia is essential for reducing the critical public health disparities found in this region. As a designated medically underserved area, the people of Appalachia endure limited access to healthcare and accompanying public health education, and exhibit higher disease incidences and shorter lifespans than the conventional U.S. population (Pollard & Jacobsen, 2013). These health concerns, coupled with the fact that rural Appalachian adults are less likely to trust people from outside their communities, highlights the need for rural Appalachian youth to enter the biomedical, behavioral, and clinical research workforce. However, doing so requires not only the specific desire to pursue a science, technology, engineering, math, or medical science (STEMM) related degree, it also requires the more general desire to pursue post-secondary education at all. This is clearly not occurring in Tennessee’s rural Appalachian regions where nearly 75% of adults realize educational achievements only up to the high school level. Although a great deal of research and intervention has been done to increase students’ interest in STEMM disciplines, very little research has considered the unique barriers to higher education experienced by rural Appalachian youth. A critical gap in past interventions research is the failure to address these key pieces of the puzzle: combatting real and perceived barriers to higher education and STEMM pursuits in order to increase self-efficacy for, belief in the value of, and interest in pursuing an undergraduate degree. Such barriers are especially salient for rural Appalachian youth.
Our long-range goal is to increase the diversity of biomedical, clinical and behavioral research scientists by developing interventions that both reduce barriers to higher education and increase interest in pipeline STEMM majors among rural Appalachian high school students. Our objective in this application is to determine the extent to which a multifaceted intervention strategy combining interventions to address the barriers to and supports for higher education with interventions to increase interest in STEMM fields leads to increased intentions to pursue an undergraduate STEMM degree. Our hypothesis is that students who experience such interventions will show increases in important intrapersonal social-cognitive factors and in their intentions to pursue a postsecondary degree than students not exposed to such interventions. Based on the low numbers of students from this region who pursue post-secondary education and the research demonstrating the unique barriers faced by this and similar populations (Gibbons & Borders, 2010), we believe it is necessary to reduce perceived barriers to college-going in addition to helping students explore STEMM career options. In other words, it is not enough to simply offer immersive and hands-on research and exploratory career experiences to rural Appalachian youth; they need targeted interventions to help them understand college life, navigate financial planning for college, strategize ways to succeed in college, and interact with college-educated role models. Only this combination of general college-going and specific STEMM-field information can overcome the barriers faced by this population. Therefore, our specific aims are:
Specific Aim 1: Understand the role of barriers to and support for higher education in Appalachian high school students’ interest in pursuing STEMM-related undergraduate degrees. We will compare outcomes for students who participate in our interventions, designed to proactively reduce general college-going barriers while increasing support systems, to outcomes for students from closely matched schools who do not participate in these interventions to determine the extent to which such low-cost interventions, which can reach large numbers of students, are effective in increasing rural Appalachian youth’s intent to pursue STEMM-related undergraduate degrees.
Specific Aim 2: Develop sustainable interventions that decrease barriers to and increase support for higher education and that increase STEMM-related self-efficacy and interest. Throughout our project, we will integrate training for teachers and school counselors, nurture lasting community partnerships, and develop a website with comprehensive training modules to allow the schools to continue implementing the major features of the interventions long after funding ends.
This research is innovative because it is among the first to recognize the unique needs of this region by directly addressing barriers to and supports for higher education and integrating such barriers-focused interventions with more typical STEMM-focused interventions. Our model provides opportunities to assess college-going and STEMM-specific self-efficacy, outcome expectations, and barriers/supports, giving us a true understanding of how to best serve this group. Ultimately, this project will allow future researchers to understand the complex balance of services needed to increase the number of rural Appalachians entering the biomedical, behavioral, and clinical research science workforce.
The death of Pope John Paul II, the "Polish pope", in Rome and the subsequent election of Benedict XVI, the "German pope", have been two great events gaining world-wide media coverage and affecting the whole world. This was due to Karol Wojtyla's ability to reach everyone's heart thus once dubbed the "Great Communicator" and to the Vatican's spiritual, cultural, and political influence all over the world. The death of Pope John Paul II and the election of Benedict XVI also concern science and science communication issues.