Computational social science represents an interdisciplinary approach to the study of reality based on advanced computer tools. From economics to political science, from journalism to sociology, digital approaches and techniques for the analysis and management of large quantities of data have now been adopted in several disciplines. The papers in this JCOM commentary focus on the use of such approaches and techniques in the research on science communication. As the papers point out, the most significant advantages of a computational approach in this sector include the chance to open up a range
Research in the field of science communication started emerging about 50 years ago and has since then matured as a field of academic enquiry. Early findings about research-active authors and countries reveal that scholarly activity in the field has traditionally been dominated by male authors from English-speaking countries in the West. The current study is a systematic, bibliographic analysis of a full sample of research papers that were published in the three most prominent journals in the field from 1979 to 2016. The findings reveal that early inequities remain prevalent, but also that
There is a gap between the discipline of economics and the public it is supposedly about and for. This gap is reminiscent of the divide that led to movements for the public understanding of and public engagement with the natural sciences. It is a gap in knowledge, trust, and opinions, but most of all it is a gap in engagement. In this paper we ask: What do we need to think about — and what do we need to do — in order to bring economics and its public into closer dialogue? At stake is engaged, critical democracy. We turn to the fields of public understanding of science and science studies for
The U.S. Education system is becoming more and more diverse and educators must adapt to continue to be effective. Educators must embrace the diversity of language, color, and history that comprises the typical classroom; this means becoming culturally competent. In doing so, comes with it the prospect of using culture to enhance the learning experience for students and the educator. Although the process of becoming culturally competent can be outlined, the realization of a culturally competent educator depends on changing one’s own perceptions and beliefs. The need for cultural competency and
Science educators in the United States are adapting to a new vision of how students learn science. Children are natural explorers and their observations and intuitions about the world around them are the foundation for science learning. Unfortunately, the way science has been taught in the United States has not always taken advantage of those attributes. Some students who successfully complete their K–12 science classes have not really had the chance to “do” science for themselves in ways that harness their natural curiosity and understanding of the world around them.
The introduction of
DATE:
TEAM MEMBERS:
National Academies of Sciences, Engineering, and Medicine
Given the importance of learning to economic and life success, this review seeks to broaden the conception of learning beyond traditional formal education. Learning occurs every day in many ways and in a range of settings. This broad scope of learning--termed "informal learning"--is increasingly important in the rapidly changing knowledge economy. As such, in this review paper, we examine the different types of informal learning, their opportunities and challenges, and their issues of access and equity. Spanning multiple disciplines, e draw particular attention to the workplace and adult
DATE:
TEAM MEMBERS:
Michelle Van NoyHeather JamesCrystal Bedley
It’s important to communicate the excitement and value of NSF-funded research. This tool (formatted as a Prezi presentation) helps you do that with assistance from NSF public affairs experts, exploring options for communicating your research and broader impacts.
Students in the U.S. educational system are increasingly diverse, and this diversity is reflected in science, technology, engineering, and mathematics (STEM) fields. Diversity in education encompasses students from many races, genders, and socioeconomic backgrounds; students who speak a variety of languages; and students from many cultures. For instance, ethnic diversity increased by 5% across primary and secondary public schools from 2000 to 2007 (Aud, Fox, & KewalRamani, 2010). Diversity is also evident in the socioeconomic make-up of students, with almost half of 4th graders in public
This project will develop standardized, exportable and comparable assessment instruments and models for Women In Engineering (WIE) programs nationwide, thus allowing them to assess their program's activities and ultimately provide data for making well-informed evaluations.
To accomplish this goal, the principal investigators at the University of Missouri and Penn State University will work over a three-year period with their institutions' WIE programs and three cooperating programs at Rensselaer Polytechnic Institute, Georgia Tech, and University of Texas at Austin. With these five programs that collectively represent a variety of private and public, years of experience for WIE directors and student body characteristics, the investigators will pilot, revise, implement, conduct preliminary data analysis and disseminate easy-to-access, reliable and valid assessment instruments. The principles of formative evaluation will be applied to all instruments and products. All institutions will use the same set of instruments, thus allowing them to have access to powerful benchmarking data in addition to the data from each of their respective institutions.
A prior project, the Women's Experience in College Engineering Project (WECE) sought to characterize the factors that influence women students' experiences and decisions by studying college environments, events and support programs that affect women's satisfaction with their engineering major, and their decisions to persist or leave these majors. In contrast to WECE's macro-level and student focus, this proposal's target audience is WIE directors, with a focus on WIE programs, not students.
Women in Engineering programs around the United States are a crucial part of our country's response to the need for more women in engineering professions. There are about 50 WIE programs nationwide. Half have expressed interest in this effort. WIE directors will benefit by having ready-made assessment tools that will allow them to collect data on programs, evaluate these programs, and make decisions on how to revise programs and / or redistribute limited resources to maximize overall program effectiveness. Data from these instruments will also provide substantiated evidence for administrators, advisory boards and potential funding agencies. Finally, because these instruments will be available nationwide, programs will have the opportunity to take advantage of powerful benchmarking data for their decision-making processes.
This project provides the next logical step in the national movement to recruit and retain women in engineering.
Learn how to create opportunities for young people from low-income, ethnically diverse communities to learn about growing food, doing science, and how science can help them contribute to their community in positive ways. The authors developed a program that integrates hydroponics (a method of growing plants indoors without soil) into both in-school and out-of-school educational settings.
This issue features contributions on the theme of STEM Learning Surrounds Us: Building learning ecosystems that connect STEM education across multiple settings. One contribution features a statewide effort in North Carolina, while two others deal with the challenges of serving rural populations.
Reader response has been positive regarding the publishing of each issue in three parts over three months. This means that manageable amounts of content will be sent to you every month, once the journal starts coming out quarterly in spring 2018.
On the first day of the Science and Society course at the Cooperstown Graduate Program in Cooperstown, New York, I present the students with an incandescent lightbulb, with clear glass so one can easily see the filament inside. I ask the students how it works and they are able to tell me that the electricity comes in there, runs through the filament here, heats up, and produces light. Then I take out my iPhone and slide it across the table and ask, “How does this work?” Blank stares abound.