The State University of New York (SUNY) and the New York Academy of Sciences (NYAS) are collaborating to implement the SUNY/NYAS STEM Mentoring Program, a full scale development project designed to improve the science and math literacy of middle school youth. Building upon lessons learned through the implementation of national initiatives such as NSF's Graduate STEM Fellows in K-12 Education (GK-12) Program, university initiatives such as the UTeach model, and locally-run programs, this project's goals are to: 1) increase access to high quality, hands-on STEM programs in informal environments, 2) improve teaching and outreach skills of scientists in training (graduate and postdoctoral fellows), and 3) test hypotheses around scalable program elements. Together, SUNY and NYAS propose to carry out a comprehensive, systemic science education initiative to recruit graduate students and postdoctoral fellows studying science, technology, engineering, and mathematics (STEM) disciplines at colleges and universities statewide to serve as mentors in afterschool programs. SUNY campuses will partner with a community-based organization (CBO) to place mentors in afterschool programs serving middle school students in high-need, low-resource urban and rural communities. Project deliverables include a three-credit online graduate course for mentor training, six pilot sites, a best practices guide, and a model for national dissemination. The online course will prepare graduate and postdoctoral fellows to spend 12-15 weeks in afterschool programs, introducing students to life science, earth science, mathematics and engineering using curriculum modules that are aligned with the New York State standards. The project design includes three pre-selected sites (College of Nanoscale Science & Engineering at the University of Albany, SUNY Institute of Technology, and SUNY Downstate Medical Center) and three future sites to be selected through a competitive process, each of which will be paired with a CBO to create a locally designed STEM mentoring program. As a result, a minimum of 192 mentors will provide informal STEM education to 2,880 middle school students throughout New York State. The comprehensive, mixed-methods evaluation will address the following questions: 1) Does student participation in an afterschool model of informal education lead to an increase in STEM content knowledge, attitudes, self-efficacy, and interest in pursuing further STEM education and career pathways? 2) Do young scientists who participate in the program develop effective teaching and mentoring skills, and develop interest in teaching or mentoring career options that result in STEM retention? 3) What are the attributes of an effective STEM afterschool program and the elements of local adaptation and innovation that are necessary to achieve a successful scale-up to geographically diverse locations? 4) What is the role of the afterschool model in delivering informal STEM education? This innovative model includes a commitment to scale across the 64 SUNY campuses and 122 Councils of the Girl Scouts of the USA, use an online platform to deliver training, and place scientists-in-training in informal learning environments. It is hypothesized that as a result of greater access to STEM education in an informal setting, participating middle school youth will develop increased levels of STEM content knowledge, self-efficacy, confidence in STEM learning, and interest in STEM careers. Scientist mentors will: 1) gain an understanding of the context and characteristics of informal science education, 2) develop skills in mentoring and interpersonal communication, 3) learn and apply best practices of inquiry instruction, and 4) potentially develop interest in teaching as a viable career option. It is anticipated that the project will add to the research literature in several areas such as the effectiveness of incentives for graduate students; the design of mentor support systems; and the structure of pilot site programs in local communities. Findings and materials from this project will be disseminated through presentations at local, regional, and national conferences, publications in peer-reviewed journals focused on informal science education, and briefings sent to more than 25,000 NYAS members around the world.
This 2006 paper reviews the ways in which structured informal learning programs for youth have been characterized in the research literature. The paper synthesizes opportunities for and challenges to research in this domain; it categorizes programs and gives concrete examples of various program types. A proposed Vygotskian research framework is organized around key dimensions of the informal learning context, including location, relationships, content, pedagogy, and assessment.
Argumentation in science involves the development, justification, and defence of evidence-based claims, together with the reasoned dispute of counterclaims. This process is the foundation for all scientific endeavours. Supporting the development of argumentation skills, therefore, is a key part of science education. Laboratory work is also as an essential part of science. Combining these two activities, therefore, would seem to be worthwhile. In this study, researchers explored the impact of three different lab-based tasks on the nature and quality of any subsequent argumentation.
In this chapter we explore how people build new theories in the context of collaborative scientific thinking. As illustrated by many of the chapters in this volume, our default notion of "scientific thinking" has changed from that of the lone scientist or student toiling away on a magnum opus or in the laboratory, to that of people working as part of collaborative groups who negotiate goals for the task, co-construct knowledge, and benefit from the diverse prior knowledge that each collaborator brings to the table. In some ways, conceptualizing scientific thinking as fundamentally
Many science educators encourage student experiences of “authentic” science by means of student participation in science-related workplaces. Little research has been done, however, to investigate how “teaching” naturally occurs in such settings, where scientists or technicians normally do not have pedagogical training and generally do not have time (or value) receiving such training. This study examines how laboratory members without a pedagogical background or experience in teaching engage high school students during their internship activities. Drawing on conversation analysis, we analyze
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TEAM MEMBERS:
Pei-Ling HsuWolff-Michael RothAsit Mazumder
Elementary school children are capable of reproducing sophisticated science process skills such as observing, designing experiments, collecting data, and evaluating evidence. An understanding of the nature of scientific knowledge requires more than teaching and learning the performance of these skills. It also requires an appreciation of how these actions lead to knowledge generation and shape its durable and tentative nature. Our understanding of activities that support the teaching and learning of the nature of scientific knowledge is still growing. This study compares how scientific
This article is the culmination of an extensive inquiry-focused interactive experience involving female middle school students and five university scientists, which demonstrated that middle school girls 'perception of science and scientists can be successfully improved. The study exposed students to adult professional scientists over a period of a few days in laboratory and field exercises. Based on student journal entries and pictorial illustrations, as well as attitude surveys, the experience resulted in a keen appreciation of the sciences among the majority of participants and both a
This paper uses a possible selves theoretical framework to examine whether and how adolescent girls' images of themselves as future scientists change during their transition from high school to college. Forty-one female high school graduates from diverse ethnic and socioeconomic backgrounds, who had enrolled in an intensive math and science program while in high school, participated in interviews focused on their perceptions of factors that influenced their career plans over time. Participants suggested that career-related internships and intensive academic programs, especially those that
Summer science programs held in university research facilities provide ideal opportunities for pre-college students to master new skills and renew, refresh, and enrich their interest in science. These types of programs have a positive impact on a student's understanding of the nature of science and scientific inquiry and can open a youngster's eyes to the many possible career opportunities in science. This paper describes a study of high school students enrolled in the Summer Science Academy program at the University of Rochester that investigates the program's impact on students' knowledge of
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TEAM MEMBERS:
Kerry KnoxJan MoynihanDina Markowitz
The purpose of this paper is to explore and discuss the role of practical work in the teaching and learning of science at school level. It emphasizes practical work as a means for students to learn about the nature of science.
Reports from the NSF, NRC, AAAS, and others urge over and over that we must teach "science as science is done," that "science is a way of knowing," that our goal should be to impart "scientific habits of mind," and that learning must be learner-centered and oriented toward process. Fine. But what does this really mean for science education, and especially laboratory education?
The purpose of this paper is to examine the role of laboratory-based science from a perspective that synthesizes developments in (1) science studies, e.g., history, philosophy and sociology of science and (2) the learning sciences, e.g., cognitive science, philosophy of mind, educational psychology, social psychology, computer sciences, linguistics, and (3) educational research focusing on the design of learning environments that promote dynamic assessments. Taken together these three domains have reshaped our thinking about the role inquiry, and in turn the laboratory, has in science