The American Museum of Natural History (AMNH), in collaboration with New York University's Institute for Education and Social Policy and the University of Southern Maine Center for Evaluation and Policy, will develop and evaluate a new teacher education program model to prepare science teachers through a partnership between a world class science museum and high need schools in metropolitan New York City (NYC). This innovative pilot residency model was approved by the New York State (NYS) Board of Regents as part of the state’s Race To The Top award. The program will prepare a total of 50 candidates in two cohorts (2012 and 2013) to earn a Board of Regents-awarded Masters of Arts in Teaching (MAT) degree with a specialization in Earth Science for grades 7-12. The program focuses on Earth Science both because it is one of the greatest areas of science teacher shortages in urban areas and because AMNH has the ability to leverage the required scientific and educational resources in Earth Science and allied disciplines, including paleontology and astrophysics.
The proposed 15-month, 36-credit residency program is followed by two additional years of mentoring for new teachers. In addition to a full academic year of residency in high-needs public schools, teacher candidates will undertake two AMNH-based clinical summer residencies; a Museum Teaching Residency prior to entering their host schools, and a Museum Science Residency prior to entering the teaching profession. All courses will be taught by teams of doctoral-level educators and scientists.
The project’s research and evaluation components will examine the factors and outcomes of a program offered through a science museum working with the formal teacher preparation system in high need schools. Formative and summative evaluations will document all aspects of the program. In light of the NYS requirement that the pilot program be implemented in high-need, low-performing schools, this project has the potential to engage, motivate and improve the Earth Science achievement and interest in STEM careers of thousands of students from traditionally underrepresented populations including English language learners, special education students, and racial minority groups. In addition, this project will gather meaningful data on the role science museums can play in preparing well-qualified Earth Science teachers. The research component will examine the impact of this new teacher preparation model on student achievement in metropolitan NYC schools. More specifically, this project asks, "How do Earth Science students taught by first year AMNH MAT Earth Science teachers perform academically in comparison with students taught by first year Earth Science teachers not prepared in the AMNH program?.”
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TEAM MEMBERS:
Maritza MacdonaldMeryle WeinsteinRosamond KinzlerMordecai-Mark Mac LowEdmond MathezDavid Silvernail
The Liz Lerman Dance Exchange, in partnership with several universities and a science advisory committee of distinguished international researchers in physics and astronomy, is producing "The Matter of Origins," a two-part experimental program that engages the public in explorations of the nature of beginnings and the physics of the origin of matter. Act I takes place in a theater where audiences will experience a dance performance illuminated by video and a vivid soundscape. Act II takes place in an adjacent space where audiences, who will be seated with scientists, historians, philosophers, and religious leaders, can participate in facilitated dialogue about the nature of origins in an immersive environment that incorporates dance, projected images, and provocative questions. The program will be implemented around the country, initially at four universities, with possible expansion to additional venues. The goals of this EAGER project are (1) to develop an innovative model for using dance, digital media, and structured dialogue to attract and engage public audiences in science content and processes and (2) to explore how artistic practices may have broader applications with respect to science learning and research. The intention is to explore how science can be represented in the art and in the experience and not simply interpreted into abstract choreographic expression with a program note. The program elements and outcomes will be evaluated by researchers from Michigan State University who will study impacts on the public and on participating professionals - dancers, scientists, etc. Dissemination of results will be to professional communities in the sciences, arts and informal science education.
'Be a Scientist!' is a full-scale development project that examines the impact of a scalable, STEM afterschool program which trains engineers to develop and teach inquiry-based Family Science Workshops (FSWs) in underserved communities. This project builds on three years of FSWs which demonstrate improvements in participants' science interest, knowledge, and self-efficacy and tests the model for scale, breadth, and depth. The project partners include the Viterbi School of Engineering at the University of Southern California, the Albert Nerken Engineering Department at the Cooper Union, the Los Angeles Museum of Natural History, and the New York Hall of Science. The content emphasis is physics and engineering and includes topics such as aerodynamics, animal locomotion, automotive engineering, biomechanics, computer architecture, optics, sensors, and transformers. The project targets underserved youth in grades 1-5 in Los Angeles and New York, their parents, and engineering professionals. The design is grounded in motivation theory and is intended to foster participants' intrinsic motivation and self-direction while the comprehensive design takes into account the cultural, social, and intellectual needs of diverse families. The science activities are provided in a series of Family Science Workshops which take place in afterschool programs in eight partner schools in Los Angeles and at the New York Hall of Science in New York City. The FSWs are taught by undergraduate and graduate engineering students with support from practicing engineers who serve as mentors. The primary project deliverable is a five-year longitudinal evaluation designed to assess (1) the impact of intensive training for engineering professionals who deliver family science activities in community settings and (2) families' interest in and understanding of science. Additional project deliverables include a 16-week training program for engineering professionals, 20 physics-based workshops and lesson plans, Family Science Workshops (40 in LA and 5 in NY), a Parent Leadership Program and social networking site, and 5 science training videos. This project will reach nearly one thousand students, parents, and student engineers. The multi-method evaluation will be conducted by the Center for Children and Technology at the Education Development Center. The evaluation questions are as follows: Are activities such as recruitment, training, and FSWs aligned with the project's goals? What is the impact on families' interest in and understanding of science? What is the impact on engineers' communication skills and perspectives about their work? Is the project scalable and able to produce effective technology tools and develop long-term partnerships with schools? Stage 1 begins with the creation of a logic model by stakeholders and the collection of baseline data on families' STEM experiences and knowledge. Stage 2 includes the collection of formative evaluation data over four years on recruitment, training, co-teaching by informal educators, curriculum development, FSWs, and Parent Leadership Program implementation. Finally, a summative evaluation addresses how well the project met the goals associated with improving families' understanding of science, family involvement, social networking, longitudinal impact, and scalability. A comprehensive dissemination plan extends the project's broader impacts in the museum, engineering, evaluation, and education professional communities through publications, conference presentations, as well as web 2.0 tools such as blogs, YouTube, an online social networking forum for parents, and websites. 'Be a Scientist!' advances the field through the development and evaluation of a model for sustained STEM learning experiences that helps informal science education organizations broaden participation, foster collaborations between universities and informal science education organizations, increase STEM-based social capital in underserved communities, identify factors that develop sustained interest in STEM, and empower parents to co-invest and sustain a STEM program in their communities.
Explore the Galaxy involved teens from Chicago Public Schools (CPS) in planning for an upcoming exhibition and its interpretation. The Adler Planetarium worked with teens from several CPS high schools, with a special focus on the CPS Air Force Academy High School (AFAHS). The goals were to develop institutional partnerships and capacity for a teen docent program as well as to do formative evaluation for an upcoming exhibition. All goals were met. The Adler is now in year 4 of a comprehensive partnership with the AFAHS involving students from all four grades in field trips, activities, after-school clubs and Adler internships. The AFAHS students are now participants in an active teen internship program that places students in different Adler professional departments every summer. As well the Adler employs volunteer and paid teen interpreters on school year weekends. These relationships and programs depend on the foundations laid through the work of this grant. In the realm of exhibition design, teens also interviewed visitors about prior conceptions and interest in several areas related to cosmology including how gravity works and the size and age of the universe. Their comments influenced design of, The Universe a Walk through Space and Time, which opened in summer of 2012.
Annotated, integrated, illustrated practical instructions result in higher levels of performance on task; lower completion time, task difficulty, and perceived cognitive load; higher relative efficiency score and post-test scores than the conventional instructions; and makes practical work instructions easier to understand for students with no prior knowledge of the subject matter.
Transitioning from textbook-style problems to ""real-world"" physics problem-solving requires participants to set limiting assumptions. In textbook-style questions these assumptions aren't necessary because all the numerical values are provided by the textbook. However, in real-world challenges this is often not the case. The article has implications for educators who are thinking about how to use real-world problems in their work.
In this paper, the learning resources and museum visit that formed part of an undergraduate teaching sequence on the special theory of relativity are described and discussed. Findings highlight the importance of integrating pre- and post-visit activities, although the methods used to evaluate the impact of the experience do not offer conclusive results.
This study reports on how high school students use scientifically correct language to articulate the concept of ‘force’. Although the analysis is somewhat complex, the importance of this study is its research of how the students engage with scientific concepts and language, and moreover, how they use and apply it.
The formal introduction of learners to scientific phenomena is accompanied by the need to reconcile what they are being taught in classrooms with their informal or pre-existing conceptualizations of the same phenomena. Reconciled formal and informal conceptualizations represent what the authors of this study refer to as “conceptual continuity,” which, they argue, is an important asset for science educators seeking to support students’ conceptual development. In this paper, authors studied the ways in which high-school baseball players expressed their understanding of how curveballs curve using
The EDC Center for Children and Technology (CCT), a nonprofit international research organization, conducted the formative evaluation of the first year's implementation of the Be A Scientist! (BAS) project. The goal of this five-year afterschool family science program project is to provide quality science and engineering courses to underserved families in New York City and Los Angeles. It targeted underserved first graders and their families in the Spring 2010. Guiding by formative research questions (e.g., X) and using multi-method research approach (e.g., X), CCT researchers uncovered
The proposed CAREER study uses a comprehensive mixed-methods design to develop measures of motivational beliefs and family supports for Spanish and English speaking Mexican-origin youth in high school physical science. The research examines a three-part model which may provide a deeper understanding of how Mexican families support youth through their general education strategies, beliefs about physical science, and science specific behaviors. This approach incorporates motivation and ecodevelopmental theories while pursuing an innovative line of research that examines how the contributions of older siblings and relatives complement or supplement parental support. The study has four aims which are to (1) to develop reliable, valid measures of Mexican-origin adolescent motivational beliefs and family supports in relation to high school chemistry and physics, (2) to test whether family supports predict motivational beliefs and course enrollment, (3) to test how indicators in Aim 2 vary based on gender, culture, English language skills and relationship quality, and (4) to examine how family supports strengthen or weaken the relationship between school-based interactions (teachers and peer support) and the pursuit of physical science studies. Spanish and English-speaking Mexican-origin youth will participate in focus groups to inform the development of a survey instrument which will be used in a statistical measurement equivalence study of 300 high school students in fulfillment of Aim 1. One hundred and fifty Mexican high school students and their families will participate in a longitudinal study while students progress through grades 9-12 to examine Aims 2- 4. Data to be collected includes information on science coursework, adolescent motivational beliefs, supports by mothers and older youth in the family, and family interactions. All materials will be in English and Spanish. The educational and research integration plan uses a three pronged approach which includes mentoring of doctoral students, teacher outreach, and the evaluation of the ASU Biodesign high school summer internship program using measures resulting from the research. It is anticipated that the study findings will provide research-based solutions to some of the specific behaviors that influence youth motivation in physical sciences. Specifically, the study will identify youth that might be most affected by an intervention and the age of maximum benefit, as well as valid, reliable measures of youths' motivation that can used in interventions to measure outcomes. The study will also identify family behaviors that may be influenced, including education strategies for school preparation, beliefs about physical science, and sciece-specific strategies such as engaging in science activities outside school. The findings will be broadly disseminated to science teachers, scholars, and families of Mexican-origin youth. This multi-tiered approach will advance current scholarship and practice concerning Mexican-origin adolescents' pursuit of physical science.
This research project, from The University of Central Florida, and the Museum of Science and Industry, investigates a three-cycle research and development process where middle school student learners will be immersed in a mixed reality environment while interacting with functional metaphors to determine the effects of conceptual change, motivation and scientific habits of mind while engaged in learning physics content. The project is guided by the following research questions: How does the opportunity to embody elements of an immersive simulation affect a learner's propensity to experience conceptual change and develop scientific habits of mind? What design features of missed reality environments best support metaphors? What metrics are most effective for assessing learning through body-based metaphors? What are the practical considerations to creating immersive metaphor-based learning experiences in ISE institutions such as a Science Center? The investigators will use a between subjects mixed method approach with middle school students (N = 360) involving three research cycles that are performed in controlled conditions. The multiple iterations will allow modifications to the study's design to dig deeper into the data and afford more careful analysis, revisions and modifications to simulation content, protocol and data collection instruments and the technology installation. Middle school students will be recruited from local schools and the Museum of Science and Industry visitors. The evaluation plan includes the assessment of perceived values of using whole-body metaphors within mixed reality environments to learn physics. Professional audiences, educators and ISE practitioners will assess the impact, design and content associated with research on learning, mixed reality design, science and physics education. Research on understanding the process of using whole-body interactions in a mixed reality environments will help educational researchers and practitioners in the field understand the effectiveness of metaphor based learning of scientific concepts with whole body interactions. This project contributes knowledge about how people learn within informal settings. This theory-driven design approach has the potential for broad implementation in both formal and informal environments.