RISES (Re-energize and Invigorate Student Engagement through Science) is a coordinated suite of resources including 42 interactive English and Spanish STEM videos produced by Children's Museum Houston in coordination with the science curriculum department at Houston ISD. The videos are aligned to the Texas Essential Knowledge and Skills standards, and each come with a bilingual Activity Guide and Parent Prompt sheet, which includes guiding questions and other extension activities.
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TEAM MEMBERS:
resourceevaluationProfessional Development, Conferences, and Networks
This document describes the summative project evaluation of 5 annual cohorts of STE(A)M teachers, mostly from California, Florida, and New Mexico participating in out-of-school authentic research experiences collecting fossils and learning about geology, biology, and the natural history along the Panama Canal, and their experiences with museums and research collections. The STEM content of this project is based on the Great American Biotic Interchange (GABI) of animals and plants across the Isthmus of Panama over the past 5 million years. This report also describes the efficacy of sustained
The project team is developing a prototype of a web-based game utilizing the illustrations of chemical elements and science terms created by Simon Basher in his three books, The Periodic Table: Elements with Style!, Chemistry: Getting a Big Reaction!, and Physics: Why Matter Matters! The game will incorporate augmented reality (person-to-person gameplay with the support of the software) to teach grade 4 to 6 students science concepts, including an introduction to chemistry. The game will include curriculum support materials. Pilot research in Phase I will seek to demonstrate that the software prototype functions as planned, teachers are able to integrate it within the classroom environment, and students are engaged with the prototype.
The project team is developing a prototype of Happy Atoms, a game to support middle school students in learning about the composition of molecules. Happy Atoms will include physical manipulative balls with embedded magnets wirelessly connected to a tablet application (app) to recognize whether or not the created molecule exists and explain why or why not. The app will also include teacher resources including instructional videos and curriculum suggestions in order to better integrate the use of the product into classrooms. In the Phase I pilot research, the project team will examine whether the hardware and software prototypes function as planned, teachers are able to integrate it within the classroom environment, and students are engaged with the prototype.
Purpose: This project will develop and test Happy Atoms, a physical modeling set and an interactive iPad app for use in high school chemistry classrooms. Happy Atoms is designed to facilitate student learning of atomic modeling, a difficult topic for chemistry high school students to master. Standard instructional practice in this area typically includes teachers using slides, static ball and stick models, or computer-simulation software to present diagrams on a whiteboard. However, these methods do not adequately depict atomic interactions effectively, thus obscuring complex knowledge and understanding of their formulas and characteristics.
Project Activities: During Phase I (completed in 2014), the team developed a prototype of a physical modeling set including a computerized ball and stick molecular models representing the first 17 elements on the periodic table and an iPad app that identifies and generates information about atoms. A pilot study at the end of Phase I tested the prototype with 187 high school students in 12 chemistry classes. Researchers found that the prototype functioned as intended. Results showed that 88% of students enjoyed using the prototype, and that 79% indicated that it helped learning. In Phase II, the team will develop additional models and will strengthen functionality for effective integration into instructional practice. After development is complete, a larger pilot study will assess the usability and feasibility, fidelity of implementation, and promise of Happy Atoms to improve learning. The study will include 30 grade 11 chemistry classrooms, with half randomly assigned to use Happy Atoms and half who will continue with business as usual procedures. Analyses will compare pre-and-post scores of student's chemistry learning, including atomic modeling.
Product: Happy Atoms will include a set of physical models paired with an iPad app to cover high school chemistry topics in atomic modeling. The modeling set will include individual plastic balls representing the elements of the periodic table. Students will use an iPad app to take a picture of models they create. Using computer-generated algorithms, the app will then identify the model and generate information about its physical and chemical properties and uses. The app will also inform students if a model that is created does not exist. Happy Atoms will replace or supplement lesson plans to enhance chemistry teaching. The app will include teacher resources suggesting how to incorporate games and activities to reinforce lesson plans and learning.
This is the poster for the CCI Solar Fuels and Westside Science Club collaboration presented by Michelle Hansen and Benjamin Dickow at the 2014 AISL PI meeting in Washington DC.
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California Institute of Technology Center for Chemical InnovationMichelle Hansen
The Community STEM Outreach Project at the Saint Louis Science Center (SLSC) received funding from the United States Office of Naval Research (ONR) from October 2010 through September 2013. Klein Consulting, with support from Tisdal Consulting, conducted the evaluation of the three-year project. The original proposal from the SLSC to ONR laid the foundation for the Community STEM Outreach Project by describing the institution and its youth program, the Youth Exploring Science (YES) Program. Plans were underway to reach out to existing and new national partners to document and disseminate a
The National Federation of the Blind (NFB), with six science centers across the U.S., will develop, implement, and evaluate the National Center for Blind Youth in Science (NCBYS), a three-year full-scale development project to increase informal learning opportunities for blind youth in STEM. Through partnerships and companion research, the NCBYS will lead to greater capacity to engage the blind in informal STEM learning. The NCBYS confronts a critical area of need in STEM education, and a priority for the AISL program: the underrepresentation of people with disabilities in STEM. Educators are often unaware of methods to deliver STEM concepts to blind students, and students do not have the experience with which to advocate for accommodations. Many parents of blind students are ill-equipped to provide support or request accessible STEM adaptations. The NCBYS will expose blind youth to non-visual methods that facilitate their involvement in STEM; introduce science centers to additional non-visual methods that facilitate the involvement of the blind in their exhibits; educate parents as to their students' ability to be independent both inside and outside the STEM classroom; provide preservice teachers of blind students with hands-on experience with blind students in STEM; and conduct research to inform a field that is lacking in published material. The NCBYS will a) conduct six regional, two-day science programs for a total of 180 blind youth, one day taking place at a local science center; b) conduct concurrent onsite parent training sessions; c) incorporate preservice teachers of blind students in hands-on activities; and d) perform separate, week-long, advanced-study residential programs for 60 blind high school juniors and seniors focused on the design process and preparation for post-secondary STEM education. The NCBYS will advance knowledge and understanding in informal settings, particularly as they pertain to the underrepresented disability demographic; but it is also expected that benefits realized from the program will translate to formal arenas. The proposed team represents the varied fields that the project seeks to inform, and holds expertise in blindness education, STEM education, museum education, parent outreach, teacher training, disability research, and project management. The initiative is a unique opportunity for science centers and the disability population to collaborate for mutual benefit, with lasting implications in informal STEM delivery, parent engagement, and teacher training. It is also an innovative approach to inspiring problem-solving skills in blind high school students through the design process. A panel of experts in various STEM fields will inform content development. NCBYS advances the discovery and understanding of STEM learning for blind students by integrating significant research alongside interactive programs. The audience includes students and those responsible for delivering STEM content and educational services to blind students. For students, the program will demonstrate their ability to interface with science center activities. Students will also gain mentoring experience through activities paired with younger blind students. Parents and teachers of blind students, as well as science center personnel, will gain understanding in the experiences of the blind in STEM, and steps to facilitate their complete involvement. Older students will pursue design inquiries into STEM at a more advanced level, processes that would be explored in post-secondary pursuits. By engaging these groups, the NCBYS will build infrastructure in the informal and formal arenas. Society benefits from the inclusion of new scientific minds, resulting in a diverse workforce. The possibility for advanced study and eventual employment for blind students also reduces the possibility that they would be dependent upon society for daily care in the future. The results of the proposed project will be disseminated and published broadly through Web sites; e-mail lists; social media; student-developed e-portfolios of the design program; an audio-described video; and presentations at workshops for STEM educators, teachers of blind students, blind consumer groups, researchers in disability education, and museum personnel.
The Westside Science Club (WSSC) is an out-of-school time opportunity that brings participant-directed STEM activities to under-resourced late-elementary and middle school students in low-income housing units in Los Angeles. WSSC and CCI Solar began a collaboration in 2012 with funding from the NSF to connect research scientists from Caltech with the underserved youth in the club. Another community partner, Wildwood School, provided high school students to act as near-peer mentors for the club members. CCI Solar's research on the efficient and economical conversion of solar energy into stored chemical fuel provides an entry point for informal science education activities designed to introduce pre-high school participants to basic chemistry and related STEM concepts such as physics and plant biology. Activities were largely student driven, though lessons were developed by the team of facilitators including the club's founder Ben Dickow, Wildwood teacher Levi Simons, and students, post-docs, and staff from Caltech. Each lesson was tied to CCI Solar's research through a mind-map of related chemistry concepts. The activities were mostly intended to be "maker-type" experiences that allowed the club members to follow their own interests and questions. Caltech students and postdocs from CCI Solar helped deliver activities while honing their science communication skills with the young WSSC audience. The team is currently adapting the model of this successful collaboration to develop another science club in a different Los Angeles community. Two-years of lessons developed from this project, an evaluation of the project by Kimberly Burtnyk of Science for Society, and a model on how to replicate such a program are available in the project final report below. This was a two-year pilot program that was completed in July 2014.
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.
Chemistry in the Community (ChemCom) was designed to provide an attractive, open access route for all high school students to the realm of relevant and useful chemical phenomena. What began as a dream a few years ago is now a well-developed high school program brought about by the concerted efforts of high school teachers, college and university professors, and industrial chemists and financed by the National Science Foundation and the American Chemical Society. This three-year project is designed as a partnership to support the dissemination of the Chemcom curriculum. Specially selected teachers will be educated so that they can become resource teachers who will conduct ChemCom inservice workshops throughout the country. These resource teachers are expected to represent as many as 150 school systems and will reach as many as 2,000 teachers with their inservice programs. The project also includes a series of networking activities entitled "An Evening with ChemCom, the establishment of a computer network, and the production of a newsletter. The evaluation will focus on the effectiveness of this particular model for implementing curriculum change. The total cost sharing (ACS, Publisher, School Systems) is expected to be almost five times the NSF request.
Individuals are at an increased risk to drop out of the STEM pipeline if they are female or Latino, and during certain periods including high school. Families are a potential untapped resource of support for high school students. Based on the expectancy-value model, we examined if a variety of parental behaviors predicted students’ ability self-concepts in and value they placed on biology, chemistry, and physics. Self-report surveys were collected from 988 9th grade Latino boys, Latina girls, Caucasian boys, and Caucasian girls. The findings suggest that, as early as the beginning of high