Even as he was accepting the prestigious Carnegie Foundation Massachusetts Teacher of the Year award in Washington, D.C., last November, Michael Barnett was eager to get back to 艾可直播. One of his singular hands-on science education programs鈥攖eaching public high school students to grow hydroponic fruits and vegetables and then sell them at farmers鈥 markets in underserved areas of the city鈥攈ad launched the day before.
Barnett and his 艾可直播 College colleagues are using his recently awarded $1.2 million National Science Foundation (NSF) grant to implement and study the impact of a hydroponic farming project, using solar panels and windmills to help power the indoor gardens at 艾可直播鈥檚 Salvation Army Kroc Center. The project, 鈥淪eeding the Future: Creating a Green Collar Workforce,鈥 is funded through the NSF鈥檚 Innovative Technology Experiences for Students and Teachers (ITEST) program and will engage approximately 1,000 students and 40 to 60 teachers at 20 schools.
Barnett, an associate professor at the Lynch School of Education, specializes in using innovative research projects to pique and sustain interest in science, technology, engineering, and mathematics (STEM) among college undergraduates and students attending urban high schools. Over the past decade, he and fellow 艾可直播 College researchers have received close to $10 million in external funding, mostly from the NSF. In the 2012鈥13 academic year alone, the NSF awarded Barnett a total of $1.65 million to support programs that bring STEM subjects and research skills to undergradu- ates who aren鈥檛 science majors, to teachers, and to high school students in the Lynch School鈥檚 College Bound academic enrichment and support program serving public high schools in the city of 艾可直播.
As he introduces students to research, Barnett conducts his own, gathering data while he explores new ways to teach science. In the process, he discovers what draws and engages students who tend to shy away from the subject, and studies how to attract high school and first-generation college students to STEM study.
Barnett and a group of undergraduate researchers used state-of-the-art Air Quality Eggs鈥攄o-it-yourself air-pollution sensors鈥攁nd touch-screen technology to measure air-quality data and share it with a network of interested community members in 艾可直播 neighborhoods. In another program, Barnett and a group of students in the College Bound program used special software to collaborate with a community development corporation to create a master plan for an underused parcel of urban land.
Projects such as the hydroponic farming program at the Kroc Center鈥攇rowing food indoors using mineral nutrient solutions dissolved in water鈥攙ividly illustrate Barnett鈥檚 approach to science education. When students grow their own food, he says, they aren鈥檛 just using applied chemistry, physics, biology, and economics and learning about the optimum amounts of sunlight, water, and nutrients their plants need to flourish. They are also tackling the larger societal problem of 鈥渇ood deserts鈥濃攁reas lacking access to full-service grocery stores鈥攊n their own lower-income neighborhoods. As part of the program, they explore reasons there are so few grocery stores in some urban areas, research the best locations in which to market their products, and learn the basics of social entrepreneurship as they craft and run a community-focused business.
Social entrepreneurship鈥攊dentifying novel ways of addressing a pressing social need鈥攊s a focal point of Barnett鈥檚 work with College Bound students, he says. In learning what it means to be an entrepreneur, students acquire new skills they can apply to solving problems鈥攐r creating their own jobs. 鈥淭oday, the ability to create your own job is really the only kind of job security that remains in our economic system,鈥 Barnett says.
Barnett鈥檚 research reveals that urban high school students who understand the science of growing their own food are more likely to develop not only critical thinking and analytical skills but also an interest in science and healthier eating habits. The hands-on programs and research are all part of Barnett鈥檚 attempt to plug what he calls the 鈥渓eaky STEM pipeline鈥濃攖he dwindling interest of high school students in science, technology, engineering, and math as the subjects get more intense and complicated. Barnett says he is particularly interested in learning how students work through barriers and solve tough problems as they pursue science research. He tries to counter an inclination he says he has observed during student interviews: the students鈥 tendency to assume they simply can鈥檛 do any kind of advanced science work and that science is only for 鈥渟mart鈥 people.
Barnett says his research analyzing how his programs affect high school students has yielded promising results. Student engagement, frequently modest during the difficult first year of a project, rises dramatically in each subsequent year students spend in the program as they become interested in science linked to family, community, and social issues that matter to them. Slightly more than half the College Bound students who have participated in Barnett鈥檚 experiments over the years have gone on to study STEM-related subjects in college; three College Bound alumni鈥攁ll of them students of color鈥攈ave become Gates Scholars, receiving full college tuition scholar- ships to the schools of their choice.
Barnett鈥檚 overall goal for his students? 鈥淟et鈥檚 build a generation of role models,鈥 he says. Although he鈥檚 a first-generation college student himself, he suspects students may not necessarily take notice if he shares his own story of what studying science has meant to him. 鈥淏ut if [it鈥檚] another person from their neighborhood, who has done it and been successful鈥攖hat means a lot.鈥