Tag Archives: Funding

Science, Engineering and Math Fellowships

I work at the American Society for Engineering Education as an Information Technology Program Manager (this blog is not affiliated with ASEE). A large portion of the computer applications I work on are related to the science and engineering fellowships we administer. The fellowship applications are all open now (for certain fields the NSF application deadline is next week). Those fellowships include:

National Science Foundation Graduate Research Fellowship has the earliest deadline, starting November 3rd for some while some fields are as late as November 12th. The fellowship provides support for 3 years (a yearly stipend of $30,000 plus educational expense) to approximately 1,000 students and is open to most science, engineering and math fields.
National Defense Science and Engineering Graduate Fellowship applications are accepted until January 5th, 2009. 200 students receive $31,000 for 3 years plus educational expenses.
Science, Mathematics And Research for Transformation Scholarship for Service Program is another Department of Defense fellowship with a deadline of December 15th, 2008. This program offers awards to 200 science and engineering undergraduate and graduate students with awards between $25,000 and $41,000 a year as well as education expenses, health insurance, internships and employment placement after graduation.
NASA Aeronautics Scholarship offers 20 two-year undergraduate scholarships and 5 two-year graduate scholarships to students in Aeronautics and related fields. The deadline is January 16th, 2009.

Other scholarships and fellowships (these are not managed by ASEE): Gates Millennium Scholars Program (January 12th deadline) – NASA Graduate Student Researchers (February 1st) – Goldwater Science Scholarships (January 30th)

NIH Punished Scientist Who Called for Open Records

NIH Punished Scientist Who Had Called for Open Records

The National Institutes of Health and some leading universities, such as Harvard and Stanford, have suffered black eyes this year because of revelations that researchers with federal grants failed to disclose secret payments that they took from pharmaceutical companies.

The NIH was warned about the dangers of the problem years ago by one of its own scientists, Ned Feder, who wrote letters to several publications suggesting that the agency require its grantees to publicly disclose money they earn from medical companies. Instead of heeding Dr. Feder’s advice, the agency punished him
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Dr. Feder went on to suggest that “the NIH could require grantees to make public disclosures of their paid arrangements with pharmaceutical, investment, and other companies, as well as their ownership of stock and stock options, as a condition of having their medical research funded by the government.”

The agency formally reprimanded Dr. Feder for writing to Nature and identifying himself in the letter as an employee of the NIH. Dr. Feder protested the reprimand, and it was subsequently removed, without explanation.
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“The NIH has shown no interest in reforming its policies unless they’re forced to do it,” said Dr. Feder, who is now staff scientist at the Project on Government Oversight.

Silk E.coli Sensors

“Edible Optics” Could Make Food Safer

Scientists at Tufts University’s School of Engineering have demonstrated for the first time that it is possible to design such “living” optical elements that could enable an entirely new class of sensors. These sensors would combine sophisticated nanoscale optics with biological readout functions, be biocompatible and biodegradable, and be manufactured and stored at room temperatures without use of toxic chemicals. The Tufts team used fibers from silkworms to develop the platform devices.
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The possibility of integrating optical readout and biological function in a single biocompatible device unconstrained by these limitations is tantalizing. Silk optics has captured the interest of the Defense Department, which has funded and been instrumental in enabling rapid progress on the topic. The Defense Advanced Research Projects Agency (DARPA) awarded Tufts a research contract in 2007 and is funding Tufts and others on groundbreaking projects that could someday result in biodegradable optical sensing communications technology.
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To form the devices, Tufts scientists boiled cocoons of the Bombyx mori silkworm in a water solution and extracted the glue-like sericin proteins. The purified silk protein solution was ultimately poured onto negative molds of ruled and holographic diffraction gratings with spacing as fine as 3600 grooves/mm.
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The Tufts team embedded three very different biological agents in the silk solution: a protein (hemoglobin), an enzyme (horseradish peroxidase) and an organic pH indicator (phenol red). In the hardened silk optical element, all three agents maintained their activity for long periods when simply stored on a shelf. “We have optical devices embedded with enzymes that are still active after almost a year of storage at room temperature.

Stanford Gets $75 Million for Stem Cell Center

Stanford gets $75 million for stem cell center

With today’s announcement, Lokey more than doubles his commitment. School officials say he is the lead contributor for a $200 million stem cell research building that will break ground Oct. 27 and be finished in the summer of 2010. In a statement released by the medical school, Lokey said stem cells would be “as significant as the silicon chip that created Silicon Valley,” producing treatments for disease and saving lives.

He said he was driven to fund research after President Bush, in August 2001, forbid the use of federal funds for stem cell research that involved the destruction of human embryos. “It’s very narrow-minded,” Lokey said of the position. “This is about lives being saved.”
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Some 350 scientists will work in the 200,000-square-foot Lorry I. Lokey Stem Cell Research Building, the school said. The center is also getting a $43.6 million grant from the California Institute for Regenerative Medicine. The institute, the state’s $3 billion stem cell funding unit, was created by a 2004 state initiative from research advocates opposed to Bush’s restrictions.

$92 Million for Engineering Research Centers

photo of Alex Huabg

NSF Launches Third Generation of Engineering Research Centers with Awards Totaling $92.5 Million. Each of the 5 sites will receive will use $18.5 million over five-years. Each center has international university partners and partners in industry.

The NSF Engineering Research Center for Biorenewable Chemicals (CBiRC), based at Iowa State University, seeks to transform the existing petrochemical-based chemical industry to one based on renewable materials.

The NSF Engineering Research Center for Future Renewable Electric Energy Delivery and Management (FREEDM) Systems, based at North Carolina State University, will conduct research to transform the nation’s power grid into an efficient network that integrates alternative energy generation and new storage methods with existing power sources.

The NSF ERC for Integrated Access Networks (CIAN), based at the University of Arizona, will conduct research to create transformative technologies for optical access networks that offer dramatically improved performance and expanded capabilities.

The NSF ERC for Revolutionizing Metallic Biomaterials, based at North Carolina Agricultural and Technical State University, aims to transform current medial and surgical treatments by creating “smart” implants for craniofacial, dental, orthopedic and cardiovascular interventions.

The NSF Smart Lighting ERC, based at Rensselaer Polytechnic Institute, aims to create new solid-state lighting technologies to enable rapid biological imaging, novel modes of communication, efficient displays and safer transportation.

Photo: Alex Huang will lead direct the research of ways to integrate renewable energy sources into the nation’s power grid at North Carolina State University.

$400 Million More for Harvard and MIT

$400 million endowment for the Broad Institute of Harvard and MIT

“Today the Broad Institute is the world’s leading genomics and biomedical institute, and we’re now making a $600 million bet that the Broad will be the place where the greatest scientific discoveries take place,” Eli Broad said at today’s ceremony.
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In its short history, the Broad Institute’s accomplishments include cataloging and identifying genetic risk factors for diseases such as type 2 diabetes and autism; discovering new therapeutic targets for cancer, malaria, and other diseases; and applying genomic tools to better understand and treat human pathogens like tuberculosis.
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The Broads’ gift is the largest to support biomedical research at a university anywhere in the world. The Broads initially invested $100 million in 2003 as a way to test the institute’s new approach to biomedical research. By 2005, the Broad Institute had already made significant accomplishments and progress, and the Broads invested a second $100 million. Their endowment of $400 million today will allow the Broad Institute to transition to a permanent, non-profit 501(c)(3) organization with both Harvard and MIT still at the heart of it, continuing to help govern the institute.

Many countries would love to create a world class center of biomedical research. And several are trying. Boston sure seems to be staking a claim that it will be one of those centers of excellence. The economic benefits of that to Boston will be huge.

2008 MacArthur Fellows

photos of Kirsten Bomblies, Marin Soljacic, Rachel Wilson and Andrea Ghez

MacArthur Fellows receive $500,000 is support over 5 years with no strings attached. Unfortunately for me, I was passed over again. However, 25 people have been selected including

Kirsten Bomblies, Max Planck Institute for Developmental Biology, Tubingen, Germany. Plant Evolutionary Geneticist opening avenues into the mysteries of how new species originate through her explorations of incompatible hybrids as a mechanism for speciation in shared ecological niches.

Marin Soljacic, Massachusetts Institute of Technology, Cambridge, Massachusetts. Optical Physicist demonstrating both theoretically and experimentally that power can be transmitted wirelessly, potentially leading to a range of electrical devices that can operate without batteries or wall connections.

Rachel Wilson, Harvard Medical School, Boston, Massachusetts. Experimental Neurobiologist integrating electrophysiology, neuropharmacology, molecular genetics, and anatomy to measure the activity of neurons in the diminutive brain of the fruit fly.

Andrea Ghez, University of California Los Angeles, Los Angeles, California. Astrophysicist using novel, ground-based telescopic techniques to identify thousands of new star systems and illuminate the role of super-massive black holes in the evolution of galaxies.

Photos, from the MacArthur Foundation web site left to right Kirsten Bomblies, Marin Soljacic, Rachel Wilson and Andrea Ghez.

2008 Innovation Generation Grants

The Motorola Foundation today announced the recipients of its 2008 Innovation Generation grants, which provide $4 million to 92 K-12 education programs across the country.

Eileen Sweeney, director of the Motorola Foundation: “Building a diverse pipeline of critical thinkers, skilled scientists and engineers is a by-product of our efforts that not only will benefit Motorola and our industry, but it also will support a sustainable workforce and bolster the country’s competitive advantage in the global, knowledge-based economy.”

According to the Bureau of Labor Statistics, Strengthening Education: Meeting the Challenge of a Changing World, jobs requiring science, engineering or technical training will increase 24 percent between 2004 and 2014 to 6.3 million. The disparity between the growing demand for critical thinkers and the country’s ability to adequately prepare students to fill these jobs has been widening for decades. The lack of skilled graduates in these fields poses a significant threat to sustained U.S. competitiveness in the global, knowledge-intensive economy.

Examples of this year’s grant recipients include:

* American Indian Science and Engineering Society (AISES) – The AISES National American Indian Science and Engineering Fair and Expo inspires American Indian and Alaska Native students from all 50 states to pursue their interest in science and engineering through in-person and virtual presentations of research, access to role models and mentors, and hands-on demonstrations of scientific and engineering innovations across industries.

* Edheads in Columbus, Ohio – A highly interactive website for middle school girls interested in engineering design will be used nationally by schools and after-school programs.

* Rochester Institute of Technology – TechGirlz weeklong camp for girls who are deaf and hard-of-hearing and entering seventh, eighth or ninth grades fosters their long-term interest in STEM and enhances their awareness of the opportunities available to them in these disciplines in higher education.

* University of Central Florida – My Sports Pulse engages Florida middle school and high school students in a youth mobile learning initiative that imparts science and technology concepts through interactive sports games and tests.

Symptom of America’s Decline in Particle Physics

Land Of Big Science

Probing more deeply than ever before into the stuff of the universe requires some big hardware. It also requires the political will to lavish money on a project that has no predictable practical return, other than prestige and leadership in the branch of science that delivered just about every major technology of the past hundred years.

Those advances came, in large measure, from the United States. The coming decades may be different.
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A third of the scientists working at the LHC hail from outside the 20 states that control CERN. America has contributed 1,000 or so researchers, the largest single contingent from any non-CERN nation.
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The U.S. contribution amounts to $500 million—barely 5 percent of the bill. The big bucks have come from the Europeans. Germany is picking up 20 percent of the tab, the British are contributing 17 percent, and the French are giving 14 percent.
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The most worrying prospect is that scientists from other countries, who used to flock to the United States to be where the action is, are now heading to Europe instead.

This is a point I have made before. The economic benefits of investing in science are real. The economic benefits of having science and engineering centers of excellence in your country are real. That doesn’t mean you automatically gain economic benefit but it is a huge advantage and opportunity if you act intelligently to make it pay off.

MIT International Science and Technology Initiatives

MIT is providing seed funding to faculty to encourage global research. The seed funds cover a variety of expenses, including exploratory field research, workshop materials and instrument costs. Each proposal is eligible for up to $20,000 in funding. Research and collaboration can take place anywhere in the world on any topic. For all projects, up to $10,000 in additional funding is available for undergraduate and graduate student participation.

MISTI country programs also offer five country-specific seed funds for collaborative research involving France, India, Italy, Japan or Spain.

This is a good use of their huge endowment. So is the Open Courseware initiative. As is their elimination of tuition for those with families earning less than $75,000. Good for MIT.