Difference between revisions of "Federal Grant Data"

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Each year can be downloaded from: [https://www.nsf.gov/awardsearch/download.jsp https://www.nsf.gov/awardsearch/download.jsp]
 
Each year can be downloaded from: [https://www.nsf.gov/awardsearch/download.jsp https://www.nsf.gov/awardsearch/download.jsp]
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Data is located in:
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  E:\McNair\Projects\Federal Grant Data\NSF
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   <rootTag>
 
   <rootTag>

Revision as of 18:15, 24 January 2017

General

Finding NIH, NSF, and other federal grant data

NSF Grant Data

The NSF grant data are in folders by year, each grant is an xml file. The format of a typical file is shown below.

Each year can be downloaded from: https://www.nsf.gov/awardsearch/download.jsp

Data is located in:

 E:\McNair\Projects\Federal Grant Data\NSF


 <rootTag>
 <Award>
 <AwardTitle>
 Collaborative Research: Hybrid Organic-Inorganic Thermoelectric Materials
 </AwardTitle>
 <AwardEffectiveDate>08/31/2016</AwardEffectiveDate>
 <AwardExpirationDate>06/30/2017</AwardExpirationDate>
 <AwardAmount>95461</AwardAmount>
 <AwardInstrument>
 <Value>Standard Grant</Value>
 </AwardInstrument>
 <Organization>
 07030000
 <Directorate>
 <LongName>Directorate For Engineering</LongName>
 </Directorate>
 <Division>
 <LongName>Div Of Civil, Mechanical, & Manufact Inn</LongName>
 </Division>
 </Organization>
 <ProgramOfficer>
 <SignBlockName>Thomas F. Kuech</SignBlockName>
 </ProgramOfficer>
 <AbstractNarration>
 Thermoelectric materials are materials which can be used to convert thermal energy directly to electricity. The performance of a thermoelectric material is measured by the "figure of merit", termed ZT. There has been much research into increasing thermoelectric materials, figure of merit, however, progress in this area has been slow and most of the researched thermoelectric materials up to now are suffering from either high fabrication cost, usage of rare earth or toxic elements, or poor mechanical properties. Organic thermoelectric materials (OTEs) have recently attracted attention for low temperature applications (< 300K), especially cooling purposes, as they are flexible, low-cost and abundant, and low-cost fabrication methods for synthesizing them exist... A large class of semiconducting nanostructures (e.g. Si, CdTe, Bi, and PbTe nanowires and holely structures) combined with conjugated polymers (e.g., chemically-modified PEDOT and low bandgap polymers) and organic molecules (specifically charged chemical species attached to molecules such as CF3- substituted styrene molecules) will be simulated, synthesized and optimized to identify new hybrid materials with a potentially high ZT.
 </AbstractNarration>
 <MinAmdLetterDate>12/22/2016</MinAmdLetterDate>
 <MaxAmdLetterDate>12/22/2016</MaxAmdLetterDate>
 <ARRAAmount/>
 <AwardID>1723353</AwardID>
 <Investigator>
 <FirstName>Mona</FirstName>
 <LastName>Zebarjadi</LastName>
 <EmailAddress>mz6g@virginia.edu</EmailAddress>
 <StartDate>12/22/2016</StartDate>
 <EndDate/>
 <RoleCode>Principal Investigator</RoleCode>
 </Investigator>
 <Institution>
 <Name>University of Virginia Main Campus</Name>
 <CityName>CHARLOTTESVILLE</CityName>
 <ZipCode>229044195</ZipCode>
 <PhoneNumber>4349244270</PhoneNumber>
 <StreetAddress>P.O. BOX 400195</StreetAddress>
 <CountryName>United States</CountryName>
 <StateName>Virginia</StateName>
 <StateCode>VA</StateCode>
 </Institution>
 <ProgramElement>
 8092
 <Text>Materials Eng. & Processing</Text>
 </ProgramElement>
 <ProgramReference>
 024E
 <Text>MATERIALS DESIGN</Text>
 </ProgramReference>
 <ProgramReference>
 036E
 <Text>CIVIL INFRASTRUCTURE</Text>
 </ProgramReference>
 </Award>
 </rootTag>