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*{{Cite journal|last=Milliron|first=Delia J.|last2=Jaume Gazquez|last3=Garcia|first3=Guillermo|last4=Llordés|first4=Anna|date=2013|title=Tunable near-infrared and visible-light transmittance in nanocrystal-in-glass composites|url=https://www.nature.com/articles/nature12398|journal=Nature|language=en|volume=500|issue=7462|pages=323–326|doi=10.1038/nature12398|issn=1476-4687}}
*{{Cite journal|last=Milliron|first=Delia J.|last2=Jaume Gazquez|last3=Garcia|first3=Guillermo|last4=Llordés|first4=Anna|date=2013|title=Tunable near-infrared and visible-light transmittance in nanocrystal-in-glass composites|url=https://www.nature.com/articles/nature12398|journal=Nature|language=en|volume=500|issue=7462|pages=323–326|doi=10.1038/nature12398|issn=1476-4687}}
*{{Cite journal|last=Buonsanti|first=Raffaella|last2=Llordes|first2=Anna|last3=Aloni|first3=Shaul|last4=Helms|first4=Brett A.|last5=Milliron|first5=Delia J.|date=2011-11-09|title=Tunable Infrared Absorption and Visible Transparency of Colloidal Aluminum-Doped Zinc Oxide Nanocrystals|url=https://doi.org/10.1021/nl203030f|journal=Nano Letters|volume=11|issue=11|pages=4706–4710|doi=10.1021/nl203030f|issn=1530-6984}}
*{{Cite journal|last=Buonsanti|first=Raffaella|last2=Llordes|first2=Anna|last3=Aloni|first3=Shaul|last4=Helms|first4=Brett A.|last5=Milliron|first5=Delia J.|date=2011-11-09|title=Tunable Infrared Absorption and Visible Transparency of Colloidal Aluminum-Doped Zinc Oxide Nanocrystals|url=https://doi.org/10.1021/nl203030f|journal=Nano Letters|volume=11|issue=11|pages=4706–4710|doi=10.1021/nl203030f|issn=1530-6984}}
*{{Cite journal|last=J. Milliron|first=Delia|last2=D. Lounis|first2=Sebastien|last3=Llordés|first3=Anna|last4=L. Runnerstrom|first4=Evan|date=2014|title=Nanostructured electrochromic smart windows: traditional materials and NIR-selective plasmonic nanocrystals|url=https://pubs.rsc.org/en/content/articlelanding/2014/cc/c4cc03109a|journal=Chemical Communications|language=en|volume=50|issue=73|pages=10555–10572|doi=10.1039/C4CC03109A}}
*{{Cite journal|last=Milliron|first=Delia J.|last2=D. Lounis|first2=Sebastien|last3=Llordés|first3=Anna|last4=L. Runnerstrom|first4=Evan|date=2014|title=Nanostructured electrochromic smart windows: traditional materials and NIR-selective plasmonic nanocrystals|url=https://pubs.rsc.org/en/content/articlelanding/2014/cc/c4cc03109a|journal=Chemical Communications|language=en|volume=50|issue=73|pages=10555–10572|doi=10.1039/C4CC03109A}}
*{{Cite journal|last=Chan|first=Emory M.|last2=Xu|first2=Chenxu|last3=Mao|first3=Alvin W.|last4=Han|first4=Gang|last5=Owen|first5=Jonathan S.|last6=Cohen|first6=Bruce E.|last7=Milliron|first7=Delia J.|date=2010-05-12|title=Reproducible, High-Throughput Synthesis of Colloidal Nanocrystals for Optimization in Multidimensional Parameter Space|url=https://doi.org/10.1021/nl100669s|journal=Nano Letters|volume=10|issue=5|pages=1874–1885|doi=10.1021/nl100669s|issn=1530-6984}}
*{{Cite journal|last=Chan|first=Emory M.|last2=Xu|first2=Chenxu|last3=Mao|first3=Alvin W.|last4=Han|first4=Gang|last5=Owen|first5=Jonathan S.|last6=Cohen|first6=Bruce E.|last7=Milliron|first7=Delia J.|date=2010-05-12|title=Reproducible, High-Throughput Synthesis of Colloidal Nanocrystals for Optimization in Multidimensional Parameter Space|url=https://doi.org/10.1021/nl100669s|journal=Nano Letters|volume=10|issue=5|pages=1874–1885|doi=10.1021/nl100669s|issn=1530-6984}}
*{{Cite journal|last=Milliron|first=Delia J.|last2=Staller|first2=Corey M.|last3=Dahlman|first3=Clayton J.|last4=Reimnitz|first4=Lauren C.|last5=Shearer|first5=Alex B.|last6=Agrawal|first6=Ankit|last7=Zandi|first7=Omid|date=2018|title=Impacts of surface depletion on the plasmonic properties of doped semiconductor nanocrystals|url=https://www.nature.com/articles/s41563-018-0130-5|journal=Nature Materials|language=en|volume=17|issue=8|pages=710–717|doi=10.1038/s41563-018-0130-5|issn=1476-4660}}
*{{Cite journal|last=Milliron|first=Delia J.|last2=Staller|first2=Corey M.|last3=Dahlman|first3=Clayton J.|last4=Reimnitz|first4=Lauren C.|last5=Shearer|first5=Alex B.|last6=Agrawal|first6=Ankit|last7=Zandi|first7=Omid|date=2018|title=Impacts of surface depletion on the plasmonic properties of doped semiconductor nanocrystals|url=https://www.nature.com/articles/s41563-018-0130-5|journal=Nature Materials|language=en|volume=17|issue=8|pages=710–717|doi=10.1038/s41563-018-0130-5|issn=1476-4660}}
*{{Cite journal|last=Milliron|first=Delia J.|last2=Truskett|first2=Thomas M.|last3=Agrawal|first3=Ankit|last4=Lindquist|first4=Beth A.|last5=Jadrich|first5=Ryan B.|last6=Ong|first6=Gary K.|last7=Cabezas|first7=Camila A. Saez|date=2018-09-04|title=Gelation of plasmonic metal oxide nanocrystals by polymer-induced depletion attractions|url=https://www.pnas.org/content/115/36/8925|journal=Proceedings of the National Academy of Sciences|language=en|volume=115|issue=36|pages=8925–8930|doi=10.1073/pnas.1806927115|issn=0027-8424|pmc=6130341|pmid=30127030}}
*{{Cite journal|last=Milliron|first=Delia J.|last2=Truskett|first2=Thomas M.|last3=Agrawal|first3=Ankit|last4=Lindquist|first4=Beth A.|last5=Jadrich|first5=Ryan B.|last6=Ong|first6=Gary K.|last7=Saez Cabezas|first7=Camila A.|date=2018-09-04|title=Gelation of plasmonic metal oxide nanocrystals by polymer-induced depletion attractions|url=https://www.pnas.org/content/115/36/8925|journal=Proceedings of the National Academy of Sciences|language=en|volume=115|issue=36|pages=8925–8930|doi=10.1073/pnas.1806927115|issn=0027-8424|pmc=6130341|pmid=30127030}}


== Awards ==
== Awards ==

Revision as of 23:52, 22 June 2019

Delia J. Milliron is the T. Brockett Hudson Professor in Chemical Engineering at the University of Texas at Austin.[1] Milliron leads a research team that focuses on developing and studying the properties of new electronic nanomaterials.[2] Her team pursues studies on nanocrystals, nanoscale interfaces, and controlled assemblies of nanocrystals. Her team takes a systematic approach towards elucidating effects that arise at the nanoscale with a special focus on structure-property relationships.

Among many other topics, she is well known for her discoveries leading to development and innovation of technologies in the energy sciences. For her development of energy-efficient "smart window" coating technologies, Milliron is the co-founder and chief scientific officer of Heliotrope Technologies.[3]

Research and career

Delia Milliron
Alma materPrinceton University, University of California, Berkeley
Known forNanoscience, Materials science
Scientific career
FieldsChemistry and Chemical Engineering
InstitutionsUniversity of Texas at Austin
Doctoral advisorPaul Alivisatos

Delia Milliron (Markiewicz) received her A.B. in Chemistry and Materials Science and Engineering from Princeton University where she performed undergraduate research with Jeffrey Schwartz and Antoine Kahn. During her undergraduate research experiences (and internships), Milliron established an early publication record on techniques and topics spanning from magnetic force microscopy to polymer cross-linking. Milliron would go on to receive her Ph.D. in Physical Chemistry from UC Berkeley in the laboratory of Paul Alivisatos where her thesis was on "New materials for nanocrystal solar cells" (2004). Milliron's research during her early career was distinguished by studies on shape control of nanomaterials, charge transfer, and preparation of hybrid nanocrystal-polymer photovoltaic cells. After graduate school, Milliron held a post-doctoral research position at the IBM T.J. Watson Research Center and was then a research staff member at the IBM Almaden Research Center. At IBM, Milliron's publication record included studies on phase change nanomaterials and topics relevant to self-assembly of nanostructures. She also notably contributed to innovations in the field surrounding preparation of metal-chalcogen clusters and applications therof. In 2008, Milliron transitioned to Lawrence Berkeley National Lab where she led a research team as a Staff Scientist in the Inorganic Nanostructures Facility of the Molecular Foundry. Milliron served as the Deputy Directory of the Molecular Foundry at large from 2008 to 2012.[4] During her time at the Foundry, Milliron would continue to contribute to fundamental questions in nanoscience with technological impact. She contributed to advances in robotic nanocrystal synthesis through the development of WANDA with her then post-doc Emory Chan. And importantly for applications energy sciences, she began to explore topics relevant to innovations in window coating technology. Milliron's research continued to be distinguished by advancing fundamental knowledge in the field of nanoscience through studies on mixed ionic and electronic conductors, plasmonic nanocrystals, nanocrystal assemblies, and nanocrystal phase transitions. Milliron and her research group moved to UT Austin in 2014. In addition to her current faculty appointment at UT Austin, Milliron is a co-principal investigator for the Center for Dynamics and Control of Materials a National Science Foundation Materials Research Science and Engineering Center (MRSEC). As part of the MRSEC, Milliron is also the faculty co-leader for the internal research group on "Reconfigurable and Porous Nanoparticle Networks".[5]

Notable publications and patents

Milliron has been prolific in her publication record and also in technology impact of her research which has lead over 17 patents.[6] Listed below are some of her notable publications:

Awards

References

  1. ^ Us, Contact; Sitemap; Policy, Privacy; Accessibility, U. T.; Home, UT Austin; Twitter; Facebook; YouTube; LinkedIn. "Milliron, Delia Ph.D." McKetta Department of Chemical Engineering. Retrieved 2019-03-15. {{cite web}}: |last3= has generic name (help)
  2. ^ "Milliron Research Group - Home". nanocrystal.che.utexas.edu. Retrieved 2019-03-15.
  3. ^ Orcutt, Mike. "Why Don't We Have Smart Windows Yet?". MIT Technology Review. Retrieved 2019-03-15.
  4. ^ "Molecular Foundry". foundry.lbl.gov. Retrieved 2019-03-16.
  5. ^ "NSF Award Search: Award#1720595 - Center for Dynamics and Control of Materials". www.nsf.gov. Retrieved 2019-03-16.
  6. ^ "Delia J. Milliron Inventions, Patents and Patent Applications - Justia Patents Search". patents.justia.com. Retrieved 2019-03-18.
  7. ^ Us, Contact; Sitemap; Policy, Privacy; Accessibility, U. T.; Home, UT Austin; Twitter; Facebook; YouTube; LinkedIn (2017-12-12). "Milliron Receives TAMEST's 2018 O'Donnell Award in Engineering". McKetta Department of Chemical Engineering. Retrieved 2019-03-15. {{cite web}}: |last3= has generic name (help)
  8. ^ "UT Austin's Milliron Awarded O'Donnell Award". www.photonics.com. Retrieved 2019-03-15.
  9. ^ Us, Contact; Sitemap; Policy, Privacy; Accessibility, U. T.; Home, UT Austin; Twitter; Facebook; YouTube; LinkedIn (2017-03-01). "Delia Milliron to Receive 2017 Norman Hackerman Award". McKetta Department of Chemical Engineering. Retrieved 2019-03-15. {{cite web}}: |last3= has generic name (help)
  10. ^ "Dr. Delia J. Milliron". www.welch1.org. Retrieved 2019-03-15.
  11. ^ Us, Contact; Sitemap; Policy, Privacy; Accessibility, U. T.; Home, UT Austin; Twitter; Facebook; YouTube; LinkedIn (2016-02-23). "Delia Milliron Wins Prestigious Sloan Research Fellowship". McKetta Department of Chemical Engineering. Retrieved 2019-03-15. {{cite web}}: |last3= has generic name (help)
  12. ^ "Resnick | 2015 Winners". resnick.caltech.edu. Retrieved 2019-03-15.
  13. ^ "Berkeley Lab scientists win four DOE Early Career Research grants | Berkeley Lab". News Center. 2010-01-15. Retrieved 2019-03-16.
  14. ^ Chao, Julie (2013-07-08). "Berkeley Lab Wins Eight 2013 R&D 100 Awards | Berkeley Lab". News Center. Retrieved 2019-03-15.
  15. ^ "A "Smart" Solution to Thermal Gain R&D 100 Conference". www.rd100conference.com. Retrieved 2019-03-16.
  16. ^ "ARPA-E award helps Berkeley Lab groups shine smart windows tech". The American Ceramic Society. 2012-12-07. Retrieved 2019-03-16.
  17. ^ "2010 MDV Innovators Award Winners Announced". CITRIS and the Banatao Institute. 2009-12-17. Retrieved 2019-03-16.
  18. ^ "Berkeley Lab Wins Four 2009 R&D 100 Awards | Berkeley Lab". News Center. 2009-07-20. Retrieved 2019-03-16.