She moved to the
University of Florida as an associate professor in 1993 and was promoted to Professor in 1997. Following a term as Associate Dean for Administrative Affairs in the College of Liberal Arts and Sciences, she returned to full-time conducting research and teaching in 1998. She currently serves as director of the UF Beckman Scholars Program and recently served as the Director of the NSF-CCI Center for Nanostructured Electronic Materials. Professor McElwee-White's current research interests center around the applications of
organometallic chemistry in materials science.
Her work has been funded by a variety of federal agencies, foundations, and private companies including NSF, DOE, ARO, ONR, NASA, ACS-PRF, the Beckman Foundation, HHMI and FEI. She has authored more than 140 peer-reviewed publications and has presented more than 180 invited lectures. Her Editorial Board service includes Organometallics, the
Journal of Organic Chemistry, Letters in Organic Chemistry and Current Organic Chemistry. She has recently served as Chair of the Division of Organic Chemistry of the American Chemical Society and was named as a Fellow of the American Chemical Society in 2010. Her recent awards include the Florida Award (2015) and the Charles H. Stone Award (2012).
Research
Chemical Vapor Deposition
Chemical Vapor Deposition (CVD) is a technique that produces materials by depositing solid films. It has been a very attractive process because it is chemically selective process, the material produced is high-quality and high-performing, and the thickness of the film can be easily controlled.[1]
McElwee-White has studied the various complexities of CVD on
tungsten nitride and carbonitride films (WNxCy films), exploring tungsten nitrido complexes as precursors[2][3] and analyzing the effect of ligand structure on the reaction.[4] She has also expanded her research scope to the metallization of organic thin films. For the process of metallization of organic thin films, normal thermal CVD processes which require high temperatures usually destroy organic films. McElwee-White introduced
photochemical CVD processes as an alternative, and employed ruthenium-based precursors.[5]
Electron Beam-Induced Deposition
Electron beam-induced deposition (EBID) uses a high energy, focused electron beam to deposit
nanomaterials onto a surface using organometallic precursors. It is useful because it is able to produce three-dimensional nanostructures with well-controlled size, shape and interparticle distance.[6] McElwee-White has explored EBID using a variety of organometallic precursors, such as cis-Pt(CO)2Cl2 to make pure
platinum nanostructures[7] and (η3-C3H5)Ru(CO)3Br to make Ru-based
nanostructures and to study the effects of
ligands.[7][8]
McElwee-White enjoys playing the
flute. She was able to perform in several concerts such as the “Lobby Concert” and the “Flute Choir Showcase” with the Gainesville Flute Ensemble in the 32nd Annual Convention of the
National Flute Association in August 2004.[citation needed]
Another hobby that she has is
horseback riding. She owns several horses on her property that she loves to ride on during her free time.[citation needed]
^
abMcElwee-White, Lisa (2006-11-13). "Design of precursors for the CVD of inorganic thin films". Dalton Transactions (45): 5327–5333.
doi:
10.1039/B611848H.
ISSN1477-9234.
PMID17102856.
^
abMcClain, K. Randall; O’Donohue, Christopher; Koley, Arijit; Bonsu, Richard O.; Abboud, Khalil A.; Revelli, Joseph C.; Anderson, Timothy J.; McElwee-White, Lisa (2014). "Tungsten Nitrido Complexes as Precursors for Low Temperature Chemical Vapor Deposition of WNxCyFilms as Diffusion Barriers for Cu Metallization". Journal of the American Chemical Society. 136 (4): 1650–1662.
doi:
10.1021/ja4117582.
PMID24383494.
^
abKoley, Arijit; O’Donohue, Christopher T.; Nolan, Michelle M.; McClain, K. Randall; Bonsu, Richard O.; Korotkov, Roman Y.; Anderson, Tim; McElwee-White, Lisa (2015-12-22). "Effect of the Ligand Structure on Chemical Vapor Deposition of WNxCy Thin Films from Tungsten Nitrido Complexes of the Type WN(NR2)3". Chemistry of Materials. 27 (24): 8326–8336.
doi:
10.1021/acs.chemmater.5b03691.
ISSN0897-4756.
^
abJohnson, Kelsea R.; Arevalo Rodriguez, Paul; Brewer, Christopher R.; Brannaka, Joseph A.; Shi, Zhiwei; Yang, Jing; Salazar, Bryan; McElwee-White, Lisa; Walker, Amy V. (2017-02-07). "Photochemical CVD of Ru on functionalized self-assembled monolayers from organometallic precursors". The Journal of Chemical Physics. 146 (5): 052816.
Bibcode:
2017JChPh.146e2816J.
doi:
10.1063/1.4971434.
ISSN1089-7690.
PMID28178809.
^
abSpencer, Julie A.; Rosenberg, Samantha G.; Barclay, Michael; Wu, Yung-Chien; McElwee-White, Lisa; Fairbrother, D. Howard (2014-12-01). "Understanding the electron-stimulated surface reactions of organometallic complexes to enable design of precursors for electron beam-induced deposition". Applied Physics A. 117 (4): 1631–1644.
Bibcode:
2014ApPhA.117.1631S.
doi:
10.1007/s00339-014-8570-5.
ISSN0947-8396.
S2CID53503634.
^
abThorman, Rachel M.; Brannaka, Joseph A.; McElwee-White, Lisa; Ingólfsson, Oddur (2017-05-24). "Low energy electron-induced decomposition of (η3-C3H5)Ru(CO)3Br, a potential focused electron beam induced deposition precursor with a heteroleptic ligand set". Physical Chemistry Chemical Physics. 19 (20): 13264–13271.
Bibcode:
2017PCCP...1913264T.
doi:
10.1039/C7CP01696D.
ISSN1463-9084.
PMID28492652.
^Spencer, Julie A.; Brannaka, Joseph A.; Barclay, Michael; McElwee-White, Lisa; Fairbrother, D. Howard (2015-07-09). "Electron-Induced Surface Reactions of η3-Allyl Ruthenium Tricarbonyl Bromide [(η3-C3H5)Ru(CO)3Br]: Contrasting the Behavior of Different Ligands". The Journal of Physical Chemistry C. 119 (27): 15349–15359.
doi:
10.1021/acs.jpcc.5b03775.
ISSN1932-7447.