Our publications
Vapor deposition rate modifies anisotropic glassy structure of an anthracene-based organic semiconductor." The Journal of Chemical Physics. 156 (2022).
"Stable Glasses of Organic Semiconductor Resist Crystallization." Journal of Physical Chemistry B. 125.1 (2021): 461-466.
"Surface equilibration mechanism controls the molecular packing of glassy molecular semiconductors at organic-organic interfaces." PNAS. 118.42 (2021).
"Using Deposition Rate and Substrate Temperature to Manipulate Liquid Crystal-Like Order in a Vapor-Deposited Hexagonal Columnar Glass." Journal of Physical Chemistry B. 125.10 (2021): 2761-2770.
"Molecular Orientation for Vapor-Deposited Organic Glasses Follows Rate-Temperature Superposition: The Case of Posaconazole." Journal of Physical Chemistry B. 124.12 (2020): 2505-2513.
"Over What Length Scale Does an Inorganic Substrate Perturb the Structure of a Glassy Organic Semiconductor." ACS Applied Materials and Interfaces. 12.23 (2020): 26717-26726.
"Physical vapor deposition of a polyamorphic system: Triphenyl phosphite." The Journal of Chemical Physics. 153.12 (2020).
"Effect of molecular size and hydrogen bonding on three surface-facilitated processes in molecular glasses: Surface diffusion, surface crystal growth, and formation of stable glasses by vapor deposition." Journal of Chemical Physics. 150.2 (2019).
"Generic packing motifs in vapor-deposited glasses of organic semiconductors." Soft Matter. 15.38 (2019).
"Origin of Anisotropic Molecular Packing in Vapor-Deposited Alq3 Glasses." Journal of Physical Chemistry Letters. 10 (2019).
"Vapor deposition of a nonmesogen prepares highly structured organic glasses." Proceedings of the National Academy of Sciences of the United States of America (2019).
"Vapor deposition of a nonmesogen prepares highly structured organic glasses." Proceedings of the National Academy of Sciences of the United States of America (2019).
"Vapor-Deposited Glass Structure Determined by Deposition Rate–Substrate Temperature Superposition Principle." Journal of Physical Chemistry Letters. 10 (2019).
"Glasses of three alkyl phosphates show a range of kinetic stabilities when prepared by physical vapor deposition." Journal of Chemical Physics. 148 (2018).
"Organic Glasses with Tunable Liquid-Crystalline Order." Physical Review Letters. 120.5 (2018).
"Tenfold increase in the photostability of an azobenzene guest in vapor-deposited glass mixtures." Journal of Chemical Physics. 149.20 (2018).
"Highly Organized Smectic-like Packing in Vapor-Deposited Glasses of a Liquid Crystal." Chemistry of Materials.29 (2017).
"Limited surface mobility inhibits stable glass formation for 2-ethyl-1-hexanol." Journal of Chemical Physics.146 (2017).
"Vapor-Deposited Glasses with Long-Range Columnar Liquid Crystalline Order." Chemistry of Materials. 29 (2017).
"Glass transition and stable glass formation of tetrachloromethane." The Journal of Chemical Physics. 144 (2016).
"Glass transition and stable glass formation of tetrachloromethane." The Journal of Chemical Physics. 144 (2016).
"Vapor-deposited alcohol glasses reveal a wide range of kinetic stability." Journal of Chemical Physics. 145 (2016).
"How much time is needed to form a kinetically stable glass? AC calorimetric study of vapor-deposited glasses of ethylcyclohexane." Journal of Chemical Physics. 142 (2015).
"Kinetic stability and heat capacity of vapor-deposited glasses of o-terphenyl." Journal of Chemical Physics. 143 (2015).
"Structural Characterization of Vapor-Deposited Glasses of an Organic Hole Transport Material with X-ray Scattering." Chemistry of Materials. 27.9 (2015).
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