Marie K. Mapes scite author profile

Vapor deposition has been used to create glassy materials with extraordinary thermodynamic and kinetic stability and high density. For glasses prepared from indomethacin or 1,3-bis-(1-naphthyl)-5-(2-naphthyl)benzene, stability is optimized when deposition occurs on substrates at a temperature of 50 K below the conventional glass transition temperature. We attribute the substantial improvement in thermodynamic and kinetic properties to enhanced mobility within a few nanometers of the glass surface during deposition. This technique provides an efficient means of producing glassy materials that are low on the energy landscape and could affect technologies such as amorphous pharmaceuticals.

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Self-Diffusion of Supercooled o-Terphenyl near the Glass Transition Temperature

Mapes

2005

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Self-diffusion coefficients for the low molecular weight glass former o-terphenyl have been measured near Tg by isothermally desorbing thin film bilayers of deuterio and protio o-terphenyl in a vacuum chamber. We observe translational diffusion that is about 100 times faster at Tg + 3 K than the Stokes-Einstein prediction. Predictions from random first order transition theory and a dynamic facilitation approach are in reasonable agreement with our results; in these approaches, enhanced translational diffusion is associated with spatially heterogeneous dynamics. Self-diffusion controls crystallization in o-terphenyl for most of the supercooled liquid regime, but at temperatures below Tg + 10 K, the reported crystallization rate increases suddenly while the self-diffusion coefficient does not. This work and previous work on trisnaphthylbenzene both find a self-diffusion-controlled crystal growth regime and an enhancement in self-diffusion near Tg, suggesting that these phenomena are general characteristics of fragile low molecular weight glass formers. We discuss the width of the relaxation time distributions of o-terphenyl and trisnaphthylbenzene as they relate to the observation of enhanced translational diffusion.

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Highly Conductive Siloxane Polymers

Hooper

Lyons²,

Mapes³

et al. 2001

Macromolecules

132

116

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A series of double-comb, disubstituted polysiloxane polymers have been prepared containing oligoethylene oxide units, CH3(OCH2CH2) n (CH2)3−, in the side chains. These polymers were doped with LiN(SO2CF3)2 (LiTFSI, 1), and conductivities of the polymer-salt complexes were determined as a function of temperature and doping level. Conductivities increase with n up to n = 6 and then decrease. The maximum conductivity of the polymer with n = 6 at 25 °C was 4.5 × 10-4, the highest value yet recorded for a lithium-doped polymer electrolyte.

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Neutron reflectivity measurements of the translational motion of tris(naphthylbenzene) at the glass transition temperature

Swallen

Mapes

Kim

et al. 2006

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The translational dynamics of the low molecular weight glass-former tris(naphthylbenzene) have been studied on the length scale of a few nanometers at the glass transition temperature Tg. Neutron reflectivity was used to measure isotopic interdiffusion of multilayer samples created by physical vapor deposition. Deposition with the substrate held at Tg-6 K allows observation of dynamics characterizing the equilibrium supercooled liquid. The diffusion coefficient measured at q = 0.03 A(-1) was determined to be 1x10(-17) cm2/s at 342 K (Tg). The self-part of the intermediate scattering function I(s)(q,t) decays exponentially. Samples deposited well below Tg show a substantial thermal history effect during subsequent translational motion at Tg.

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Isothermal desorption measurements of self-diffusion in supercooled o-terphenyl

Mapes

Swallen

Kearns

et al. 2006

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Isothermal desorption of o-terphenyl thin-film bilayers was used to measure self-diffusion coefficients of supercooled o-terphenyl near the glass transition temperature (Tg=243 K). Diffusion coefficients from 10(-15.5) to 10(-12) cm2 s(-1) were obtained between 246 and 265 K. Protio and deuterio o-terphenyl were sequentially vapor deposited, then annealed to simultaneously diffuse and desorb the sample in a vacuum chamber. During the desorption of the bilayer, the concentration of each isotope was detected by a mass spectrometer, which revealed the extent of interfacial broadening. In these experiments, isotopic interdiffusion is indistinguishable from self-diffusion and the measured interfacial broadening is consistent with Fickian diffusion. The samples prepared under several different deposition conditions yielded the same self-diffusion coefficients, indicating that the experiments were conducted in the equilibrium supercooled liquid state.

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U.S. department of energy photovoltaics research evaluation and assessment

Cheese¹,

Mapes²,

Turo³

et al. 2017

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Marie K. Mapes

Organic Glasses with Exceptional Thermodynamic and Kinetic Stability

Self-Diffusion of Supercooled o-Terphenyl near the Glass Transition Temperature

Highly Conductive Siloxane Polymers

Neutron reflectivity measurements of the translational motion of tris(naphthylbenzene) at the glass transition temperature

Isothermal desorption measurements of self-diffusion in supercooled o-terphenyl

U.S. department of energy photovoltaics research evaluation and assessment

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