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13 results on '"Aubry, Taylor J"'

1. Ultrastrong Coupling of Band-Nested Excitons in Few-Layer Molybdenum Disulphide

Author

Rose, Aaron H., Aubry, Taylor J., Zhang, Hanyu, and van de Lagemaat, Jao

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Optics
Abstract

The two-dimensional transition-metal dichalcogenides (2D TMDCs) are an intriguing platform for studying light-matter interactions because they combine the electronic properties of conventional semiconductors with the optical resonances found in organic systems. However, the coupling strengths demonstrated in strong exciton-polariton coupling remain much lower than those found in organic systems. In this paper, we take on a new approach by utilizing the large oscillator strength of the above-band gap C exciton in few-layer molybdenum disulphide ($\text{FL-MoS}_2$). We show a k-space Rabi splitting of 293 meV when coupling $\text{FL-MoS}_2$ C excitons to surface plasmon polaritons at room temperature. This value is 11% of the uncoupled exciton energy (2.67 eV or 464 nm), ~2x what is typically seen in the TMDCs, placing the system in the ultrastrong coupling regime. Our results take a step towards finally achieving the efficient quantum coherent processes of ultrastrong coupling in a CMOS-compatible system -- the 2D TMDCs -- in the visible spectrum.

Published
2022

3. Tunable Dopants with Intrinsic Counterion Separation Reveal the Effects of Electron Affinity on Dopant Intercalation and Free Carrier Production in Sequentially Doped Conjugated Polymer Films

Author

Aubry, Taylor J, Winchell, KJ, Salamat, Charlene Z, Basile, Victoria M, Lindemuth, Jeffrey R, Stauber, Julia M, Axtell, Jonathan C, Kubena, Rebecca M, Phan, Minh D, Bird, Matthew J, Spokoyny, Alexander M, Tolbert, Sarah H, and Schwartz, Benjamin J

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, counterion distance, doping efficiency, electronic offset, molecular dopants, redox-driven infiltration, semiconducting polymers, tunable electron affinity, redox‐driven infiltration, Physical Sciences, Materials, Chemical sciences, Physical sciences
Abstract

Carrier mobility in doped conjugated polymers is limited by Coulomb interactions with dopant counterions. This complicates studying the effect of the dopant's oxidation potential on carrier generation because different dopants have different Coulomb interactions with polarons on the polymer backbone. Here, dodecaborane (DDB)-based dopants are used, which electrostatically shield counterions from carriers and have tunable redox potentials at constant size and shape. DDB dopants produce mobile carriers due to spatial separation of the counterion, and those with greater energetic offsets produce more carriers. Neutron reflectometry indicates that dopant infiltration into conjugated polymer films is redox-potential-driven. Remarkably, X-ray scattering shows that despite their large 2-nm size, DDBs intercalate into the crystalline polymer lamellae like small molecules, indicating that this is the preferred location for dopants of any size. These findings elucidate why doping conjugated polymers usually produces integer, rather than partial charge transfer: dopant counterions effectively intercalate into the lamellae, far from the polarons on the polymer backbone. Finally, it is shown that the IR spectrum provides a simple way to determine polaron mobility. Overall, higher oxidation potentials lead to higher doping efficiencies, with values reaching 100% for driving forces sufficient to dope poorly crystalline regions of the film.

Published
2020

4. Dodecaborane-Based Dopants Designed to Shield Anion Electrostatics Lead to Increased Carrier Mobility in a Doped Conjugated Polymer.

Author

Aubry, Taylor J, Axtell, Jonathan C, Basile, Victoria M, Winchell, KJ, Lindemuth, Jeffrey R, Porter, Tyler M, Liu, Ji-Yuan, Alexandrova, Anastassia N, Kubiak, Clifford P, Tolbert, Sarah H, Spokoyny, Alexander M, and Schwartz, Benjamin J

Subjects
Coulomb screening, dodecaboranes, mobility, molecular dopants, semiconducting polymers, Physical Sciences, Chemical Sciences, Engineering, Nanoscience & Nanotechnology
Abstract

One of the most effective ways to tune the electronic properties of conjugated polymers is to dope them with small-molecule oxidizing agents, creating holes on the polymer and molecular anions. Undesirably, strong electrostatic attraction from the anions of most dopants localizes the holes created on the polymer, reducing their mobility. Here, a new strategy utilizing a substituted boron cluster as a molecular dopant for conjugated polymers is employed. By designing the cluster to have a high redox potential and steric protection of the core-localized electron density, highly delocalized polarons with mobilities equivalent to films doped with no anions present are obtained. AC Hall effect measurements show that P3HT films doped with these boron clusters have conductivities and polaron mobilities roughly an order of magnitude higher than films doped with F4 TCNQ, even though the boron-cluster-doped films have poor crystallinity. Moreover, the number of free carriers approximately matches the number of boron clusters, yielding a doping efficiency of ≈100%. These results suggest that shielding the polaron from the anion is a critically important aspect for producing high carrier mobility, and that the high polymer crystallinity required with dopants such as F4 TCNQ is primarily to keep the counterions far from the polymer backbone.

Published
2019

12. Tuning Counterion Chemistry to Reduce Carrier Localization in Doped Thermoelectric Carbon Nanotube Networks

Author

Murrey, Tucker L., primary, Aubry, Taylor J., additional, Ruiz, Omar Leon, additional, Thurman, Kira A., additional, Eckstein, Klaus H., additional, Doud, Evan A., additional, Stauber, Julia M., additional, Spokoyny, Alexander M., additional, Schwartz, Benjamin J., additional, Hertel, Tobias, additional, Blackburn, Jeff, additional, and Ferguson, Andrew John, additional

Published
2022
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