Kailai Lin scite author profile

An in-depth theoretical analysis of key chemical equilibria in Signal Amplification by Reversible Exchange (SABRE) is provided, employing density functional theory calculations to characterize the likely reaction network. For all reactions in the network, the potential energy surface is probed to identify minimum energy pathways. Energy barriers and transition states are calculated, and harmonic transition state theory is applied to calculate exchange rates that approximate experimental values. The reaction network energy surface can be modulated by chemical potentials that account for the depend-ence on concentration, temperature, and partial pressure of molecular constituents (hydrogen, methanol, pyridine) supplied to the experiment under equilibrium conditions. We show that, under typical experimental conditions, the Gibbs free energies of the two key states involved in pyridine-hydrogen exchange at the common Ir-IMes catalyst system in methanol are essentially the same, i. e., nearly optimal for SABRE. We also show that a methanol-containing intermediate is plausible as a transient species in the process.

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Composition-Defined Optical Properties and the Direct-to-Indirect Transition in Core–Shell In_1–xGa_xP/ZnS Colloidal Quantum Dots

Gupta

Ondry

Lin

et al. 2023

J. Am. Chem. Soc.

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Semiconductors are commonly divided into materials with direct or indirect band gaps based on the relative positions of the top of the valence band and the bottom of the conduction band in crystal momentum (k) space. It has, however, been debated if k is a useful quantum number to describe the band structure in quantum-confined nanocrystalline systems, which blur the distinction between direct and indirect gap semiconductors. In bulk III−V semiconductor alloys like In 1−x Ga x P, the band structure can be tuned continuously from the direct-to indirect-gap by changing the value of x. The effect of strong quantum confinement on the direct-to-indirect transition in this system has yet to be established because high-quality colloidal nanocrystal samples have remained inaccessible. Herein, we report one of the first systematic studies of ternary III−V nanocrystals by utilizing an optimized molten-salt In-to-Ga cation exchange protocol to yield bright In 1−x Ga x P/ZnS core−shell particles with photoluminescence quantum yields exceeding 80%. We performed two-dimensional solid-state NMR studies to assess the alloy homogeneity and the extent of surface oxidation in In 1−x Ga x P cores. The radiative decay lifetime for In 1−x Ga x P/ZnS monotonically increases with higher gallium content. Transient absorption studies on In 1−x Ga x P/ZnS nanocrystals demonstrate signatures of direct-and indirect-like behavior based on the presence or absence, respectively, of excitonic bleach features. Atomistic electronic structure calculations based on the semi-empirical pseudopotential model are used to calculate absorption spectra and radiative lifetimes and evaluate band-edge degeneracy; the resulting calculated electronic properties are consistent with experimental observations. By studying photoluminescence characteristics at elevated temperatures, we demonstrate that a reduced lattice mismatch at the III−V/II−VI core−shell interface can enhance the thermal stability of emission. These insights establish cation exchange in molten inorganic salts as a viable synthetic route to nontoxic, high-quality In 1−x Ga x P/ZnS QD emitters with desirable optoelectronic properties.

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Theory of Photoluminescence Spectral Line Shapes of Semiconductor Nanocrystals

Lin

Jasrasaria

Yoo

et al. 2023

J. Phys. Chem. Lett.

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Single-molecule photoluminescence (PL) spectroscopy of semiconductor nanocrystals (NCs) reveals the nature of exciton−phonon interactions in NCs. Understanding the homogeneous spectral line shapes and their temperature dependence remains an open problem. Here, we develop an atomistic model to describe the PL spectrum of NCs, accounting for excitonic effects, phonon dispersion relations, and exciton−phonon couplings. We validate our model using single-NC measurements on CdSe/CdS NCs from T = 4 to 290 K, and we find that the slightly asymmetric main peak at low temperatures is comprised of a narrow zerophonon line (ZPL) and acoustic phonon sidebands. Furthermore, we identify the specific phonon modes that give rise to the optical phonon sidebands. At temperatures above 200 K, the spectral line width shows a stronger dependence upon the temperature, which we demonstrate to be correlated with higher order exciton−phonon couplings. We also identify the line width dependence upon reorganization energy, NC core sizes, and shell thicknesses.

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Density Functional Theory Study of Reaction Equilibria in Signal Amplification by Reversible Exchange

et al. 2021

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Theory of photoluminescence spectral line shapes of semiconductor nanocrystals

Lin¹,

Jasrasaria²,

Yoo³

et al. 2022

Preprint

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Kailai Lin

Density Functional Theory Study of Reaction Equilibria in Signal Amplification by Reversible Exchange

Composition-Defined Optical Properties and the Direct-to-Indirect Transition in Core–Shell In_1–xGa_xP/ZnS Colloidal Quantum Dots

Theory of Photoluminescence Spectral Line Shapes of Semiconductor Nanocrystals

Density Functional Theory Study of Reaction Equilibria in Signal Amplification by Reversible Exchange

Theory of photoluminescence spectral line shapes of semiconductor nanocrystals

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About

Kailai Lin

Density Functional Theory Study of Reaction Equilibria in Signal Amplification by Reversible Exchange

Composition-Defined Optical Properties and the Direct-to-Indirect Transition in Core–Shell In1–xGaxP/ZnS Colloidal Quantum Dots

Theory of Photoluminescence Spectral Line Shapes of Semiconductor Nanocrystals

Density Functional Theory Study of Reaction Equilibria in Signal Amplification by Reversible Exchange

Theory of photoluminescence spectral line shapes of semiconductor nanocrystals

Contact Info

Product

Resources

About

Composition-Defined Optical Properties and the Direct-to-Indirect Transition in Core–Shell In_1–xGa_xP/ZnS Colloidal Quantum Dots