Vyacheslav S Bryantsev
Overview
Explore the profile of Vyacheslav S Bryantsev including associated specialties, affiliations and a list of published articles.
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103
Citations
739
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Recent Articles
1.
Nguyen H, Gibson L, Emerson M, Borah B, Roy S, Bryantsev V, et al.
Phys Chem Chem Phys
. 2025 Feb;
27(8):4290-4297.
PMID: 39918394
Next-generation nuclear power plants may include exciting novel designs in which molten salts are the coolant or a combination of the coolant and fuel. Whereas it is straightforward to see...
2.
Kumar N, Bryantsev V
J Phys Chem B
. 2025 Jan;
129(6):1818-1826.
PMID: 39879123
Direct air capture of CO using amino acid absorbents, such as glycine or sarcosine, is constrained by the relatively slow mass transfer of CO through the air-aqueous interface. Our recent...
3.
Gibson L, Chahal R, Bryantsev V
Chem Sci
. 2025 Jan;
16(7):3078-3091.
PMID: 39867953
The successful design and deployment of next-generation nuclear technologies heavily rely on thermodynamic data for relevant molten salt systems. However, the lack of accurate force fields and efficient methods has...
4.
Chahal R, Gibson L, Roy S, Bryantsev V
J Phys Chem B
. 2025 Jan;
129(3):952-964.
PMID: 39801049
Molten salts are promising candidates in numerous clean energy applications, where knowledge of thermophysical properties and vapor pressure across their operating temperature ranges is critical for safe operations. Due to...
5.
Islam M, Lin L, Ray D, Premadasa U, Ma Y, Sacci R, et al.
J Am Chem Soc
. 2025 Jan;
147(6):5080-5088.
PMID: 39744917
Chemical selectivity is traditionally understood in the context of rigid molecular scaffolds with precisely defined local coordination and chemical environments that ultimately facilitate a given transformation of interest. By contrast,...
6.
Kumar N, Bryantsev V, Roy S
J Am Chem Soc
. 2024 Dec;
147(2):1411-1415.
PMID: 39711150
Direct air capture (DAC) technologies are limited by the poor understanding of the dynamic role of interfaces in modulating the chemisorption of CO from air into solutions. While the reactivity...
7.
Premadasa U, Kumar N, Stamberga D, Bocharova V, Damron J, Li T, et al.
J Chem Phys
. 2024 Oct;
161(16).
PMID: 39450735
The direct air capture (DAC) of CO2 using aqueous solvents is plagued by slow kinetics and interfacial barriers that limit effectiveness in combating climate change. Functionalizing air/aqueous surfaces with charged...
8.
Ray D, Sartori A, Radujevic A, George S, Postema R, Tan X, et al.
Chemistry
. 2024 Oct;
30(61):e202401872.
PMID: 39413149
A hybrid receptor-sensor for anions originating from the merging of positively charged ammonium moieties for electrostatic attraction/stronger binding of azacrowns with directionality of calixpyrrole hydrogen bond donors for selectivity is...
9.
Dang D, Einkauf J, Ma X, Custelcean R, Ma Y, Zimmerman P, et al.
Phys Chem Chem Phys
. 2024 Sep;
26(36):24008-24020.
PMID: 39246286
The hydrazone functional group, when coupled with a pyridyl substituent, offers a unique class of widely tunable photoswitches, whose -to- photoisomerization equilibria can be controlled through intramolecular hydrogen bonding between...
10.
Huang S, Ray D, Zhang Q, Yang J, Bryantsev V, Sessler J
J Am Chem Soc
. 2024 Aug;
146(32):22145-22150.
PMID: 39101883
A heat-driven catch-and-release strategy for CoCl capture is described. It is based on the use of an immobilized neutral dicyclohexylacetamide-based receptor supported on polystyrene (PS-). An X-ray diffraction analysis of...