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Ying-Zhong Ma

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Articles 55
Citations 216
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Recent Articles
1.
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,...
2.
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...
3.
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...
4.
Kumar N, Premadasa U, Dong D, Roy S, Ma Y, Doughty B, et al.
Langmuir . 2024 Jul; 40(28):14311-14320. PMID: 38958522
Amino acids make up a promising family of molecules capable of direct air capture (DAC) of CO from the atmosphere. Under alkaline conditions, CO reacts with the anionic form of...
5.
Liu Z, Lin L, Li T, Premadasa U, Hong K, Ma Y, et al.
J Colloid Interface Sci . 2024 May; 669:552-560. PMID: 38729003
Hypothesis: Understanding the rules that control the assembly of nanostructured soft materials at interfaces is central to many applications. We hypothesize that electrolytes can be used to alter the hydration...
6.
Premadasa U, Doughty B, Custelcean R, Ma Y
Chempluschem . 2024 Mar; 89(10):e202300713. PMID: 38456801
The intensive energy demands associated with solvent regeneration and CO release in current direct air capture (DAC) technologies makes their deployment at the massive scales (GtCO/year) required to positively impact...
7.
Premadasa U, Kumar N, Zhu Z, Stamberga D, Li T, Roy S, et al.
ACS Appl Mater Interfaces . 2024 Feb; 16(9):12052-12061. PMID: 38411063
Interfaces are considered a major bottleneck in the capture of CO from air. Efforts to design surfaces to enhance CO capture probabilities are challenging due to the remarkably poor understanding...
8.
Ma Y, Premadasa U, Bryantsev V, Miles A, Ivanov I, Elgattar A, et al.
Phys Chem Chem Phys . 2024 Jan; 26(5):4062-4070. PMID: 38224171
Direct access to - photoisomerization in a metastable state photoacid (mPAH) remains challenging owing to the presence of competing excited-state relaxation pathways and multiple transient isomers with overlapping spectra. Here,...
9.
Premadasa U, Bocharova V, Lin L, Genix A, Heller W, Sacci R, et al.
J Phys Chem B . 2023 May; 127(21):4886-4895. PMID: 37216432
Liquid/liquid (L/L) interfaces play a key, yet poorly understood, role in a range of complex chemical phenomena where time-evolving interfacial structures and transient supramolecular assemblies act as gatekeepers to function....
10.
Premadasa U, Bocharova V, Miles A, Stamberga D, Belony S, Bryantsev V, et al.
Angew Chem Int Ed Engl . 2023 May; 62(29):e202304957. PMID: 37198131
One of the grand challenges underlying current direct air capture (DAC) technologies relates to the intensive energy cost for sorbent regeneration and CO release, making the massive scale (GtCO /year)...