David G Kwabi
Overview
Explore the profile of David G Kwabi including associated specialties, affiliations and a list of published articles.
Author names and details appear as published. Due to indexing inconsistencies, multiple individuals may share a name, and a single author may have variations. MedLuna displays this data as publicly available, without modification or verification
Snapshot
Snapshot
Articles
13
Citations
107
Followers
0
Related Specialties
Related Specialties
Top 10 Co-Authors
Top 10 Co-Authors
Published In
Published In
Affiliations
Affiliations
Soon will be listed here.
Recent Articles
1.
Modak S, Pert D, Tami J, Shen W, Abdullahi I, Huan X, et al.
J Am Chem Soc
. 2024 Feb;
146(8):5173-5185.
PMID: 38358388
Aqueous redox flow batteries (RFBs) are attractive candidates for low-cost, grid-scale storage of energy from renewable sources. Quinoxaline derivatives represent a promising but underexplored class of charge-storing materials on account...
2.
Modak S, Shen W, Singh S, Herrera D, Oudeif F, Goldsmith B, et al.
Nat Commun
. 2023 Jun;
14(1):3602.
PMID: 37328467
Organic redox-active molecules are attractive as redox-flow battery (RFB) reactants because of their low anticipated costs and widely tunable properties. Unfortunately, many lab-scale flow cells experience rapid material degradation (from...
3.
Modak S, Valle J, Tseng K, Sakamoto J, Kwabi D
ACS Appl Mater Interfaces
. 2022 Apr;
14(17):19332-19341.
PMID: 35442617
Aqueous redox flow batteries (RFBs) are promising candidates for low-cost, grid-scale energy storage. However, the polymer-based membranes that are used in most prototypical systems fail to prevent crossover of small-molecule...
4.
Kwabi D, Ji Y, Aziz M
Chem Rev
. 2020 Feb;
120(14):6467-6489.
PMID: 32053366
Aqueous organic redox flow batteries (RFBs) could enable widespread integration of renewable energy, but only if costs are sufficiently low. Because the levelized cost of storage for an RFB is...
5.
Morasch R, Kwabi D, Tulodziecki M, Risch M, Zhang S, Shao-Horn Y
ACS Appl Mater Interfaces
. 2017 Feb;
9(5):4374-4381.
PMID: 28173703
O reduction in aprotic Na-O batteries results in the formation of NaO, which can be oxidized at small overpotentials (<200 mV) on charge. In this study, we investigated the NaO...
6.
Sayed S, Yao K, Kwabi D, Batcho T, Amanchukwu C, Feng S, et al.
Chem Commun (Camb)
. 2016 Dec;
53(2):460.
PMID: 27910967
Correction for 'Revealing instability and irreversibility in nonaqueous sodium-O battery chemistry' by Sayed Youssef Sayed et al., Chem. Commun., 2016, 52, 9691-9694.
7.
Kwabi D, Batcho T, Feng S, Giordano L, Thompson C, Shao-Horn Y
Phys Chem Chem Phys
. 2016 Aug;
18(36):24944-53.
PMID: 27560806
Understanding what controls Li-O2 battery discharge product chemistry and morphology is key to enabling its practical deployment as a low-cost, high-specific-energy energy conversion technology. Several studies have recently shown that...
8.
Sayed S, Yao K, Kwabi D, Batcho T, Amanchukwu C, Feng S, et al.
Chem Commun (Camb)
. 2016 Jul;
52(62):9691-4.
PMID: 27406258
Charging kinetics and reversibility of Na-O2 batteries can be influenced greatly by the particle size of NaO2 formed upon discharge, and exposure time (reactivity) of NaO2 to the electrolyte. Micrometer-sized...
9.
Kwabi D, Tulodziecki M, Pour N, Itkis D, Thompson C, Shao-Horn Y
J Phys Chem Lett
. 2016 Mar;
7(7):1204-12.
PMID: 26949979
Fundamental understanding of growth mechanisms of Li2O2 in Li-O2 cells is critical for implementing batteries with high gravimetric energies. Li2O2 growth can occur first by 1e(-) transfer to O2, forming...
10.
Kwabi D, Bryantsev V, Batcho T, Itkis D, Thompson C, Shao-Horn Y
Angew Chem Int Ed Engl
. 2016 Jan;
55(9):3129-34.
PMID: 26822277
Understanding and controlling the kinetics of O2 reduction in the presence of Li(+)-containing aprotic solvents, to either Li(+)-O2(-) by one-electron reduction or Li2 O2 by two-electron reduction, is instrumental to...