Detalhe da pesquisa
1.
Understanding Electrolyte Ion Size Effects on the Performance of Conducting Metal-Organic Framework Supercapacitors.
J Am Chem Soc;
146(18): 12473-12484, 2024 May 08.
Artigo
em Inglês
| MEDLINE
| ID: mdl-38716517
2.
Role of Surface Terminations for Charge Storage of Ti3C2Tx MXene Electrodes in Aqueous Acidic Electrolyte.
Angew Chem Int Ed Engl;
63(14): e202319238, 2024 Apr 02.
Artigo
em Inglês
| MEDLINE
| ID: mdl-38324461
3.
Unraveling the Capacitive Charge Storage Mechanism of Nitrogen-Doped Porous Carbons by EQCM and ssNMR.
J Am Chem Soc;
144(31): 14217-14225, 2022 08 10.
Artigo
em Inglês
| MEDLINE
| ID: mdl-35914237
4.
Perspectives for electrochemical capacitors and related devices.
Nat Mater;
19(11): 1151-1163, 2020 Nov.
Artigo
em Inglês
| MEDLINE
| ID: mdl-32747700
5.
A general Lewis acidic etching route for preparing MXenes with enhanced electrochemical performance in non-aqueous electrolyte.
Nat Mater;
19(8): 894-899, 2020 Aug.
Artigo
em Inglês
| MEDLINE
| ID: mdl-32284597
6.
Mesoscopic simulations of the in situ NMR spectra of porous carbon based supercapacitors: electronic structure and adsorbent reorganisation effects.
Phys Chem Chem Phys;
23(30): 15925-15934, 2021 Aug 04.
Artigo
em Inglês
| MEDLINE
| ID: mdl-34286771
7.
Carbon-carbon supercapacitors: Beyond the average pore size or how electrolyte confinement and inaccessible pores affect the capacitance.
J Chem Phys;
155(18): 184703, 2021 Nov 14.
Artigo
em Inglês
| MEDLINE
| ID: mdl-34773950
8.
Nanoporous carbon for electrochemical capacitive energy storage.
Chem Soc Rev;
49(10): 3005-3039, 2020 May 21.
Artigo
em Inglês
| MEDLINE
| ID: mdl-32285082
9.
Electrochemical Characterization of Single Layer Graphene/Electrolyte Interface: Effect of Solvent on the Interfacial Capacitance.
Angew Chem Int Ed Engl;
60(24): 13317-13322, 2021 Jun 07.
Artigo
em Inglês
| MEDLINE
| ID: mdl-33555100
10.
Charge Storage Mechanisms of Single-Layer Graphene in Ionic Liquid.
J Am Chem Soc;
141(42): 16559-16563, 2019 Oct 23.
Artigo
em Inglês
| MEDLINE
| ID: mdl-31588740
11.
Partial breaking of the Coulombic ordering of ionic liquids confined in carbon nanopores.
Nat Mater;
16(12): 1225-1232, 2017 12.
Artigo
em Inglês
| MEDLINE
| ID: mdl-28920938
12.
Confined water controls capacitance.
Nat Mater;
20(12): 1597-1598, 2021 12.
Artigo
em Inglês
| MEDLINE
| ID: mdl-34815568
13.
Author Correction: A general Lewis acidic etching route for preparing MXenes with enhanced electrochemical performance in non-aqueous electrolyte.
Nat Mater;
20(4): 571, 2021 Apr.
Artigo
em Inglês
| MEDLINE
| ID: mdl-33462470
14.
In situ NMR and electrochemical quartz crystal microbalance techniques reveal the structure of the electrical double layer in supercapacitors.
Nat Mater;
14(8): 812-9, 2015 Aug.
Artigo
em Inglês
| MEDLINE
| ID: mdl-26099110
15.
Nanomaterials for Electrochemical Energy Storage: the Good and the Bad.
Acta Chim Slov;
63(3): 417-23, 2016.
Artigo
em Inglês
| MEDLINE
| ID: mdl-27640370
16.
NMR Study of Ion Dynamics and Charge Storage in Ionic Liquid Supercapacitors.
J Am Chem Soc;
137(22): 7231-42, 2015 Jun 10.
Artigo
em Inglês
| MEDLINE
| ID: mdl-25973552
17.
Confinement, Desolvation, And Electrosorption Effects on the Diffusion of Ions in Nanoporous Carbon Electrodes.
J Am Chem Soc;
137(39): 12627-32, 2015 Oct 07.
Artigo
em Inglês
| MEDLINE
| ID: mdl-26369420
18.
Electrochemical quartz crystal microbalance (EQCM) study of ion dynamics in nanoporous carbons.
J Am Chem Soc;
136(24): 8722-8, 2014 Jun 18.
Artigo
em Inglês
| MEDLINE
| ID: mdl-24869895
19.
High-rate electrochemical energy storage through Li+ intercalation pseudocapacitance.
Nat Mater;
12(6): 518-22, 2013 Jun.
Artigo
em Inglês
| MEDLINE
| ID: mdl-23584143
20.
Nanoarchitectured graphene-based supercapacitors for next-generation energy-storage applications.
Chemistry;
20(43): 13838-52, 2014 Oct 20.
Artigo
em Inglês
| MEDLINE
| ID: mdl-25251360