Richard L McCreery
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Explore the profile of Richard L McCreery including associated specialties, affiliations and a list of published articles.
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70
Citations
525
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Recent Articles
1.
McCreery R
Acc Chem Res
. 2022 Sep;
55(19):2766-2779.
PMID: 36137180
The field of molecular electronics has grown rapidly since its experimental realization in the late 1990s, with thousands of publications on how molecules can act as circuit components and the...
2.
Saxena S, Tefashe U, Supur M, McCreery R
ACS Sens
. 2020 Dec;
6(2):513-522.
PMID: 33315386
Molecular junctions with partially transparent top contacts permit monitoring photocurrents as probes of transport mechanism and potentially could act as photosensors with characteristics determined by the molecular layer inside the...
3.
McCreery R, Saxena S, Supur M, Tefashe U
Phys Chem Chem Phys
. 2020 Sep;
22(37):21543-21546.
PMID: 32926016
Misinterpretation of scanning tunnelling microscopy results yielded incorrect conclusions about the flatness of a carbon electrode substrate used for molecular electronic devices. Furthermore, the results are not supported statistically and...
4.
Saxena S, Tefashe U, McCreery R
J Am Chem Soc
. 2020 Aug;
142(36):15420-15430.
PMID: 32786741
The bias and temperature dependence of both dark and photoinduced currents in carbon-based molecular junctions were examined over a wide range of oligomeric layer thickness () values from 4 to...
5.
Supur M, Saxena S, McCreery R
J Am Chem Soc
. 2020 Jun;
142(27):11658-11662.
PMID: 32567306
Resonant injection and resulting charge storage were examined in a large-area carbon/tetraphenylporphyrin(TPP)/LiF/carbon junction, where the LiF layer provides mobile ions in acetonitrile (ACN) vapor. Resonant electron transfer into TPP molecules...
6.
Nguyen T, McCreery R, McDermott M
Analyst
. 2020 Jun;
145(14):5041-5052.
PMID: 32555909
Carbon film electrodes can often be used without pretreatment, and their fabrication allows for flexibility in size and shape and for mass production. In this work, we are exploring layered...
7.
Santos A, Tefashe U, McCreery R, Bueno P
Phys Chem Chem Phys
. 2020 May;
22(19):10828-10832.
PMID: 32377646
It has been demonstrated that mesoscopic rates operate in nanoscale electrochemical systems and, from a fundamental point of view, are able to establish a bridge between electrochemical and molecular electronic...
8.
James D, Bayat A, Smith S, Lacroix J, McCreery R
Nanoscale Horiz
. 2020 Apr;
3(1):45-52.
PMID: 32254109
Much of the motivation for developing molecular electronic devices is the prospect of achieving novel electronic functions by varying molecular structure. We describe a "building block" approach for molecular junctions...
9.
Wang H, Sayed S, Luber E, Olsen B, Shirurkar S, Venkatakrishnan S, et al.
ACS Nano
. 2020 Mar;
14(3):2575-2584.
PMID: 32180396
Redox flow batteries (RFBs) are promising energy storage candidates for grid deployment of intermittent renewable energy sources such as wind power and solar energy. Various new redox-active materials have been...
10.
Farquhar A, Smith S, Van Dyck C, McCreery R
ACS Appl Mater Interfaces
. 2020 Feb;
12(9):10211-10223.
PMID: 32040296
An inexpensive, solution phase modification of flat carbon electrodes by electrochemical reactions of a 1,8-diaminonaphthalene derivative results in a 120- to 700-fold increase in capacity by formation of a 15-22...