James Cassidy
Overview
Explore the profile of James Cassidy 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
46
Citations
2036
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.
Marder A, Smith S, Cassidy J, Harankahage D, Hu Z, Savoy S, et al.
ACS Nano
. 2024 Oct;
18(44):30863-30870.
PMID: 39460753
Quantum information processing demands efficient quantum light sources (QLS) capable of producing high-fidelity single photons or entangled photon pairs. Single epitaxial quantum dots (QDs) have long been proven to be...
2.
Pero J, Mueller E, Adams A, Adolph R, Bagchi P, Balce D, et al.
J Med Chem
. 2024 Aug;
67(16):14586-14608.
PMID: 39136957
In the aftermath of the COVID-19 pandemic, opportunities to modulate biological pathways common to the lifecycles of viruses need to be carefully considered. -linked glycosylation in humans is mediated exclusively...
3.
Zhao K, Zhou X, Li X, Moon J, Cassidy J, Harankahage D, et al.
ACS Nano
. 2024 Apr;
18(16):10946-10953.
PMID: 38613507
Spherical semiconductor nanoplatelets, known as quantum shells (QSs), have captured significant interest for their strong suppression of Auger recombination, which leads to long multiexciton lifetimes and wide optical gain bandwidth....
4.
Cassidy J, Ondry J, Talapin D
Nat Mater
. 2023 Sep;
22(10):1167-1168.
PMID: 37758975
No abstract available.
5.
Malin A, Cassidy J
J Intensive Care Soc
. 2023 Sep;
24(3):335-337.
PMID: 37744081
The COVID-19 pandemic has brought with it a large number of challenges for healthcare professionals including intubation safety in out-of-theatre environments. An important aspect of this topic is the optimisation...
6.
Beavon J, Huang J, Harankahage D, Montemurri M, Cassidy J, Zamkov M
Chem Commun (Camb)
. 2023 Sep;
59(76):11337-11348.
PMID: 37676487
Colloidal semiconductor nanocrystals (NCs) have attracted a great deal of attention in recent decades. The quantum efficiency of many optoelectronic processes based on these nanomaterials, however, declines with increasing optical...
7.
Harankahage D, Cassidy J, Beavon J, Huang J, Brown N, Berkinsky D, et al.
J Am Chem Soc
. 2023 Jun;
145(24):13326-13334.
PMID: 37279071
Many optoelectronic processes in colloidal semiconductor nanocrystals (NCs) suffer an efficiency decline under high-intensity excitation. This issue is caused by Auger recombination of multiple excitons, which converts the NC energy...
8.
Saunders M, Iype R, Kelly C, Crosby J, Kerr R, Harkin A, et al.
Clin Colorectal Cancer
. 2023 Mar;
22(2):231-237.
PMID: 36967267
Aim: Patients with loco-regional right-sided colorectal tumors have a worse overall survival (OS). Here we investigate the difference in disease free survival (DFS) between colorectal patients with right and left...
9.
Cassidy J, Diroll B, Mondal N, Berkinsky D, Zhao K, Harankahage D, et al.
ACS Nano
. 2022 Feb;
16(2):3017-3026.
PMID: 35129951
Auger decay of multiple excitons represents a significant obstacle to photonic applications of semiconductor quantum dots (QDs). This nonradiative process is particularly detrimental to the performance of QD-based electroluminescent and...
10.
Cassidy J, Yang M, Harankahage D, Porotnikov D, Moroz P, Razgoniaeva N, et al.
Nano Lett
. 2021 Aug;
21(17):7339-7346.
PMID: 34450018
Electrically coupled quantum dots (QDs) can support unique optoelectronic properties arising from the superposition of single-particle excited states. Experimental methods for integrating colloidal QDs within the same nano-object, however, have...