Gregory Vincent
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Explore the profile of Gregory Vincent including associated specialties, affiliations and a list of published articles.
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26
Citations
53
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Recent Articles
1.
Gureghian C, Rodriguez J, Dupuis C, Bardou N, Ferlazzo L, Ribet I, et al.
Opt Express
. 2024 Jun;
32(8):13438-13449.
PMID: 38859314
This article deals with the optical study of nanostructured components which absorb light across the entire long-wave infrared (LWIR) spectral band. The components are made of type-II superlattice (T2SL) absorber...
2.
Dang T, Cavallo M, Khalili A, Dabard C, Bossavit E, Zhang H, et al.
Nano Lett
. 2023 Sep;
23(18):8539-8546.
PMID: 37712683
Optoelectronic devices rely on conductive layers as electrodes, but they usually introduce optical losses that are detrimental to the device performances. While the use of transparent conductive oxides is established...
3.
Pierini S, Abadie C, Dang T, Khalili A, Zhang H, Cavallo M, et al.
Materials (Basel)
. 2023 Mar;
16(6).
PMID: 36984214
Nanocrystals' (NCs) band gap can be easily tuned over the infrared range, making them appealing for the design of cost-effective sensors. Though their growth has reached a high level of...
4.
Mid-wave infrared sensitized InGaAs using intraband transition in doped colloidal II-VI nanocrystals
Khalili A, Cavallo M, Dang T, Dabard C, Zhang H, Bossavit E, et al.
J Chem Phys
. 2023 Mar;
158(9):094702.
PMID: 36889960
Narrow bandgap nanocrystals (NCs) are now used as infrared light absorbers, making them competitors to epitaxially grown semiconductors. However, these two types of materials could benefit from one another. While...
5.
Abadie C, Paggi L, Fabas A, Khalili A, Dang T, Dabard C, et al.
Nano Lett
. 2022 Oct;
22(21):8779-8785.
PMID: 36190814
While the integration of nanocrystals as an active medium for optoelectronic devices progresses, light management strategies are becoming required. Over recent years, several photonic structures (plasmons, cavities, mirrors, etc.) have...
6.
Chehaibou B, Izquierdo E, Chu A, Abadie C, Cavallo M, Khalili A, et al.
Nanoscale
. 2022 Feb;
14(7):2711-2721.
PMID: 35112698
As nanocrystals (NCs) gain maturity, they become central building blocks for optoelectronics in devices such as solar cells and, more recently, infrared focal plane arrays. Now that the proof of...
7.
Dang T, Vasanelli A, Todorov Y, Sirtori C, Prado Y, Chu A, et al.
Nano Lett
. 2021 Aug;
21(15):6671-6677.
PMID: 34339191
Nanocrystals (NCs) have gained considerable attention for their broadly tunable absorption from the UV to the THz range. Nevertheless, their optical features suffer from a lack of tunability once integrated...
8.
Chu A, Greboval C, Prado Y, Majjad H, Delerue C, Dayen J, et al.
Nat Commun
. 2021 Mar;
12(1):1794.
PMID: 33741921
Narrow band gap nanocrystals offer an interesting platform for alternative design of low-cost infrared sensors. It has been demonstrated that transport in HgTe nanocrystal arrays occurs between strongly-coupled islands of...
9.
Mas A, Druart G, Bouchon P, Vincent G, Favier S, Compain E, et al.
Appl Opt
. 2020 Sep;
59(26):7779-7791.
PMID: 32976448
In the field of spectral imaging, numerous instruments use scanning-based technologies. However, the temporal dimension of these systems, whether to scan the spectrum or scan the scene, can be an...
10.
Rastogi P, Chu A, Greboval C, Qu J, Noumbe U, Chee S, et al.
Nano Lett
. 2020 Apr;
20(5):3999-4006.
PMID: 32283029
To date, defect-tolerance electronic structure of lead halide perovskite nanocrystals is limited to an optical feature in the visible range. Here, we demonstrate that IR sensitization of formamidinium lead iodine...