Peter J Reece
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Explore the profile of Peter J Reece including associated specialties, affiliations and a list of published articles.
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39
Citations
239
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Recent Articles
1.
Stewart A, Zhu Y, Liu Y, Simpson D, Reece P
Nano Lett
. 2024 Sep;
24(39):12188-12195.
PMID: 39291712
Here we show that gradient force optical tweezers can be used to mediate the self-assembly of nanodiamonds into superstructures, which can serve as optically trapped nanoscale quantum probes with superior...
2.
Pusch A, Nielsen M, Sazzad M, Reece P, Ekins-Daukes N
Opt Lett
. 2021 Oct;
46(20):5124.
PMID: 34653135
The current-voltage characteristics presented by Zhang et al. in their recent work on designing thermoradiative systems overestimate the achievable power using the proposed material by several orders of magnitude.
3.
Shan X, Wang F, Wang D, Wen S, Chen C, Di X, et al.
Nat Nanotechnol
. 2021 Feb;
16(5):531-537.
PMID: 33603239
Optical tweezers are widely used in materials assembly, characterization, biomechanical force sensing and the in vivo manipulation of cells and organs. The trapping force has primarily been generated through the...
4.
Gautam S, Goncales V, Colombo R, Tang W, Cordoba de Torresi S, Reece P, et al.
Chem Commun (Camb)
. 2020 Jun;
56(54):7435-7438.
PMID: 32490860
Light-activated electrochemistry (LAE) consists of employing a focused light beam to illuminate a semiconducting area and make it electrochemically active. Here, we show how to reduce the electrochemical spatial resolution...
5.
Khan M, Zhu Y, Yao Y, Zhang P, Agrawal A, Reece P
Nanoscale
. 2020 Feb;
12(14):7577-7585.
PMID: 32073105
Plasmonic nanohole arrays for biosensing applications have attracted tremendous attention because of their flexibility in optical signature design, high multiplexing capabilities, simple optical alignment setup, and high sensitivity. The quality...
6.
Ortega-Piwonka I, Angstmann C, Henry B, Reece P
Chaos
. 2020 Jan;
28(4):043101.
PMID: 31906650
We describe a mechanism whereby random noise can play a constructive role in the manifestation of a pattern, aperiodic rotations, that would otherwise be damped by internal dynamics. The mechanism...
7.
Han F, Armstrong T, Andres-Arroyo A, Bennett D, Soeriyadi A, Alinezhad Chamazketi A, et al.
Nanoscale
. 2020 Jan;
12(3):1680-1687.
PMID: 31894817
We report on the characterisation of the optical properties and dynamic behaviour of optically trapped single stimuli-responsive plasmonic nanoscale assemblies. Nano-assemblies consist of a core-satellite arrangement where the constituent nanoparticles...
8.
Chuah K, Wu Y, Vivekchand S, Gaus K, Reece P, Micolich A, et al.
Nat Commun
. 2019 May;
10(1):2109.
PMID: 31068594
Nanopore sensors detect individual species passing through a nanoscale pore. This experimental paradigm suffers from long analysis times at low analyte concentration and non-specific signals in complex media. These limit...
9.
Piya R, Zhu Y, Soeriyadi A, Silva S, Reece P, Gooding J
Biosens Bioelectron
. 2019 Jan;
127:229-235.
PMID: 30622037
The work presented here describes the development of an optical label-free biosensor based on a porous silicon (PSi) Bragg reflector to study heterogeneity in single cells. Photolithographic patterning of a...
10.
Sriram M, Markhali B, Nicovich P, Bennett D, Reece P, Hibbert D, et al.
Biosens Bioelectron
. 2018 Jul;
117:530-536.
PMID: 29982124
The integration of plasmonic nanoparticles into biosensors has the potential to increase the sensitivity and dynamic range of detection, through the use of single nanoparticle assays. The analysis of the...