Your search keyword '"Homewood, KP"' showing total 9 results

1. Designing and fabricating a CdS QDs/Bi 2 MoO 6 monolayer S-scheme heterojunction for highly efficient photocatalytic C 2 H 4 degradation under visible light.

Author

Xu X, Su Y, Dong Y, Luo X, Wang S, Zhou W, Li R, Homewood KP, Xia X, Gao Y, and Chen X

Abstract

Achieving efficient photocatalytic degradation of atmospheric volatile organic compounds (VOCs) under sun-light is still a significant challenge for environmental protection. The S-scheme heterojunction with its unique charge migration route, high charge separation rate and strong redox ability, has great potential. However, how to regulate interfacial charge transfer of the S-scheme heterojunction is of significant importance. Here, density functional theory (DFT) calculations were first conducted and predicted that an S-scheme heterojunction could be formed in the CdS quantum dots/Bi 2 MoO 6 monolayer system. Subsequently, this novel heterojunction is constructed by in-situ hydrothermal synthesis of CdS quantum dots on monolayer Bi 2 MoO 6 . Under visible-light, this novel S-scheme system gives a high-efficiency photocatalytic degradation rate (6.04 × 10 -2 min -1 ) towards C 2 H 4 , which is 30.3 times higher than that of pure CdS (1.99 × 10 -3 min -1 ) and 41.7 times higher than pure Bi 2 MoO 6 (1.45 × 10 -3 min -1 ). Strong evidence for the S-scheme charge transfer path is provided by in-situ XPS, PL, TRPL and EPR., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2022

2. Super-enhancement of 1.54 μm emission from erbium codoped with oxygen in silicon-on-insulator.

Author

Lourenço MA, Milošević MM, Gorin A, Gwilliam RM, and Homewood KP

Abstract

We report on the super enhancement of the 1.54 μm Er emission in erbium doped silicon-on-insulator when codoped with oxygen at a ratio of 1:1. This is attributed to a more favourable crystal field splitting in the substitutional tetrahedral site favoured for the singly coordinated case. The results on these carefully matched implant profiles show that optical response is highly determined by the amount and ratio of erbium and oxygen present in the sample and ratios of O:Er greater than unity are severely detrimental to the Er emission. The most efficient luminescence is forty times higher than in silicon-on-insulator implanted with Er only. This super enhancement now offers a realistic route not only for optical communication applications but also for the implementation of silicon photonic integrated circuits for sensing, biomedical instrumentation and quantum communication.

Published

2016

3. Crystal field analysis of Dy and Tm implanted silicon for photonic and quantum technologies.

Author

Hughes MA, Lourenço MA, Carey JD, Murdin B, and Homewood KP

Subjects

Crystallization, Luminescence, Static Electricity, Thermodynamics, Dysprosium chemistry, Photons, Quantum Theory, Silicon chemistry, Thulium chemistry

Abstract

We report the lattice site and symmetry of optically active Dy 3+ and Tm 3+ implanted Si. Local symmetry was determined by fitting crystal field parameters (CFPs), corresponding to various common symmetries, to the ground state splitting determined by photoluminescence measurements. These CFP values were then used to calculate the splitting of every J manifold. We find that both Dy and Tm ions are in a Si substitution site with local tetragonal symmetry. Knowledge of rare-earth ion symmetry is important in maximising the number of optically active centres and for quantum technology applications where local symmetry can be used to control decoherence.

Published

2014

4. n-type chalcogenides by ion implantation.

Author

Hughes MA, Fedorenko Y, Gholipour B, Yao J, Lee TH, Gwilliam RM, Homewood KP, Hinder S, Hewak DW, Elliott SR, and Curry RJ

Abstract

Carrier-type reversal to enable the formation of semiconductor p-n junctions is a prerequisite for many electronic applications. Chalcogenide glasses are p-type semiconductors and their applications have been limited by the extraordinary difficulty in obtaining n-type conductivity. The ability to form chalcogenide glass p-n junctions could improve the performance of phase-change memory and thermoelectric devices and allow the direct electronic control of nonlinear optical devices. Previously, carrier-type reversal has been restricted to the GeCh (Ch=S, Se, Te) family of glasses, with very high Bi or Pb 'doping' concentrations (~5-11 at.%), incorporated during high-temperature glass melting. Here we report the first n-type doping of chalcogenide glasses by ion implantation of Bi into GeTe and GaLaSO amorphous films, demonstrating rectification and photocurrent in a Bi-implanted GaLaSO device. The electrical doping effect of Bi is observed at a 100 times lower concentration than for Bi melt-doped GeCh glasses.

Published

2014

5. High temperature luminescence of Dy3+ in crystalline silicon in the optical communication and eye-safe spectral regions.

Author

Lourenço MA, Mustafa Z, Ludurczak W, Wong L, Gwilliam RM, and Homewood KP

Abstract

We report on photoluminescence in the 1.3 and 1.7 μm spectral ranges in silicon doped with dysprosium. This is attributed to the Dy3+ internal transitions between the second Dy3+ excited state and the ground state, and between the third Dy3+ excited state and the ground state. Luminescence is achieved by Dy implantation into Si substrates codoped with boron, to form dislocation loops, and show a strong dependence on fabrication process. The spectra consist of several sharp lines with the strongest emission at 1736 nm, observed up to 200 K. No Dy3+ luminescence is observed in samples without B codoping, showing the paramount importance of dislocation loops to enable the Dy emission.

Published

2013

6. An efficient room-temperature silicon-based light-emitting diode.

Author

Ng WL, Lourenço MA, Gwilliam RM, Ledain S, Shao G, and Homewood KP

Abstract

There is an urgent requirement for an optical emitter that is compatible with standard, silicon-based ultra-large-scale integration (ULSI) technology. Bulk silicon has an indirect energy bandgap and is therefore highly inefficient as a light source, necessitating the use of other materials for the optical emitters. However, the introduction of these materials is usually incompatible with the strict processing requirements of existing ULSI technologies. Moreover, as the length scale of the devices decreases, electrons will spend increasingly more of their time in the connections between components; this interconnectivity problem could restrict further increases in computer chip processing power and speed in as little as five years. Many efforts have therefore been directed, with varying degrees of success, to engineering silicon-based materials that are efficient light emitters. Here, we describe the fabrication, using standard silicon processing techniques, of a silicon light-emitting diode (LED) that operates efficiently at room temperature. Boron is implanted into silicon both as a dopant to form a p-n junction, as well as a means of introducing dislocation loops. The dislocation loops introduce a local strain field, which modifies the band structure and provides spatial confinement of the charge carriers. It is this spatial confinement which allows room-temperature electroluminescence at the band-edge. This device strategy is highly compatible with ULSI technology, as boron ion implantation is already used as a standard method for the fabrication of silicon devices.

Published

2001

7. Interdiffusion of the group-III sublattice in In-Ga-As-P/In-Ga-As-P and In-Ga-As/In-Ga-As heterostructures.

Author

Rao SS, Gillin WP, and Homewood KP

Published

1994

8. Thermal quenching and retrapping effects in the photoluminescence of InyGa1-yAs/GaAs/AlxGa1-xAs multiple-quantum-well structures.

Author

Vening M, Dunstan DJ, and Homewood KP

Published

1993

9. Hydrostatic and uniaxial pressure coefficients of CdTe.

Author

Dunstan DJ, Gil B, and Homewood KP

Published

1988