Nanoparticle Scattering for Multijunction Solar Cells: The Tradeoff Between Absorption Enhancement and Transmission Loss

Mellor, A.; Hylton, Nicholas P.; Hauser, Hubert; Thomas, Tomos; Lee, Kan‐Hua; Al-Saleh, Y.; Giannini, Vincenzo; Braun, Avi; Loo, Josine; Vercruysse, Dries; Dorpe, Pol Van; Bläsi, Bénédikt; Maier, Stefan A.; Ekins-Daukes, N. J.

doi:10.1109/jphotov.2016.2601944

Cited by 13 publications

(11 citation statements)

References 36 publications

(46 reference statements)

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“…The amelioration of the shear-induced migration of particles in planar channel flows is demonstrated by the use of a DEM simulation framework that uses particle collisional dynamics in the presence of the fluid lubrication and viscous drag forces, which also allows for the implicit consideration of the surface roughness of particles through the D/(h + h 0 ) ratio. The simulation results presented in Figures 5 and 6 demonstrate convincingly that the particle-particle and particle-wall thermal and electrical conduction processes are controlled effectively, and could be enhanced to suit practical purposes such as in electrode charging in fuel cells (Canizares et al 2007) [28] and photovoltaic cells for solar energy storage (Mellor et al 2016) [29] by manipulating the Brownian motion of the sub-micron particles. Conversely, the Brownian motion could be arrested to a measure to reduce the particle/wall friction experienced in micro-fluidic flows such as in the targeted introduction of bio-pharmaceuticals in the bloodstream, see Pele et al (2015) [30].…”

Section: Discussionmentioning

confidence: 71%

Improving Conductivity in Nano-Conduit Flows by Using Thermal Pulse-Induced Brownian Motion: A Spectral Impulse Intensity Approach

Tüzün

2019

Applied Sciences

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Featured Application: Nanoparticle suspensions are used in a variety of applications involving the transport of reagents and products to and from structured material surfaces. The more efficient alignment of particle layers adjacent to, and in contact with, a reactive surface, such as found in a fuel cell, bio-medical and electrochemical device, is often reliant upon the effective control of the dynamics of particle assembly in narrow conduits. One such control is possible by spectral thermal pulsing to generate a controlled Brownian motion of particles. This is demonstrated by numerical simulation here to be highly effective when particles are conveyed in viscous fluids close to a neutrally buoyant condition. Abstract: Inter-particle and particle-wall connectivity in suspension flow has profound effects on thermal and electrical conductivity. The spectral impulse generation and the imparting of kinetic energy on the particles is shown through a mathematical analysis to be effective as a means of achieving an approximate equivalent of a Langevin thermostat. However, with dilute suspensions, the quadratic form of the thermal pulse spectra is modified with a damping coefficient to achieve the desired Langevin value. With the dense suspension system, the relaxation time is calculated from the non-linear differential equation, and the fluid properties were supported by the viscosity coefficient. A "smoothed" pulse is used for each time-step of the flow simulation to take care of the near-neighbor interactions of the adjacent particles. An approximate optimal thermostat is achieved when the number of extra pulses introduced within each time step is found to be nearly equal to the co-ordination number of each particle within the assembly. Furthermore, the ratio of the particle kinetic energy and the thermal energy imparted is found to be never quite equal to unity, as they both depend upon the finite values of the pulse duration and the relaxation time.well as providing uniform surface scaffolds for varied environmental emission detection and separation devices. Previous work using pore-scale CFD simulations (see for example Crevacore et al. 2017) [3] has investigated the effects of varying the direction of the acceleration due to gravity on colloidal suspensions from orthogonal to parallel to the fluid flow direction, and the resulting impact on Brownian motion and particle settling.Albert Einstein (1956) [4] formulated the mathematical framework for the kinetics of the Brownian motion of particles in suspension by considering the auto-correlation of fluctuating velocities and the spectral density of the intensity of fluctuations. It is possible to augment the physics of pressure-driven dense assembly flows of near-neutrally buoyant particles by combining the effects of (i) the lubrication forces due to the conveying fluid-immersed particle interactions and (ii) the drag forces due to fluid viscosity with those due to (iii) the thermal pulse-induced Brownian motion of particles.In a series of DEM simulations of sub-mi...

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Section: Discussionmentioning

confidence: 71%

Improving Conductivity in Nano-Conduit Flows by Using Thermal Pulse-Induced Brownian Motion: A Spectral Impulse Intensity Approach

Tüzün

2019

Applied Sciences

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“…However, this comes at an even greater loss in transmission into the solar cell, yielding an overall loss. This study is expanded on in a pending journal paper [8]. …”

Section: A Structure 1 -Nanoparticles Embedded In Arcmentioning

confidence: 99%

Improving the radiation hardness of space solar cells via nanophotonic light trapping

Mellor

Hylton

Wellens

et al. 2016

2016 IEEE 43rd Photovoltaic Specialists Conference (PVSC)

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-We show that the radiation-hardness of space solar cells can be significantly improved by employing nanophotonic light trapping. Two light-trapping structures are investigated in this work. In the first, an array of Al nanoparticles is embedded within the anti-reflection coating of a GaInP/InGaAs/Ge solar cell. A combined experimental and simulation study shows that this structure is unlikely to lead to an improvement in radiation hardness. In the second, a diffractive structure is positioned between the middle cell and the bottom cell. Computational results, obtained using an experimentally validated electro-optical simulation tool, show that a properly designed light-trapping structure in this position can lead to a relative 10% improvement in the middle-cell photocurrent at end-of-life.

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“…In recent work, we investigated the use of Al nanoparticle arrays embedded in the antireflection coating (ARC) of a InGaP/Ga(In)As/Ge solar cell as a means of improving the photocurrent in a thinned Ga(In)As subcell [20]. The presence of the nanoparticle array was found to improve the carrier collection efficiency, but also reduce transmission into the solar cell (see also Ref.…”

Section: Introductionmentioning

confidence: 99%

“…The performance of the solar cell is investigated using electrooptical simulation method, which is described in Section 2, and that has been experimentally validated in Ref. [20]. In Section 3, the simulation method is used to predict the enhancement that can be achieved in the Ga(In)As subcell of a InGaP/Ga(In)As/Ge solar cell.…”

Section: Introductionmentioning

confidence: 99%

Interstitial light-trapping design for multi-junction solar cells

Mellor

Hylton

Maier

et al. 2017

Solar Energy Materials and Solar Cells

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Nanoparticle Scattering for Multijunction Solar Cells: The Tradeoff Between Absorption Enhancement and Transmission Loss

Cited by 13 publications

References 36 publications

Improving Conductivity in Nano-Conduit Flows by Using Thermal Pulse-Induced Brownian Motion: A Spectral Impulse Intensity Approach

Improving Conductivity in Nano-Conduit Flows by Using Thermal Pulse-Induced Brownian Motion: A Spectral Impulse Intensity Approach

Improving the radiation hardness of space solar cells via nanophotonic light trapping

Interstitial light-trapping design for multi-junction solar cells

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