Performance Optimization of Luminescent Solar Concentrators under Several Shading Conditions

Bernardoni, Paolo; Mangherini, Giulio; Gjestila, Marinela; Andreoli, A.; Vincenzi, D.

doi:10.3390/en14040816

Cited by 16 publications

(27 citation statements)

References 29 publications

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“…The main idea of this device is rather old [125], and is based on the absorption of re-emitted light on the edge of a large, flat absorbing layer that is enhanced by luminescent agents, which is presented in Figure 9. In this case, many authors proposed a thin concentrator structure with light trapping and guided light direction [127,128]. The effective advantages of this approach are the large optical absorption area of the luminescent layer and the limited costs, due to the low share of the semiconductor structure in the total module volume.…”

Section: Application In Lsc (Luminescent Solar Concentrator) Systemsmentioning

confidence: 99%

Review of Luminescence-Based Light Spectrum Modifications Methods and Materials for Photovoltaics Applications

Sibiński

2023

Materials

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The dynamic development of photovoltaic and photo-sensitive electronic devices is constantly stimulated by material and technological advances. One of the key concepts that is highly recommended for the enhancement of these device parameters is the modification of the insulation spectrum. Practical implementation of this idea, although difficult, may be highly beneficial for photoconversion efficiency, photosensitivity range extension, and their cost reduction. The article presents a wide range of practical experiments leading to the manufacturing of functional photoconverting layers, dedicated to low-cost and wide-scale deposition methods. Various active agents, based on different luminescence effects as well as the possible organic carrier matrixes, substrate preparation and treatment procedures, are presented. New innovative materials, based on their quantum effects, are examined. The obtained results are discussed in terms of the application in new generation photovoltaics and other optoelectronic elements.

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Section: Application In Lsc (Luminescent Solar Concentrator) Systemsmentioning

confidence: 99%

Review of Luminescence-Based Light Spectrum Modifications Methods and Materials for Photovoltaics Applications

Sibiński

2023

Materials

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“…The use of sidewall mirrors is discussed in more details in Ref. [50]. At a steady state, the emission losses for the EASSS and conventional LSC panels are 7.4 and 25.8%, respectively, resulting in a 24.8% improvement in emission efficiency.…”

Section: Performance Comparison: Easss Vs Conventional Lsc Panelsmentioning

confidence: 99%

Elliptic Array Luminescent Solar Concentrators for Combined Power Generation and Microalgae Growth

Talebzadeh

O’Brien

2021

Energies

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The full utilization of broadband solar irradiance is becoming increasingly useful for applications such as long-term space missions, wherein power generation from external sources and regenerative life support systems are essential. Luminescent solar concentrators (LSCs) can be designed to separate sunlight into photosynthetically active radiation (PAR) and non-PAR to simultaneously provide for algae cultivation and electric power generation. However, the efficiency of LSCs suffers from high emission losses. In this work, we show that by shaping the LSC in the form of an elliptic array, rather than the conventional planar configuration, emission losses can be drastically reduced to the point that they are almost eliminated. Numerical results, considering the combined effects of emission, transmission and surface scattering losses show the optical efficiency of the elliptic array LSC is 63%, whereas, in comparison, the optical efficiency for conventional planar LSCs is 47.2%. Further, results from numerical simulations show that elliptic array luminescent solar concentrators can convert non-PAR and green-PAR to electric power with a conversion efficiency of ~17% for AM1.5 and 17.6% for AM0, while transmitting PAR to an underlying photobioreactor to support algae cultivation.

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“…After a few decades of apparent waning interest, the advent of colloidal semiconductor quantum dots (QDs) as reabsorption-free NIR LSC emitters nearly a decade ago has revived research in the field, − leading to significant advances in power efficiency and device size, both of which are essential for real-world implementation. ,,− Important advances have been made in the design of so-called Stokes-shift-engineered QDs with large spectral separation between their absorption and photoluminescence (PL) spectra and in the development of industrial-scale fabrication protocols for QD-LSC waveguides. ,,− To date, the highest efficiencies have been achieved with I–III–VI 2 QDs such as CuInS 2 and related heterostructures (e.g., CuInS 2 /ZnS), which have a natural wide Stokes shift and NIR PL, ,,,− although important advances have also been demonstrated with binary chalcogenides − and metal halides. − Despite this progress in the design of LSC waveguides, very little has been done toward a real-world implementation of this technology, which necessarily involves an assessment of the impact of environmental factors on LSC performance, − which ultimately determines the relevance and type of encapsulation/protection required for operation in a real-world context. A compelling example of this is the effect of various types of dry or wet deposits on an LSC waveguide, which in addition to reducing the amount of solar light that can reach the waveguide and be converted into useful guided PLas it commonly occurs for direct charge generation in conventional PV modulescan also affect the transport of light energy to the device edges by disrupting the waveguiding by total internal reflection.…”

Section: Introductionmentioning

confidence: 99%

Environmental Effects on the Performance of Quantum Dot Luminescent Solar Concentrators

Siripurapu,

Meinardi,

Brovelli

et al. 2023

ACS Photonics

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Luminescent solar concentrators (LSCs) are all-photonic, semitransparent solar devices with great potential in the emerging fields of building-integrated photovoltaics and agrivoltaics. Over the past decade, particularly with the advent of quantum dot (QD) LSCs, tremendous progress has been made in terms of photovoltaic efficiency and device size by increasing solar spectral coverage and suppressing reabsorption losses. Despite these advances in LSC design, the effects of environmental conditions such as rain, dust, and dirt deposits, which are ubiquitous in both urban and agricultural environments, on LSC performance have been largely overlooked. Here, we address these issues by systematically investigating the environmental effects on the solar harvesting and waveguiding capability of state-of-the-art QD-LSCs, namely, the presence of airborne pollutants (dust), water droplets, and dried deposits. Our results show that dust is unexpectedly insignificant for the waveguiding of the concentrated luminescence and only reduces the LSC efficiency through a shadowing effect when deposited on the outer surface, while dust accumulation on the inner LSC side increases the output power due to backscattering of transmitted sunlight. Water droplets, on the other hand, do not dim the incident sunlight, but are detrimental to waveguiding by forming an optical interface with the LSC. Finally, dried deposits, which mimic the evaporation residues of heavy rain or humidity, have the worst effect of all, combining shading and waveguide losses. These results are relevant for the design of application-specific surface functionalization/protection strategies real LSC modules.

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Performance Optimization of Luminescent Solar Concentrators under Several Shading Conditions

Cited by 16 publications

References 29 publications

Review of Luminescence-Based Light Spectrum Modifications Methods and Materials for Photovoltaics Applications

Review of Luminescence-Based Light Spectrum Modifications Methods and Materials for Photovoltaics Applications

Elliptic Array Luminescent Solar Concentrators for Combined Power Generation and Microalgae Growth

Environmental Effects on the Performance of Quantum Dot Luminescent Solar Concentrators

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