Tackling self-absorption in luminescent solar concentrators with type-II colloidal quantum dots

Krumer, Zachar; Pera, Suzanne J.; Moes, Relinde J. A. van Dijk; Zhao, Yiming; Brouwer, Sander de; Groeneveld, Esther; Sark, W.G.J.H.M. van; Schropp, R.E.I.; Donegá, Celso de Mello

doi:10.1364/pv.2012.pw2b.3

Cited by 20 publications

(32 citation statements)

References 36 publications

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“…Even in an idealized LSC with only escape cone losses, the trapping probability for every emitted photon is P trap = 1 -P cone = 0.75. Consequently, for a given input energy flux Φ in the output flux Φ out decreases after an average of N−1 reabsorptions per photon to [4]:…”

Section: Addressing Re-absorptoinmentioning

confidence: 99%

“…Self-absorption occurs when there is a finite probability for a luminescent species to absorb the light emitted by the same species. This is visualized in an overlap between the spectra of absorption A(λ) and emission F(λ), quantified as self-absorption cross section σ SA per 1 cm optical path [4]:…”

Section: Addressing Re-absorptoinmentioning

confidence: 99%

“…Measurements of self-absorption effects for some dyes and nanocrystals were conducted with a position-adjustable excitation source that illuminates different spots in the 978-1-4799-4398-2/14/$31.00 ©2014 IEEE material so that the optical path length travelled by the emitted light inside the luminescent solution can be varied [4]. The self-absorption crosssection of Rhodamine 6G (LQE=95%) and Lumogen Orange (LQE=95%) were calculated to be 8.5% and 6.7%, respectively.…”

Section: Addressing Re-absorptoinmentioning

confidence: 99%

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Luminescent Solar Concentrators: The route to 10% efficiency

Sark

Krumer

Donegá

et al. 2014

2014 IEEE 40th Photovoltaic Specialist Conference (PVSC)

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Luminescent solar concentrators consist of a highly transparent plastic plate, in which luminescent species are dispersed, which absorb incident light and emit light at a red-shifted wavelength, with high quantum efficiency. Fundamental issues have hampered efficiency improvements, in particular re-absorption of light emitted by luminescent species due to small Stokes' shifts and stability of these species. In this contribution, we will address recent advances to minimize reabsorption, which would allow surpassing the 10% luminescent solar concentrator efficiency

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Section: Addressing Re-absorptoinmentioning

confidence: 99%

Section: Addressing Re-absorptoinmentioning

confidence: 99%

Section: Addressing Re-absorptoinmentioning

confidence: 99%

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Luminescent Solar Concentrators: The route to 10% efficiency

Sark

Krumer

Donegá

et al. 2014

2014 IEEE 40th Photovoltaic Specialist Conference (PVSC)

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“…New nanocrystal-based luminophores are under development that allow for larger sizes at high device efficiencies. [10][11][12][13][14][15] Most of LSC applications are in the phase of research, testing, or validation. At the moment, LSC devices are tested to replace sound barriers in Den Bosch, the Netherlands [16] or be used as roof tiles, [17] and, interestingly, as miniature chemical reactors.…”

Section: Introductionmentioning

confidence: 99%

The “Electric Mondrian” as a Luminescent Solar Concentrator Demonstrator Case Study

et al. 2017

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Inspired by the works of the Dutch artist Piet Mondrian an Electric Mondrian has been developed built up from luminescent solar concentrator elements. It is based on differently colored square and rectangular elements of standard sizes based on multiples of 15 cm, as this the standard size of the c‐Si cells that are used at the sides of the elements. This paper describes the design requirements and choices that have been made in detail. The design is based on commercially available luminescent concentrator Perspex plates and solar cells. Performance testing showed that at total size of 1 m2 a light‐to‐electric power device efficiency is measured of 0.2%: the Electric Mondrian thus provides ∼2 W in full sun, and two mobile devices can be charged directly or via a built‐in battery. The Electric Mondrian functions as a decorative energy‐harvesting element indoors in the urban environment, and can be marketed as such.

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“…Another part is guided to the solar cell by total internal reflection. 4 as low as possible. Third, near-unity luminescence quantum efficiency (LQE) is required.…”

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confidence: 99%

Will luminescent solar concentrators surpass the 10% device efficiency limit?

Sark¹

2014

SPIE Newsroom

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Will luminescent solar concentrators surpass the 10% device efficiency limit? Wilfried van Sark Nanosized particles with low overlap between their absorption and emission spectra allow more of the sun's light energy to be captured. Solar photovoltaic (PV) technology is continuously increasing conversion efficiency while reducing cost. It has been sufficiently successful that by the end of 2013, installed capacity worldwide had reached 134GW, 1 with 90% of market share made up of technology based on crystalline silicon (c-Si) wafers installed on rooftops (up to several kilowatts) or fields (tens to hundreds of megawatts). Despite this, PV still has a long way to go to reach multiterawatt capacity and play a significant role in our future electricity supply. Many alternative technologies are under development that will compete with standard c-Si technology, such as inorganic thin films, but also systems that concentrate light to a high (1000 times) or low (up to 10 times) extent. One such development is luminescent solar concentrators (LSCs), which are low concentration and relatively low cost, and they can also be shaped and colored. As a consequence, they are suitable for use as building façade elements with aesthetically appealing surfaces of variable shape and color. LSCs began to be developed in the 1970s as an alternative approach for reducing PV technology costs. 2, 3 In LSCs, both direct and diffuse light is concentrated by a factor of 5-10. LSCs typically consist of a plastic plate, in which luminescent species are dispersed. These species absorb incident light and emit light at a wavelength that is a red-shifted with respect to the absorbed wavelength, as a result of the Stokes' shift of the particular luminescent species. The majority of the emission (some is lost) is guided by total internal reflection to a solar cell at the side (see Figure 1). 4 Ideally, an LSC should fulfill six requirements. 5, 6 First, it should absorb all photons with wavelength >950 nm and emit them red-shifted at 1000 nm for use with c-Si solar cells. Second, it should have minimal spectral overlap between absorption and emission spectra to keep re-absorption losses

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Tackling self-absorption in luminescent solar concentrators with type-II colloidal quantum dots

Cited by 20 publications

References 36 publications

Luminescent Solar Concentrators: The route to 10% efficiency

Luminescent Solar Concentrators: The route to 10% efficiency

The “Electric Mondrian” as a Luminescent Solar Concentrator Demonstrator Case Study

Will luminescent solar concentrators surpass the 10% device efficiency limit?

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