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Article

Mapping the Surface Heat of Luminescent Solar Concentrators

by
Yujian Sun
1,
Yongcao Zhang
2 and
Yilin Li
3,*
1
Department of Earth and Environmental Engineering, Columbia University, New York, NY 10027, USA
2
Physical Sciences and Engineering Division, King Abdullah University of Science and Technology, Jeddah 23955, United Arab Emirates
3
Department of Chemical and Biomolecular Engineering, Rice University, Houston, TX 77005, USA
*
Author to whom correspondence should be addressed.
Optics 2021, 2(4), 259-265; https://doi.org/10.3390/opt2040024
Submission received: 7 October 2021 / Revised: 2 November 2021 / Accepted: 10 November 2021 / Published: 16 November 2021
(This article belongs to the Special Issue Novel Research on Solar Photothermal Technology: Theory, Design, System and Applications)
Browse Figures
Versions Notes

Abstract

:
Luminescent solar concentrators (LSCs) have been widely studied for their potential application as building-integrated photovoltaics (BIPV). While numerous efforts have been made to improve the performance, the photothermal (PT) properties of LSCs are rarely investigated. In this report, we studied the PT properties of an LSC with a power conversion efficiency (PCE) of 3.27% and a concentration ratio of 1.42. The results showed that the total PT power of the LSC was 13.2 W, and the heat was concentrated on the edge of the luminescent waveguide with a high heat power density of over 200 W m−2.

1. Introduction

The practical integration of conventional solar panels with architectures such as buildings and other physical structures remains challengeable due to the design limitations of conventional solar panels such as shape, color, and transparency [1,2,3]. The approach of luminescent solar concentrators (LSCs) as building-integrated photovoltaics (BIPV) is considered promising for circumventing the practical issues of conventional solar panels because solar cells are placed on the edge of the luminescent waveguide in LSCs [4,5,6]. With this design, the shape of LSCs can be arbitrary, and the color and transparency can be tuned by the properties of the luminophores in the waveguide [7,8,9]. The operational mechanism of LSCs is shown in Figure 1. A fraction of sunlight is absorbed by the luminophores and converted to luminescent light, which follows the successive total internal reflection (TIR) and travels to the solar cells that are placed on the edge of the waveguide. Studies have shown that LSCs can be operated under different light conditions [10,11] and utilized in other areas beyond architectures [12].
In recent years, the research focus on LSCs has mainly been on improving the photovoltaic (PV) performance of the devices, particularly the power conversion efficiency (PCE) [13,14,15], through developing novel luminophores [16,17,18] and optical techniques [19,20,21]. These approaches mainly focused on improving the photon collecting and transporting efficiencies of the LSCs, while little attention was paid to making use of the photon energy loss. In LSCs, a significant amount of photon energy loss was through the photothermal (PT) process. Therefore, it is of great importance to study the PT properties of LSCs and find solutions to utilize the PT energy. Recently, our team performed a preliminary investigation of the PT properties of LSCs through Monte Carlo ray-tracing simulations [22]. We showed that the PCE could also be improved through the utilization of PT energy by thermoelectric devices that have been widely developed [23,24,25]. In this report, we further studied the PT properties of LSCs through the surface heat map. The results indicated that the heat concentrated on the edge of the luminescent waveguide, suggesting that LSCs could also be applied as PT energy concentrators. This study would guide the design of novel LSCs that include PT energy utilization.

2. Experimental Section

2.1. Device Fabrication

In this study, we fabricated an LSC with dimensions of 200 mm × 200 mm × 5 mm. The fabrication procedure occurred according to our previous reports [26,27,28]. We used 4-(dicyanomethylene)-2-tert-butyl-6-(1,1,7,7-tetramethyljulolidin-4-yl-vinyl)-4H-pyran (DCJTB) as the luminophores [29,30] in the waveguide and attached gallium arsenide (GaAs) solar cells to the edge of the waveguide [31]. The concentration of DCJTB was 60 ppm. The dimensions of the waveguide were 200 mm × 200 mm × 5 mm, and those of the solar cells were 200 mm × 5mm. All four edges of the waveguide were covered by the solar cells. The solar cells were connected in parallel.

2.2. Device Characterization

The absorption and emission spectra of DCJTB in the waveguide were measured using a Varian Cary 5000 UV-visible-NIR spectrometer and an ISS PC1 photon-counting spectrofluorometer, respectively. The photoluminescence quantum yield (PLQY) of DCJTB was measured using an integrating sphere connected to a Hamamatsu C9920-12 external quantum efficiency (EQE) measurement system. The PV properties of the solar cells and the LSC were measured under ambient conditions [32]. The I–V curves of the solar cells and the LSC were measured with a Keithley 2401 Sourcemeter. The EQE of the solar cells and the LSC were measured on an Enlitech QE-R3011 system. The AM1.5G sunlight (1000 W m−2) was provided by an OAI class AAA solar simulator.

2.3. Ray-Tracing Simulation

The ray-tracing simulation was performed using a commercial Monte Carlo ray-tracing service provided by Solarathlon. Details about the simulation cannot be disclosed according to the service policy. The service was customized to obtain the internal and surface heat maps of the luminescent waveguide.

3. Results and Discussion

3.1. Spectroscopic and PV Properties

We first characterized the spectroscopic properties of DCJTB in the LSC and the PV properties of the GaAs solar cells and the LSC, which were recommended by the LSC research community in a recent paper [33]. Figure 2a shows the normalized absorption and emission spectra of DCJTB in the LSC. The absorption spectrum of DCJTB was maximized at 494 nm and covered the wavelength range until 600 nm. The emission spectrum of DCJTB was maximized at 598 nm, and the Stokes shift was 104 nm. Figure 2b depicts the results for the PLQY of DCJTB in the LSC. PLQY was defined as the ratio between the number of emitted photons (Nem) and the number of absorbed photons (Nabs), which was 0.80 [34]. The PV properties of the GaAs solar cells are shown in Figure 2c,d. For four parallelly connected solar cells with a total area of 0.004 m2 (= 200 mm × 5 mm × 4), the I-V measurement provided a short-circuit current (Isc) of 1.11 A, an open-circuit voltage (Voc) of 1.03 V, and a fill factor (FF) of 0.80, which led to a maximum electric power (Pmax) of 0.92 W and a PCE of 23%. The external quantum efficiency (EQE) of the GaAs solar cells exhibited a strong spectral response of over 0.85 from 500 nm to 850 nm. The integrated short-circuit current density (Jsc) (i.e., integration of EQE with AM1.5G solar spectrum along the wavelength) was 278.32 A m−2, which was consistent with that from the I-V measurement (277.5 A m−2 = 1.11 A/0.004 m2). The PV properties of the LSC are depicted in Figure 2e,f. When the GaAs solar cells were attached to the luminescent waveguide, the resulting LSC with an area of 0.04 m2 (= 200 mm × 200 mm) exhibited an Isc of 1.54 A, a Voc of 1.05 V, and an FF of 0.81, which led to a Pmax of 1.31 W and a PCE of 3.27%. The concentration ratio, defined as the electrical power of the LSC relative to that of the solar cells, was 1.42 (=1.31 W/0.92 W), which indicated that the luminescent waveguide was a light concentrator for the GaAs solar cells. The lower PCE of the LSC compared with the PCE of the GaAs solar cells was due to the low Jsc of the LSC (38.5 A m−2 = 1.54 A/0.04 m2). The EQE of the LSC before 600 nm was due to the absorption of DCJTB, while that after 600 nm was due to the scattering effects in the luminescent waveguide [35,36,37]. The integrated Jsc of the LSC was 38.26 A m−2. A Monte Carlo ray-tracing simulation was performed to obtain the PCE of the LSC. The simulation provided a PCE of 3.3%, which was in good agreement with the experimental value (3.27%).

3.2. PT Properties

The PT properties of the LSC were studied using the Monte Carlo ray-tracing simulation. We believed that using the approach of ray-tracing was better than that of radiative heat transfer because the latter required the spatial distribution of the energy generated inside the LSC, which was typically difficult to obtain. It would have been useful to study and understand the LSC through a simulation before the experiments were performed. The PT energy is typically from the energy loss inside the luminescent waveguide, which consists of the loss due to the relaxation energy of the luminophores and the loss due to the photon absorbance of the host matrix. In the simulation, the LSC was configured with five layers of equal thickness, as shown in Figure 3a, and the map of the PT power of each layer was calculated. The results in Figure 3b–f indicated that the PT power was uniformly distributed in each layer. This possibly further indicated that the PT power in the LSC was one-dimensionally vertically distributed. The top layer (L1) possessed the highest PT power of 7.05 W, while the bottom layer (L5) possessed the lowest PT power of 1.08 W. This was because more photons were absorbed, and thus more PT energy was released, in the top layer than the bottom layer. The total PT power of the LSC was 13.2 W, which was much higher than the Pmax of the LSC (1.31 W) and suggestive of a promising energy source for electric power generation in addition to the electric power from the PV conversion. Considering the PT power produced by the LSC per volume of the LSC, the PT power per volume from the LSC in this study (6.6 × 104 W m−3) was higher than that in our previous report (6.01 × 104 W m−3) [22].

3.3. Surface Heatmap

The PT energy inside the LSC should transfer to the surface of the luminescent waveguide in order to be utilized. Here, we calculated the surface heat map of the LSC. Figure 4 depicts the definition of the surface of the LSC and the surface heat map. The heat power density for each surface from 1 to 6 was 226, 226, 150, 225, 225, and 158 W m−2, respectively. The results showed that the edge surfaces of the luminescent waveguide exhibited a much higher heat power density than the top and bottom surfaces. Differences at the junction of the surfaces were due to different boundary conditions that were used in the simulation. This indicated that the edge-attached solar cells would be heated during the operation of the LSC and that the performance of the solar cells would be affected. However, if the thermal energy at the edge of the luminescent waveguide was properly utilized, for example by thermoelectric devices, additional electric power could be produced by the LSC.

4. Conclusions

In this study, we used DCJTB and GaAs solar cells to fabricate an LSC with dimensions of 200 mm × 200 mm × 5 mm. The PV properties of the LSC were characterized, and the device showed a PCE of 3.27% and a concentration ratio of 1.42. We performed a Monte Carlo ray-tracing simulation to investigate the PT properties of the LSC. The total PT power was 13.2 W, which was much higher than the PV power (1.31 W). The surface heat map of the LSC was further investigated, and the results revealed that the heat was concentrated on the edge of the luminescent waveguide, with a high heat power density of over 200 W m−2. This suggested that the thermoelectric devices could be mounted on the edge of the luminescent waveguide associated with the solar cells to produce electricity. We believed that the results in this study would benefit the development of LSCs. The revealed PT properties provided fundamental insights for the utilization of the PT energy of LSCs. One of the direct benefits would be the improvement of the PCE of LSCs. Further work will focus on developing approaches to integrating thermoelectric devices into LSCs and on performance studies.

Author Contributions

Conceptualization, Y.L.; investigation, Y.S.; resources, Y.S.; software, Y.Z.; writing—original draft, Y.S.; writing—review & editing, Y.Z. and Y.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

This work is a part of the project Energy-Harvesting Windows and Panels. The authors would like to thank Solera City Energy for the research support and Solarathlon for the simulation service.

Conflicts of Interest

The authors declare no conflict of interest.

Nomenclature and Abbreviations

BIPVbuilding-integrated photovoltaics
DCJTB4-(dicyanomethylene)-2-tert-butyl-6-(1,1,7,7-tetramethyljulolidin-4-yl-vinyl)-4H-pyran
EQEexternal quantum efficiency
FFfill factor
GaAsgallium arsenide
Iscshort-circuit current
Jscshort-circuit current density
LSCluminescent solar concentrator
Nabsnumber of absorbed photons
Nemnumber of emitted photons
PCEpower conversion efficiency
PLQYphotoluminescence quantum yield
Pmaxmaximum electric power
PTphotothermal
PVphotovoltaic
TIRtotal internal reflection
Vocopen-circuit voltage

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Figure 1. The operational mechanism of luminescent solar concentrators (LSCs).
Figure 1. The operational mechanism of luminescent solar concentrators (LSCs).
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Figure 2. (a) Normalized absorption and emission spectra and (b) results for the PLQY of DCJTB in the LSC. Results for the (c) I–V and (d) EQE measurements of the GaAs solar cells. Results for (e) the I–V and (f) the EQE measurements of the LSC.
Figure 2. (a) Normalized absorption and emission spectra and (b) results for the PLQY of DCJTB in the LSC. Results for the (c) I–V and (d) EQE measurements of the GaAs solar cells. Results for (e) the I–V and (f) the EQE measurements of the LSC.
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Figure 3. (a) Layer configuration of the LSC, and (bf) heat maps of the layers (color bars with the unit of W).
Figure 3. (a) Layer configuration of the LSC, and (bf) heat maps of the layers (color bars with the unit of W).
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Figure 4. Surface heat map of the LSC (color bars with the unit of W m−2).
Figure 4. Surface heat map of the LSC (color bars with the unit of W m−2).
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Sun, Y.; Zhang, Y.; Li, Y. Mapping the Surface Heat of Luminescent Solar Concentrators. Optics 2021, 2, 259-265. https://doi.org/10.3390/opt2040024

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Sun Y, Zhang Y, Li Y. Mapping the Surface Heat of Luminescent Solar Concentrators. Optics. 2021; 2(4):259-265. https://doi.org/10.3390/opt2040024

Chicago/Turabian Style

Sun, Yujian, Yongcao Zhang, and Yilin Li. 2021. "Mapping the Surface Heat of Luminescent Solar Concentrators" Optics 2, no. 4: 259-265. https://doi.org/10.3390/opt2040024

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