Quantum Dot Sensitized Solar Cell: Photoanodes, Counter Electrodes, and Electrolytes
Abstract
:1. Introduction
2. Quantum Dot Sensitized Solar Cells (QDSSCs) Based on Single Quantum Dots (QDs) Photoanode
2.1. A Review on QDSSCs Based on Single QDs
2.2. The Causes of Low QDSSCs’ PCE and Solutions
- a.
- Low fill factor
- b.
- Impaired electrolyte
- A dynamic balance is existed in the S2−/Sn2− aqueous electrolyte:
- Electron–hole pairs are generated after CdSe QDS are photoexcited by possibly the following equations:
- Reaction at the CdSe/electrolyte interface:
- The S2−/Sn2− strongly obstructs the hole movement from CdSe QDs into the electrolyte [27] as described in Equation (4) and S−* is in an excited ion.
- c.
- Strong recombination processes
- d.
- Shortage of binding agents between QDs and TiO2 membrane
3. QDSSCs Based on Photoanode Binding Agents
4. QDSSCs Based on a Photoanode with a Passive Surfactant
5. QDSSCs Based on a Photoanode with Multilayer QDs
6. QDSSCs Based on a Photoanode with Doped QDs
7. QDSSCs Based on Different Counter Electrodes
8. QDSSCs Based on Different Electrolytes
9. Opportunities and Challenges
- a.
- QDSSCs based on QDs possessing intermediate band (IB)
- b.
- Graphene thin film with QDs for photoanode fabrication
Author Contributions
Funding
Conflicts of Interest
References
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Metal Oxide Layer | QDs | Counter Electrode | Electrolyte | Synthesis Method | FF (%) | PCE (%) | Ref |
---|---|---|---|---|---|---|---|
TiO2 | CdS | Pt | KCl+Na2S | SILAR | - | - | [61] |
TiO2 | CdSe | Pt | [Fe(CN)6]3−/4− | CBD | - | - | [62] |
TiO2 | CdSe | Pt | Na2S+Na2SO4 | CBD | - | - | [63] |
TiO2 | CdS | Pt | Na2SO3 | CBD | - | - | [64] |
TiO2 | CdSe | Pt | Polysulfide | CBD | 59 | 1.03 | [65] |
TiO2 | CdSe | Pt | Na2S | CBD | 40 | 0.7 | [66] |
TiO2 | CdSe | Pt | Na2S | CBD | 27.7 | 0.84 | [67] |
TiO2 | CdSe | Pt | Na2S+S+NaOH | CBD | 43 | 0.4 | [68] |
TiO2 | CdS | Pt | LiI+I2+DMPII+TPB | CBD | 70 | 0.3 | [69] |
TiO2 | CdSe | Pt | LiI+I2+HMII+TPB | CBD, Linker | 56.3 | 1.19 | [70] |
TiO2 | CdS/CdSe | Pt | Na2S+S | CBD | 41.5 | 1.42 | [71] |
TiO2 | CdS | Pt | KCl+Na2S | SILAR | - | - | [72] |
TiO2 | CdS/CdSe | Pt | Na2S+S+KCl | SILAR | 36 | 1.14 | [73] |
TiO2 | CdS/ZnSe | Pt | Thiourea | CBD, Linker | 58 | 0.86 | [74] |
TiO2 | CdS/CdSe | Pt | Na2S+S+KCl | CBD | 37 | 1.33 | [75] |
TiO2 | CdS/CdSe/ZnS | CuS, CoS | Polysulfide | SILAR | 35 | 2.7 | [76] |
TiO2 | CdS/ZnS | Pt | Sulfide | SILAR | 46 | 1.72 | [77] |
TiO2/ZnS | CdS/CdSe | Cu2S | Na2S+S | SILAR | 66 | 4.21 | [78] |
TiO2 | CdS/CuInS2 | Carbon | Na2S+S | Colloid | 37 | 1.47 | [79] |
TiO2 | CdS/JK24 | Pt | Na2S+S | Colloid | 38.2 | 1.18 | [80] |
Graphene-TiO2 | CdS | Pt | Na2S+S | Colloid | 41 | 1.31 | [81] |
TiO2 | CdS/CdSe | Pt | Na2S+S+KCl | SILAR | 36 | 1.14 | [73] |
TiO2 | CdS/ZnSe | Pt | Thiourea | CBD, Linker | 58 | 0.86 | [74] |
QDSSCs | RD (Ω) | Rd (Ω) | RS (Ω) | RSH (Ω) | PCE η (%) |
---|---|---|---|---|---|
1-h soaked TiO2/CdSe | 1230.0 | 498.0 | 732.0 | 239.0 | 0.020 |
10-h soaked TiO2/CdSe | 538.2 | 382.0 | 156.2 | 588.1 | 0.046 |
18-h soaked TiO2/CdSe | 157.3 | 83.1 | 74.2 | 2027.0 | 0.184 |
20-h soaked TiO2/CdSe | 60.8 | 33.2 | 27.4 | 5396.0 | 0.575 |
24-h soaked TiO2/CdSe | 136.5 | 80.0 | 56.5 | 2130.0 | 0.150 |
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Chung, N.T.K.; Nguyen, P.T.; Tung, H.T.; Phuc, D.H. Quantum Dot Sensitized Solar Cell: Photoanodes, Counter Electrodes, and Electrolytes. Molecules 2021, 26, 2638. https://doi.org/10.3390/molecules26092638
Chung NTK, Nguyen PT, Tung HT, Phuc DH. Quantum Dot Sensitized Solar Cell: Photoanodes, Counter Electrodes, and Electrolytes. Molecules. 2021; 26(9):2638. https://doi.org/10.3390/molecules26092638
Chicago/Turabian StyleChung, Nguyen Thi Kim, Phat Tan Nguyen, Ha Thanh Tung, and Dang Huu Phuc. 2021. "Quantum Dot Sensitized Solar Cell: Photoanodes, Counter Electrodes, and Electrolytes" Molecules 26, no. 9: 2638. https://doi.org/10.3390/molecules26092638
APA StyleChung, N. T. K., Nguyen, P. T., Tung, H. T., & Phuc, D. H. (2021). Quantum Dot Sensitized Solar Cell: Photoanodes, Counter Electrodes, and Electrolytes. Molecules, 26(9), 2638. https://doi.org/10.3390/molecules26092638