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On September 21, 2018, Science published an article title "Challenges for commercializing perovskite |
The stability ofperovskite solar cells (PSCs) has been considered as the largest obstacle totheir commercialization. Her... |
Hu,Y., Chu, Y., Wang, Q., Zhang, Z., Ming, Y., Mei, A., ... & Han, H. (2019).Standardizing Perovskite Solar Modules beyond Cells. Joule.
Wu,J., Zhang, Z., Tong, C., Li, D., Mei, A., Rong, Y., ... & Hu, Y. (2019).Two-stage melt processing of phase-pure selenium for printable triplemesoscopic solar cells. ACS applied materials & interfaces.
Ming,Y., Xu, M., Liu, S., Li, D., Wang, Q., Hou, X., ... & Han, H. (2019).Ethanol stabilized precursors for highly reproducible printable mesoscopicperovskite solar cells. Journal of Power Sources, 424, 261-267.
Yu,D., Hu, Y., Shi, J., Tang, H., Zhang, W., Meng, Q., ... & Tian, H. (2019).Stability improvement under high efficiency—next stage development ofperovskite solar cells. Science China Chemistry, 62(6), 684-707.
Cheng,Z., Mei, A., Cheng, Z., Gao, D., Li, S., Liu, S., ... & Han, H. (2019,May). Bridge from Visible Light Communication to Telecommunication viaPerovskite-Silicon Photonics. In CLEO: Applications and Technology(pp. JTh2A-56). Optical Society of America.
Hou,X., Xu, M., Tong, C., Ji, W., Fu, Z., Wan, Z., ... & Han, H. (2019). Highperformance printable perovskite solar cells based on Cs0. 1FA0. 9PbI3 inmesoporous scaffolds. Journal of Power Sources, 415, 105-111.
Liu,T., Xiong, Y., Mei, A., Hu, Y., Rong, Y., Xu, M., ... & Long, X. (2019).Spacer layer design for efficient fully printable mesoscopic perovskite solarcells. RSC Advances, 9(51), 29840-29846.
Tong,C., Ji, W., Li, D., Mei, A., Hu, Y., Rong, Y., & Han, H. (2019). Modelingthe edge effect for measuring the performance of mesoscopic solar cells withshading masks. Journal of Materials Chemistry A, 7(18), 10942-10948.
Wang,S., Jiang, P., Shen, W., Mei, A., Xiong, S., Jiang, X., ... & Han, H.(2019). A low-temperature carbon electrode with good perovskite compatibilityand high flexibility in carbon based perovskite solar cells. Chemicalcommunications, 55(19), 2765-2768.
Rong,Y., Hu, Y., Mei, A., Tan, H., Saidaminov, M. I., Seok, S. I., ... & Han, H.(2018). Challenges for commercializing perovskite solar cells. Science,361(6408), eaat8235.
Hu,Y., Zhang, Z., Mei, A., Jiang, Y., Hou, X., Wang, Q., ... & Han, H. (2018).Improved performance of printable perovskite solar cells with bifunctionalconjugated organic molecule. Advanced Materials, 30(11), 1705786.
Jiang,P., Jones, T. W., Duffy, N. W., Anderson, K. F., Bennett, R., Grigore, M., ...& Hong, L. (2018). Fully printable perovskite solar cells withhighly-conductive, low-temperature, perovskite-compatible carbon electrode. Carbon,129, 830-836.
Jiang,X., Xiong, Y., Zhang, Z., Rong, Y., Mei, A., Tian, C., ... & Liu, Q.(2018). Efficient hole-conductor-free printable mesoscopic perovskite solarcells based on SnO2 compact layer. Electrochimica Acta, 263,134-139.
Sheng,Y., Mei, A., Liu, S., Duan, M., Jiang, P., Tian, C., ... & Hu, Y. (2018).Mixed (5-AVA) x MA 1− x PbI 3− y (BF 4) y perovskites enhance the photovoltaicperformance of hole-conductor-free printable mesoscopic solar cells.Journal of Materials Chemistry A, 6(5), 2360-2364.
Xiong,Y., Liu, Y., Lan, K., Mei, A., Sheng, Y., Zhao, D., & Han, H. (2018). Fullyprintable hole-conductor-free mesoscopic perovskite solar cells based onmesoporous anatase single crystals. New Journal of Chemistry,42(4), 2669-2674.
Xu,L., Xiong, Y., Mei, A., Hu, Y., Rong, Y., Zhou, Y., ... & Han, H. (2018).Efficient Perovskite Photovoltaic‐Thermoelectric Hybrid Device. AdvancedEnergy Materials, 8(13), 1702937.
Guan,Y., Mei, A., Rong, Y., Duan, M., Hou, X., Hu, Y., & Han, H. (2018).Fullerene derivative as an additive for highly efficient printable mesoscopicperovskite solar cells. Organic Electronics, 62, 653-659.
Li,T., Wang, Q., Nichol, G. S., Morrison, C. A., Han, H., Hu, Y., & Robertson,N. (2018). Extending lead-free hybrid photovoltaic materials to new structures:thiazolium, aminothiazolium and imidazolium iodobismuthates. DaltonTransactions, 47(20), 7050-7058.
Wang,Q., Liu, S., Ming, Y., Guan, Y., Li, D., Zhang, C., ... & Han, H. (2018).Improvements in printable mesoscopic perovskite solar cells via thinner spacerlayers. Sustainable Energy & Fuels, 2(11), 2412-2418.
Duan,M., Hu, Y., Mei, A., Rong, Y., & Han, H. (2018). Printable carbon-basedhole-conductor-free mesoscopic perovskite solar cells: from lab to market. Materialstoday energy, 7, 221-231.
Tian,C., Zhang, S., Mei, A., Rong, Y., Hu, Y., Du, K., ... & Han, H. (2018). AMultifunctional Bis-Adduct Fullerene for Efficient Printable MesoscopicPerovskite Solar Cells. ACS applied materials & interfaces,10(13), 10835-10841.
Xu,L., Xiong, Y., Mei, A., Hu, Y., Rong, Y., Zhou, Y., ... & Han, H. (2018).Efficient Perovskite Photovoltaic‐Thermoelectric Hybrid Device. AdvancedEnergy Materials, 8(13), 1702937.
Xiong,Y., Zhu, X., Mei, A., Qin, F., Liu, S., Zhang, S., ... & Han, H. (2018).Bifunctional Al2O3 Interlayer Leads to Enhanced Open‐Circuit Voltage for Hole‐Conductor‐FreeCarbon‐Based Perovskite Solar Cells. Solar RRL, 2(5), 1800002.
Xu,C., Zhang, Z., Hu, Y., Sheng, Y., Jiang, P., Han, H., & Zhang, J. (2018).Printed hole-conductor-free mesoscopic perovskite solar cells with excellentlong-term stability using PEAI as an additive. Journal of energychemistry, 27(3), 764-768.
Rong,Y., Ming, Y., Ji, W., Li, D., Mei, A., Hu, Y., & Han, H. (2018). Towardindustrial-scale production of perovskite solar cells: screen printing,slot-die coating, and emerging techniques. The journal of physical chemistryletters, 9(10), 2707-2713.
Jiang,P., Xiong, Y., Xu, M., Mei, A., Sheng, Y., Hong, L., ... & Hu, Y. (2018).The Influence of the Work Function of Hybrid Carbon Electrodes on PrintableMesoscopic Perovskite Solar Cells. The Journal of Physical Chemistry C,122(29), 16481-16487.
Tian,C., Zhang, S., Li, S., Mei, A., Li, D., Liu, S., ... & Han, H. (2018). AC60 Modification Layer Using a Scalable Deposition Technology for EfficientPrintable Mesoscopic Perovskite Solar Cells. Solar RRL, 2(10),1800174.
Tian,C., Mei, A., Zhang, S., Tian, H., Liu, S., Qin, F., ... & Xie, S. (2018).Oxygen management in carbon electrode for high-performance printable perovskitesolar cells. Nano Energy, 53, 160-167.
Chen,M., Ju, M. G., Hu, M., Dai, Z., Hu, Y., Rong, Y., ... & Padture, N. P.(2018). Lead-Free Dion–Jacobson Tin Halide Perovskites for Photovoltaics.ACS Energy Letters, 4(1), 276-277.
Li,D., Tong, C., Ji, W., Fu, Z., Wan, Z., Huang, Q., ... & Han, H. (2018).Vanadium oxide post-treatment for enhanced photovoltage of printable perovskitesolar cells. ACS Sustainable Chemistry & Engineering, 7(2),2619-2625.
Duan,M., Rong, Y., Mei, A., Hu, Y., Sheng, Y., Guan, Y., & Han, H. (2017).Efficient hole-conductor-free, fully printable mesoscopic perovskite solarcells with carbon electrode based on ultrathin graphite. Carbon,120, 71-76.
Duan,M., Tian, C., Hu, Y., Mei, A., Rong, Y., Xiong, Y., ... & Zhu, X. (2017).Boron-doped graphite for high work function carbon electrode in printablehole-conductor-free mesoscopic perovskite solar cells. ACS appliedmaterials & interfaces, 9(37), 31721-31727.
Hong,L., Hu, Y., Mei, A., Sheng, Y., Jiang, P., Tian, C., ... & Han, H. (2017).Improvement and Regeneration of Perovskite Solar Cells via Methylamine GasPost‐Treatment. Advanced Functional Materials, 27(43), 1703060.
Hou,X., Hu, Y., Liu, H., Mei, A., Li, X., Duan, M., ... & Han, H. (2017).Effect of guanidinium on mesoscopic perovskite solar cells. Journal ofMaterials Chemistry A, 5(1), 73-78.
Hu,Y., Si, S., Mei, A., Rong, Y., Liu, H., Li, X., & Han, H. (2017). Stablelarge‐area (10× 10 cm2) printable mesoscopic perovskite module exceeding 10%efficiency. Solar Rrl, 1(2), 1600019.
Jiang,F., Yang, D., Jiang, Y., Liu, T., Zhao, X., Ming, Y., ... & Zhang, L.(2018). Chlorine-incorporation-induced formation of the layered phase forantimony-based lead-free perovskite solar cells. Journal of the AmericanChemical Society, 140(3), 1019-1027.
Li,T., Hu, Y., Morrison, C. A., Wu, W., Han, H., & Robertson, N. (2017).Lead-free pseudo-three-dimensional organic–inorganic iodobismuthates forphotovoltaic applications. Sustainable Energy & Fuels, 1(2),308-316.
Li,X., Zhong, X., Hu, Y., Li, B., Sheng, Y., Zhang, Y., ... & Wang, J. (2017).Organic–inorganic copper (II)-based material: a low-toxic, highly stable lightabsorber for photovoltaic application. The journal of physical chemistryletters, 8(8), 1804-1809.
Liu,T., Rong, Y., Xiong, Y., Mei, A., Hu, Y., Sheng, Y., ... & Hong, L. (2017).Spacer improvement for efficient and fully printable mesoscopic perovskitesolar cells. RSC Advances, 7(17), 10118-10123.
Liu,T., Xiong, Y., Rong, Y., & Han, H. (2017). Application of highly reflectivespacer layer in monolithic dye-sensitized solar cells. Chinese ScienceBulletin, 62(14), 1492-1499.
Ma,J., Yang, G., Qin, M., Zheng, X., Lei, H., Chen, C., ... & Fang, G. (2017).MgO nanoparticle modified anode for highly efficient SnO2‐based planarperovskite solar cells. Advanced Science, 4(9), 1700031.
Rong,Y., Hou, X., Hu, Y., Mei, A., Liu, L., Wang, P., & Han, H. (2017). Synergyof ammonium chloride and moisture on perovskite crystallization for efficientprintable mesoscopic solar cells. Nature communications, 8,14555.
Rong,Y., Hu, Y., Ravishankar, S., Liu, H., Hou, X., Sheng, Y., ... & Bisquert,J. (2017). Tunable hysteresis effect for perovskite solar cells. Energy& Environmental Science, 10(11), 2383-2391.
Tian,C., Kochiss, K., Castro, E., Betancourt-Solis, G., Han, H., & Echegoyen, L.(2017). A dimeric fullerene derivative for efficient inverted planar perovskitesolar cells with improved stability. Journal of Materials Chemistry A,5(16), 7326-7332.
Xu,L., Wan, F., Rong, Y., Chen, H., He, S., Xu, X., ... & Gao, Y. (2017).Stable monolithic hole-conductor-free perovskite solar cells using TiO2nanoparticle binding carbon films. Organic Electronics, 45,131-138.
Zheng,L., Cao, Q., Wang, J., Chai, Z., Cai, G., Ma, Z., ... & Chen, H. (2017).Novel D–A− π–A-Type Organic Dyes Containing a LadderlikeDithienocyclopentacarbazole Donor for Effective Dye-Sensitized Solar Cells. ACSOmega, 2(10), 7048-7056.
Chai,Z., Wan, S., Zhong, C., Xu, T., Fang, M., Wang, J., ... & Peng, Q. (2016).Conjugated or broken: the introduction of isolation spacer ahead of theanchoring moiety and the improved device performance. ACS appliedmaterials & interfaces, 8(42), 28652-28662.
Chen,J., Rong, Y., Mei, A., Xiong, Y., Liu, T., Sheng, Y., ... & Hou, X. (2016).Hole‐Conductor‐Free Fully Printable Mesoscopic Solar Cell with Mixed‐AnionPerovskite CH3NH3PbI (3− x)(BF4) x. Advanced Energy Materials,6(5), 1502009.
Chen,J., Xiong, Y., Rong, Y., Mei, A., Sheng, Y., Jiang, P., ... & Han, H.(2016). Solvent effect on the hole-conductor-free fully printable perovskitesolar cells. Nano Energy, 27, 130-137.
Jiang,F., Rong, Y., Liu, H., Liu, T., Mao, L., Meng, W., ... & Tong, J. (2016).Synergistic Effect of PbI2 Passivation and Chlorine Inclusion Yielding HighOpen‐Circuit Voltage Exceeding 1.15 V in Both Mesoscopic and Inverted PlanarCH3NH3PbI3 (Cl)‐Based Perovskite Solar Cells. Advanced FunctionalMaterials, 26(44), 8119-8127.
Jiang,X., Xiong, Y., Mei, A., Rong, Y., Hu, Y., Hong, L., ... & Han, H. (2016).Efficient compact-layer-free, hole-conductor-free, fully printable mesoscopicperovskite solar cell. The journal of physical chemistry letters,7(20), 4142-4146.
Li,H., Fang, M., Tang, R., Hou, Y., Liao, Q., Mei, A., ... & Li, Z. (2016).The introduction of conjugated isolation groups into the common acceptorcyanoacrylic acid: an efficient strategy to suppress the charge recombinationin dye sensitized solar cells and the dramatically improved efficiency from5.89% to 9.44%. Journal of Materials Chemistry A, 4(42),16403-16409.
Li,H., Fang, M., Xu, T., Hou, Y., Tang, R., Chen, J., ... & Li, Z. (2016). Newanthracene-based organic dyes: the flexible position of the anthracene moietybearing isolation groups in the conjugated bridge and the adjustable cellperformance. Organic Chemistry Frontiers, 3(2), 233-242.
Sheng,Y., Hu, Y., Mei, A., Jiang, P., Hou, X., Duan, M., ... & Han, H. (2016).Enhanced electronic properties in CH 3 NH 3 PbI 3 via LiCl mixing forhole-conductor-free printable perovskite solar cells. Journal ofMaterials Chemistry A, 4(42), 16731-16736.
Shi,J., Chai, Z., Tang, R., Li, H., Han, H., Peng, T., ... & Li, Z. (2016).Effect of electron-withdrawing groups in conjugated bridges: molecularengineering of organic sensitizers for dye-sensitized solar cells. Frontiersof Optoelectronics, 9(1), 60-70.
Bertoluzzi,L., Sanchez, R. S., Liu, L., Lee, J. W., Mas-Marza, E., Han, H., ... &Bisquert, J. (2015). Cooperative kinetics of depolarization in CH 3 NH 3 PbI 3perovskite solar cells. Energy & Environmental Science, 8(3),910-915.
Cao,W., Fang, M., Chai, Z., Xu, H., Duan, T., Li, Z., ... & Han, H. (2015). NewD–π–A organic dyes containing a tert-butyl-capped indolo [3, 2, 1-jk] carbazoledonor with bithiophene unit as π-linker for dye-sensitized solar cells. RSCAdvances, 5(42), 32967-32975.
Chai,Z., Wu, M., Fang, M., Wan, S., Xu, T., Tang, R., ... & Li, Z. (2015).Similar or Totally Different: the Adjustment of the Twist Conformation ThroughMinor Structural Modification, and Dramatically Improved Performance forDye‐Sensitized Solar Cell. Advanced Energy Materials, 5(18),1500846.
Chen,J., Ko, S., Liu, L., Sheng, Y., Han, H., & Li, X. (2015). The effect ofporphyrins suspended with different electronegative moieties on thephotovoltaic performance of monolithic porphyrin-sensitized solar cells with carboncounter electrodes. New Journal of Chemistry, 39(4), 2889-2900.
Chen,J., Ko, S., Liu, L., Sheng, Y., Han, H., & Li, X. (2015). The effect ofdifferent alkyl chains on the photovoltaic performance of D–π–Aporphyrin-sensitized solar cells. New Journal of Chemistry,39(5), 3736-3746.
Chen,J., Sheng, Y., Ko, S., Liu, L., Han, H., & Li, X. (2015). Push–pullporphyrins with different anchoring group orientations for fully printablemonolithic dye-sensitized solar cells with mesoscopic carbon counter electrodes.New Journal of Chemistry, 39(7), 5231-5239.
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Liu,T., Kim, D., Han, H., bin Mohd Yusoff, A. R., & Jang, J. (2015).Fine-tuning optical and electronic properties of graphene oxide for highlyefficient perovskite solar cells. Nanoscale, 7(24), 10708-10718.
Liu,T., Liu, L., Hu, M., Yang, Y., Zhang, L., Mei, A., & Han, H. (2015).Critical parameters in TiO2/ZrO2/Carbon-based mesoscopic perovskite solar cell.Journal of Power Sources, 293, 533-538.
Rong,Y., Ku, Z., Li, X., & Han, H. (2015). Transparent bifacial dye-sensitizedsolar cells based on an electrochemically polymerized organic counter electrodeand an iodine-free polymer gel electrolyte. Journal of Materials Science,50(10), 3803-3811.
Rong,Y., Liu, L., Mei, A., Li, X., & Han, H. (2015). Beyond efficiency: thechallenge of stability in mesoscopic perovskite solar cells. AdvancedEnergy Materials, 5(20), 1501066.
Yang,Y., Ri, K., Mei, A., Liu, L., Hu, M., Liu, T., ... & Han, H. (2015). Thesize effect of TiO 2 nanoparticles on a printable mesoscopic perovskite solarcell. Journal of Materials Chemistry A, 3(17), 9103-9107.
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Rong,Y., Ku, Z., Xu, M., Liu, L., Hu, M., Yang, Y., ... & Han, H. (2014).Efficient monolithic quasi-solid-state dye-sensitized solar cells based on poly(ionic liquids) and carbon counter electrodes. RSC Advances,4(18), 9271-9274.
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Liu,L., Chen, J., Ku, Z., Li, X., & Han, H. (2014). Unsymmetrical squarainesensitizers containing auxiliary arylamine donor for NIR-harvesting ondye-sensitized solar cell. Dyes and Pigments, 106, 128-135.
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Li,H., Tang, R., Hou, Y., Yang, Y., Chen, J., Liu, L., ... & Li, Z. (2014).Diphenyldibenzofulvene‐Based Sensitizers for Efficient Dye‐Sensitized SolarCells: The Tuned Absorption Properties and Partially Suppressed Aggregation. AsianJournal of Organic Chemistry, 3(2), 176-184.
Hu,M., Sun, J., Rong, Y., Yang, Y., Liu, L., Li, X., ... & Han, H. (2014).Enhancement of monobasal solid-state dye-sensitized solar cells with polymerelectrolyte assembling imidazolium iodide-functionalized silica nanoparticles. Journalof power sources, 248, 283-288.
Hu,M., Liu, L., Mei, A., Yang, Y., Liu, T., & Han, H. (2014). Efficienthole-conductor-free, fully printable mesoscopic perovskite solar cells with abroad light harvester NH 2 CH [double bond, length as m-dash] NH 2 PbI 3. Journalof Materials Chemistry A, 2(40), 17115-17121.
Liu,L., Li, X., Chen, J., Rong, Y., Ku, Z., & Han, H. (2013). Improvement ofThiolate/Disulfide Mediated Dye-Sensitized Solar Cells through SupramolecularLithium Cation Assembling of Crown Ether. Scientific reports, 3,2413.
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Liu,G., Li, X., Wang, H., Rong, Y., Ku, Z., Xu, M., ... & Han, H. (2013). Anefficient thiolate/disulfide redox couple based dye-sensitized solar cell witha graphene modified mesoscopic carbon counter electrode. Carbon,53, 11-18.
Li,X., Liu, L., Liu, G., Rong, Y., Yang, Y., Wang, H., ... & Han, H. (2013).Efficient Dye‐Sensitized Solar Cells with Potential‐Tunable Organic SulfideMediators and Graphene‐Modified Carbon Counter Electrodes. Advanced FunctionalMaterials, 23(26), 3344-3352.
Li,H., Yang, L., Tang, R., Hou, Y., Yang, Y., Wang, H., ... & Li, Z. (2013).Organic dyes incorporating N-functionalized pyrrole as conjugated bridge fordye-sensitized solar cells: convenient synthesis, additional withdrawing groupon the π-bridge and the suppressed aggregation. Dyes and Pigments,99(3), 863-870.
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Ku,Z., Rong, Y., Xu, M., Liu, T., & Han, H. (2013). Full printable processedmesoscopic CH 3 NH 3 PbI 3/TiO 2 heterojunction solar cells with carbon counterelectrode. Scientific reports, 3, 3132.
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Ku,Z., Li, X., Liu, G., Wang, H., Rong, Y., Xu, M., ... & Han, H. (2013).Transparent NiS counter electrodes for thiolate/disulfide mediateddye-sensitized solar cells. Journal of Materials Chemistry A,1(2), 237-240.
Rong,Y., & Han, H. (2013). Monolithic quasi-solid-state dye-sensitized solarcells based on graphene-modified mesoscopic carbon-counter electrodes. Journalof Nanophotonics, 7(1), 073090.
Rong,Y., Li, X., Liu, G., Wang, H., Ku, Z., Xu, M., ... & Liu, T. (2013).Monolithic quasi-solid-state dye-sensitized solar cells based on iodine-freepolymer gel electrolyte. Journal of Power Sources, 235, 243-250.
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Shi,J., Chai, Z., Su, J., Chen, J., Tang, R., Fan, K., ... & Li, Q. (2013). Newsensitizers bearing quinoxaline moieties as an auxiliary acceptor fordye-sensitized solar cells. Dyes and Pigments, 98(3), 405-413.
Wang,H., Xiang, P., Xu, M., Liu, G., Li, X., Ku, Z., ... & Han, H. (2013). Highefficiency monobasal solid-state dye-sensitized solar cell with mesoporous TiO2 beads as photoanode. Frontiers of Optoelectronics, 6(4),413-417.
Wang,H., Xu, M., Liu, G., Li, X., Xiang, P., Ku, Z., ... & Han, H. (2013).Effect of photo-doping on performance for solid-state dye-sensitized solar cellbased on 2, 2′ 7, 7′-tetrakis-(N, N-di-p-methoxyphenyl-amine)-9,9′-spirobifluorene and carbon counter electrode. Electrochimica Acta,99, 238-241.
Xu,M., Liu, G., Li, X., Wang, H., Rong, Y., Ku, Z., ... & Chen, J. (2013).Efficient monolithic solid-state dye-sensitized solar cell with a low-costmesoscopic carbon based screen printable counter electrode. OrganicElectronics, 14(2), 628-634.
Xu,M., Rong, Y., Ku, Z., Mei, A., Li, X., & Han, H. (2013). Improvement inSolid-State Dye Sensitized Solar Cells by p-Type Doping with Lewis Acid SnCl4. TheJournal of Physical Chemistry C, 117(44), 22492-22496.
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