Ligand-Exchanged CZTS Nanocrystal Thin Films: Does Nanocrystal Surface Passivation Effectively Improve Photovoltaic Performance?

Ligand-Exchanged CZTS Nanocrystal Thin Films: Does Nanocrystal Surface Passivation Effectively Improve Photovoltaic Performance?. Korala, L., Braun, M. B., Kephart, J. M., Tregillus, Z., & Prieto, A. L. Chemistry of Materials, 29(16):6621–6629, August, 2017.

Paper doi abstract bibtex

Nanocrystal (NC) Cu2ZnSnS4 (CZTS) solar cells, composed of a nontoxic and earth abundant absorber material, have great potential in low-cost solar energy harvesting. However, CZTS NC ﬁlms typically must be thermally annealed at elevated temperatures and under harsh environments to produce high-eﬃciency devices. The eﬃciencies of unannealed CZTS NC solar cells have been hampered by low open circuit potentials (Voc, \textless325 mV) and low short circuit current densities (Jsc, \textless2 mA), primarily because of the incomplete passivation of the crystal surface. Although great progress has been made in understanding the surface chemistry of II−VI and IV−VI semiconductor NCs, the surface chemistry of complex quaternary CZTS NCs is largely unexplored. Here, for the ﬁrst time, we report a comprehensive study of the surface chemistry of CZTS NCs focusing on depositing ligand-passivated, uniform NC thin ﬁlms to address the issue of large Voc deﬁcit and low current collection eﬃciency typically observed for CZTS NC solar cells. The ligand exchange reactions were rationally designed to target each metal ion on the surface [using both organic L-type ligands such as ethylenediamine and inorganic X-type ligands (I− and S2−)] and to passivate anionic chalcogen sites with inorganic Z-type ligands (ZnCl2). Herein, we show that CZTS/CdS heterojunction NC solar cells made of uniformly passivated CZTS NCs demonstrate a \textgreater180 mV improvement in Voc. Furthermore, the inﬂuence of device conﬁguration on the collection eﬃciency of photogenerated carriers in the CZTS NC absorber layer is presented, and the implications of both surface and internal defects in CZTS NCs for photovoltaic performance are discussed.

@article{korala_ligand-exchanged_2017,
	title = {Ligand-{Exchanged} {CZTS} {Nanocrystal} {Thin} {Films}: {Does} {Nanocrystal} {Surface} {Passivation} {Effectively} {Improve} {Photovoltaic} {Performance}?},
	volume = {29},
	issn = {0897-4756, 1520-5002},
	shorttitle = {Ligand-{Exchanged} {CZTS} {Nanocrystal} {Thin} {Films}},
	url = {https://pubs.acs.org/doi/10.1021/acs.chemmater.7b00541},
	doi = {10.1021/acs.chemmater.7b00541},
	abstract = {Nanocrystal (NC) Cu2ZnSnS4 (CZTS) solar cells, composed of a nontoxic and earth abundant absorber material, have great potential in low-cost solar energy harvesting. However, CZTS NC ﬁlms typically must be thermally annealed at elevated temperatures and under harsh environments to produce high-eﬃciency devices. The eﬃciencies of unannealed CZTS NC solar cells have been hampered by low open circuit potentials (Voc, {\textless}325 mV) and low short circuit current densities (Jsc, {\textless}2 mA), primarily because of the incomplete passivation of the crystal surface. Although great progress has been made in understanding the surface chemistry of II−VI and IV−VI semiconductor NCs, the surface chemistry of complex quaternary CZTS NCs is largely unexplored. Here, for the ﬁrst time, we report a comprehensive study of the surface chemistry of CZTS NCs focusing on depositing ligand-passivated, uniform NC thin ﬁlms to address the issue of large Voc deﬁcit and low current collection eﬃciency typically observed for CZTS NC solar cells. The ligand exchange reactions were rationally designed to target each metal ion on the surface [using both organic L-type ligands such as ethylenediamine and inorganic X-type ligands (I− and S2−)] and to passivate anionic chalcogen sites with inorganic Z-type ligands (ZnCl2). Herein, we show that CZTS/CdS heterojunction NC solar cells made of uniformly passivated CZTS NCs demonstrate a {\textgreater}180 mV improvement in Voc. Furthermore, the inﬂuence of device conﬁguration on the collection eﬃciency of photogenerated carriers in the CZTS NC absorber layer is presented, and the implications of both surface and internal defects in CZTS NCs for photovoltaic performance are discussed.},
	language = {en},
	number = {16},
	urldate = {2023-01-04},
	journal = {Chemistry of Materials},
	author = {Korala, Lasantha and Braun, Max B. and Kephart, Jason M. and Tregillus, Zoë and Prieto, Amy L.},
	month = aug,
	year = {2017},
	pages = {6621--6629},
}

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