Gas-phase substitution synthesis of Cu1.8S and Cu2S superlattice nanowires from CdS nanowires

Gas-phase substitution synthesis of Cu1.8S and Cu2S superlattice nanowires from CdS nanowires

Single-crystalline wurtzite CdS nanowires underwent gas-phase substitution to form unique superlattice cubic Cu1.8S (digenite) and hexagonal Cu2S (chalcocite) structures, using thermal evaporation of CuCl2 at 500[similar]600 [degree]C. The Cu1.8S nanowires consisted of superlattices along the ?111?...

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Veröffentlicht in:CrystEngComm 2011-01, Vol.13 (6), p.2091-2095
Hauptverfasser: Kim, Han Sung, Sung, Tae Kwang, Jang, So Young, Myung, Yoon, Cho, Yong Jae, Lee, Chi-Woo, Park, Jeunghee, Ahn, Jae-Pyoung, Kim, Jin-Gyu, Kim, Youn-joong
Format: Artikel
Sprache:eng
Schlagworte:
Cadmium sulfides
Chalcocite
Copper sulfides
Evaporation
Nanowires
Single crystals
Superlattices
Synthesis
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Zusammenfassung:Single-crystalline wurtzite CdS nanowires underwent gas-phase substitution to form unique superlattice cubic Cu1.8S (digenite) and hexagonal Cu2S (chalcocite) structures, using thermal evaporation of CuCl2 at 500[similar]600 [degree]C. The Cu1.8S nanowires consisted of superlattices along the ?111? direction, with controlled growth direction ([110], [211], [100], [111]) and superlattice periods of 1.6 and 1.9 nm. As the temperature decreased, the growth direction evolved from [100] to the higher surface-energy [110] or [211] directions, with longer superlattice periods. The Cu2S nanowires also exhibited a superlattice along the [0001] growth direction, with a periodicity of 2.7 nm and could be irreversibly converted into superlattice Cu1.8S by electron-beam irradiation.
ISSN:1466-8033
1466-8033
DOI:10.1039/c0ce00692k