Synthesis and Formation Mechanism of Colloidal Janus-Type Cu(2–x)S/CuInS(2) Heteronanorods via Seeded Injection

[Image: see text] Colloidal heteronanocrystals allow for the synergistic combination of properties of different materials. For example, spatial separation of the photogenerated electron and hole can be achieved by coupling different semiconductors with suitable band offsets in one single nanocrystal, which is beneficial for improving the efficiency of photocatalysts and photovoltaic devices. From this perspective, axially segmented semiconductor heteronanorods with a type-II band alignment are particularly attractive since they ensure the accessibility of both photogenerated charge carriers. Here, a two-step synthesis route to Cu(2–x)S/CuInS(2) Janus-type heteronanorods is presented. The heteronanorods are formed by injection of a solution of preformed Cu(2–x)S seed nanocrystals in 1-dodecanethiol into a solution of indium oleate in oleic acid at 240 °C. By varying the reaction time, Janus-type heteronanocrystals with different sizes, shapes, and compositions are obtained. A mechanism for the formation of the heteronanocrystals is proposed. The first step of this mechanism consists of a thiolate-mediated topotactic, partial Cu(+) for In(3+) cation exchange that converts one of the facets of the seed nanocrystals into CuInS(2). This is followed by homoepitaxial anisotropic growth of wurtzite CuInS(2). The Cu(2–x)S seed nanocrystals also act as sacrificial Cu(+) sources, and therefore, single composition CuInS(2) nanorods are eventually obtained if the reaction is allowed to proceed to completion. The two-stage seeded growth method developed in this work contributes to the rational synthesis of Cu(2–x)S/CuInS(2) heteronanocrystals with targeted architectures by allowing one to exploit the size and faceting of premade Cu(2–x)S seed nanocrystals to direct the growth of the CuInS(2) segment.