This work focuses on the fabrication of stoichiometric CulnSe(2) nanostructures with controllable physical parameters of the nanocrystals suitable for hybrid organic/inorganic photovoltaics. CuInSe2 nanostructures were prepared by the chemical close-spaced vapor transport (CCSVT) method onto Mo/barrier/glass substrates by using an In2Se3 source material and Cu precursors. The In2Se3 source material was volatilized in H-2 ambience with the addition of HCl vapors at 550 degrees C. Three different types of Cu precursors were used: (i) Cu thin films (6-250 nm thick) deposited by e-beam, (ii) Cu nanoparticles prepared by spray pyrolysis and (iii) Cu nanostructures formed by applying the nanosphere lithography (using a monolayer of 450 nm nanospheres). The CCSVT process parameters were varied to reveal the optimum conditions for the preparation of secondary phases free CuInSe2 nanostructures. The structural characterization by x-ray diffraction in both grazing incidence and 0-20 configurations revealed the formation of CulnSe(2) chalcopyrite phase independently on the applied precursor type. The elemental composition of the as-prepared CuInSe2 nanostructures was analyzed by laser ablation-inductively coupled plasma mass-spectrometry. In non-optimised processes, an excess of Se compared to stoichiometric composition was detected and attributed to the formation of molybdenum selenide and indium selenide phases. The formation of the latter secondary phases was suppressed by tuning the CCSVT deposition parameters. (C) 2017 Elsevier B.V. All rights reserved.