TY - JOUR A1 - Balderas-Valadez, Ruth Fabiola A1 - Estevez-Espinoza, J. O. A1 - Salazar-Kuri, U. A1 - Pacholski, Claudia A1 - Mochan, Wolf Luis A1 - Agarwal, Vivechana T1 - Fabrication of ordered tubular porous silicon structures by colloidal lithography and metal assisted chemical etching BT - SERS performance of 2D porous silicon structures JF - Applied surface science : a journal devoted to applied physics and chemistry of surfaces and interfaces N2 - Fabrication of well-ordered porous silicon tubular structures using colloidal lithography and metal assisted chemical etching is reported. A continuous hexagonal hole/particle gold pattern was designed over monocrystalline silicon through deposition of polyNIPAM microspheres, followed by the surface decoration with gold nanoparticles and thermal treatment. An etching reaction with HF, ethanol and H2O2 dissolved the silicon in contact with the metal nanoparticles (NP), creating a porous tubular array in the "off-metal area". The morphological characterization revealed the formation of a cylindrical hollow porous tubular shape with external and internal diameter of approx. 900 nm and 400 nm respectively, though it can be tuned to other desired sizes by choosing an appropriate dimension for the microspheres. The porous morphology and optical properties were studied as a function of resistivity of silicon substrates. Compared to two different gold templates on cSi and nontubular porous pillar structures, porous silicon tubular framework revealed a maximum surface enhanced Raman scattering enhancement factor of 10(6) for the detection of 6-mercaptopurine (6-MP). Due to the large surface area available for any surface modification, open nanostructured platforms such as those studied here have potential applications in the field of reflection/photoluminescene and SERS based optical bio-/chemical sensors. KW - SERS KW - Porous silicon KW - MACE KW - Colloidal lithography KW - PolyNIPAM KW - 6-Mercaptopurine Y1 - 2018 U6 - https://doi.org/10.1016/j.apsusc.2018.08.120 SN - 0169-4332 SN - 1873-5584 VL - 462 SP - 783 EP - 790 PB - Elsevier CY - Amsterdam ER - TY - JOUR A1 - Balderas-Valadez, Ruth Fabiola A1 - Antunez, E. E. A1 - Olive-Mendez, Sion Federico A1 - Pacholski, Claudia A1 - Campos-Alvarez, Jose A1 - Bokhimi, Xim A1 - Agarwal, V. T1 - Porous silicon pillar and bilayer structure as a nucleation center for the formation of aligned vanadium pentoxide nanorods JF - Ceramics International N2 - Porous silicon single layer (PSM), bilayer (PSB) and pillar (PSP) structures have been evaluated as nucleation centers for vanadium pentoxide (V2O5) crystals. Deposition of vanadium precursor over different substrates (drop casting technique), followed by annealing treatment under Ar-H-2 (5% H-2) atmosphere, induced crystallization of vanadium oxide. With respect to c-Si/SiO2 substrate, V2O5 nanorods with relatively large aspect ratio were formed over and within PSP structures. On the other hand, pores in PSM and PSB were found to be filled with relatively smaller crystals. Additionally, PSB provided a nucleation substrate capable to align the nanocrystals in a preferential orientation, while V2O5 crystals grown on PSP were found to be randomly aligned around the nanoporous pillar microstructure. Nanorods and nanocrystals were identified as V2O5 by temperature-controlled XRD measurements and evidence of their crystalline nature was observed via transmission electron microscopy. A careful analysis of electronic microscopy images allows the identification of the facets composing the ends of the crystals and its corresponding surface free energy has been evaluated employing the Wulff theorem. Such high surface area composite structures have potential applications as cathode material in Lithium-ion batteries. KW - Porous silicon KW - Vanadium pentoxide KW - Nanorods KW - Crystallization KW - Nanostructures Y1 - 2017 U6 - https://doi.org/10.1016/j.ceramint.2017.03.114 SN - 0272-8842 SN - 1873-3956 VL - 43 SP - 8023 EP - 8030 PB - Elsevier CY - Oxford ER -