Prof Henry Snaith FRS

Unraveling the function of an MgO interlayer in both electrolyte and solid-state SnO 2 based dye-sensitized solar cells

Journal of Physical Chemistry C 116:43 (2012) 22840-22846

Authors:

P Docampo, P Tiwana, N Sakai, H Miura, L Herz, T Murakami, HJ Snaith

Abstract:

The coating of n-type mesoporous metal oxides with nanometer thick dielectric shells is a route that has proven to be successful at enhancing the efficiency of some families of dye-sensitized solar cells. The primary intention is to introduce a "surface passivation layer" to inhibit recombination between photoinduced electrons and holes across the dye-sensitized interface. However, the precise function of these dielectric interlayers is often ambiguous. Here, the role of a thin MgO interlayer conformally deposited over mesoporous SnO 2 in liquid electrolyte and solid-state dye-sensitized solar cells is investigated. For both families of devices the open-circuit voltage is increased by over 200 mV; however, the short-circuit photocurrent is increased for the solid-state cells, but reduced for the electrolyte based devices. Through electronic and spectroscopic characterization we deduce that there are four distinct influences of the MgO interlayer: It increases dye-loading, slows down recombination, slows down photoinduced electron transfer, and results in a greater than 200 mV shift in the conduction band edge, with respect to the electrolyte redox potential. The compilation of these four factors have differing effects and magnitudes in the solid-state and electrolyte DSCs but quantitatively account for the difference in device performances observed for both systems with and without the MgO shells. To the best of our knowledge, this is the most comprehensive account of the role of dielectric shells in dye-sensitized solar cells and will enable much better interfacial design of photoelectrodes for DSCs. © 2012 American Chemical Society.

A polyfluoroalkyl imidazolium ionic liquid as iodide ion source in dye sensitized solar cells

Organic Electronics Elsevier 13:11 (2012) 2474-2478

Authors:

Antonio Abate, Annamaria Petrozza, Vittoria Roiati, Simone Guarnera, Henry Snaith, Francesco Matteucci, Guglielmo Lanzani, Pierangelo Metrangolo, Giuseppe Resnati

Solution-processed dye-sensitized ZnO phototransistors with extremely high photoresponsivity

Journal of Applied Physics 112:7 (2012)

Authors:

P Pattanasattayavong, S Rossbauer, S Thomas, JG Labram, HJ Snaith, TD Anthopoulos

Abstract:

We report the fabrication of light-sensing thin-film transistors based on solution processed films of ZnO, as the channel material, functionalized with an organic dye as the light sensitizer. Due to the presence of the dye, the hybrid devices show exceptionally high photosensitivity to green light of 10 6 and a maximum photoresponsivity on the order of 10 4 A/W. The high performance is argued to be the result of the grain barrier limited nature of electron transport across the polycrystalline ZnO film and its dependence on charge carrier density upon illumination with green light. In addition to the excellent photoresponsivity and signal gain, the hybrid ZnO-dye photoactive layer exhibits high optical transparency. The unique combination of simple device fabrication and distinctive physical characteristics, such as optical transparency, renders the technology attractive for application in large-area transparent photodetectors. © 2012 American Institute of Physics.

The perils of solar cell efficiency measurements

Nature Photonics 6:6 (2012) 337-340

TiO2 Photoanodes: Triblock‐Terpolymer‐Directed Self‐Assembly of Mesoporous TiO2: High‐Performance Photoanodes for Solid‐State Dye‐Sensitized Solar Cells (Adv. Energy Mater. 6/2012)

Advanced Energy Materials Wiley 2:6 (2012) 609-609

Authors:

Pablo Docampo, Morgan Stefik, Stefan Guldin, Robert Gunning, Nataliya A Yufa, Ning Cai, Peng Wang, Ullrich Steiner, Ulrich Wiesner, Henry J Snaith