Classification of solar cells according to mechanisms of charge separation and charge collection.

In the last decade, photovoltaics (PV) has experienced an important transformation. Traditional solar cells formed by compact semiconductor layers have been joined by new kinds of cells that are constituted by a complex mixture of organic, inorganic and solid or liquid electrolyte materials, and rely on charge separation at the nanoscale. Recently, metal organic halide perovskites have appeared in the photovoltaic landscape showing large conversion efficiencies, and they may share characteristics of the two former types. In this paper we provide a general description of the photovoltaic mechanisms of the single absorber solar cell types, combining all-inorganic, hybrid and organic cells into a single framework. The operation of the solar cell relies on a number of internal processes that exploit internal charge separation and overall charge collection minimizing recombination. There are two main effects to achieve the required efficiency, first to exploit kinetics at interfaces, favouring the required forward process, and second to take advantage of internal electrical fields caused by a built-in voltage and by the distribution of photogenerated charges. These principles represented by selective contacts, interfaces and the main energy diagram, form a solid base for the discussion of the operation of future types of solar cells. Additional effects based on ferroelectric polarization and ionic drift provide interesting prospects for investigating new PV effects mainly in the perovskite materials.

[1]  K. Walzer,et al.  Highly efficient organic devices based on electrically doped transport layers. , 2007, Chemical reviews.

[2]  Francisco Fabregat-Santiago,et al.  Role of the Selective Contacts in the Performance of Lead Halide Perovskite Solar Cells. , 2014, The journal of physical chemistry letters.

[3]  P Shafer,et al.  Above-bandgap voltages from ferroelectric photovoltaic devices. , 2010, Nature nanotechnology.

[4]  P. Würfel,et al.  Physics of solar cells , 2005 .

[5]  E. Sargent,et al.  Erratum: Selective contacts drive charge extraction in quantum dot solids via asymmetry in carrier transfer kinetics , 2013, Nature Communications.

[6]  J. Bisquert,et al.  Electrical field profile and doping in planar lead halide perovskite solar cells , 2014 .

[7]  A. G. Chynoweth,et al.  Surface Space-Charge Layers in Barium Titanate , 1956 .

[8]  A. Kahn,et al.  Electronic structure of molybdenum-oxide films and associated charge injection mechanisms in organic devices , 2011 .

[9]  Fenggong Wang,et al.  Semiconducting ferroelectric photovoltaics through Zn 2+ doping into KNbO 3 and polarization rotation , 2014 .

[10]  F. Di Fonzo,et al.  The real TiO2/HTM interface of solid-state dye solar cells: role of trapped states from a multiscale modelling perspective. , 2015, Nanoscale.

[11]  Filippo De Angelis,et al.  Intermolecular Interactions in Dye-Sensitized Solar Cells: A Computational Modeling Perspective. , 2013, The journal of physical chemistry letters.

[12]  X. Zhu,et al.  How to Draw Energy Level Diagrams in Excitonic Solar Cells. , 2014, The journal of physical chemistry letters.

[13]  M. Grätzel,et al.  Sequential deposition as a route to high-performance perovskite-sensitized solar cells , 2013, Nature.

[14]  Henry J. Snaith,et al.  Efficient planar heterojunction perovskite solar cells by vapour deposition , 2013, Nature.

[15]  C. Tang,et al.  Enhanced electron injection in organic electroluminescence devices using an Al/LiF electrode , 1997 .

[16]  Yang Yang,et al.  Interface engineering of highly efficient perovskite solar cells , 2014, Science.

[17]  Eric T. Hoke,et al.  Reversible photo-induced trap formation in mixed-halide hybrid perovskites for photovoltaics† †Electronic supplementary information (ESI) available: Experimental details, PL, PDS spectra and XRD patterns. See DOI: 10.1039/c4sc03141e Click here for additional data file. , 2014, Chemical science.

[18]  W. Marsden I and J , 2012 .

[19]  Qingfeng Dong,et al.  Giant switchable photovoltaic effect in organometal trihalide perovskite devices. , 2015, Nature materials.

[20]  Juan Bisquert,et al.  Physical Chemical Principles of Photovoltaic Conversion with Nanoparticulate, Mesoporous Dye-Sensitized Solar Cells , 2004 .

[21]  Eric T. Hoke,et al.  Re‐evaluating the Role of Sterics and Electronic Coupling in Determining the Open‐Circuit Voltage of Organic Solar Cells , 2013, Advanced materials.

[22]  P. Salvador,et al.  Flatband Potential of F:SnO2 in a TiO2 Dye-Sensitized Solar Cell: An Interference Reflection Study , 2003 .

[23]  Liyan Wu,et al.  Perovskite oxides for visible-light-absorbing ferroelectric and photovoltaic materials , 2013, Nature.

[24]  Wei Huang,et al.  Bandgap tuning of multiferroic oxide solar cells , 2014, Nature Photonics.

[25]  A. Maldonado,et al.  Physical properties of ZnO:F obtained from a fresh and aged solution of zinc acetate and zinc acetylacetonate , 2006 .

[26]  Lukas Schmidt-Mende,et al.  Research Update: Physical and electrical characteristics of lead halide perovskites for solar cell applications , 2014 .

[27]  Juan Bisquert,et al.  Slow Dynamic Processes in Lead Halide Perovskite Solar Cells. Characteristic Times and Hysteresis. , 2014, The journal of physical chemistry letters.

[28]  J. Bisquert,et al.  High-efficiency "green" quantum dot solar cells. , 2014, Journal of the American Chemical Society.

[29]  Juan Bisquert,et al.  Photoinduced Giant Dielectric Constant in Lead Halide Perovskite Solar Cells. , 2014, The journal of physical chemistry letters.

[30]  Thomas Kirchartz,et al.  Understanding the Thickness-Dependent Performance of Organic Bulk Heterojunction Solar Cells: The Influence of Mobility, Lifetime, and Space Charge. , 2012, The journal of physical chemistry letters.

[31]  Nam-Gyu Park,et al.  Organolead Halide Perovskite: New Horizons in Solar Cell Research , 2014 .

[32]  Wmm Erwin Kessels,et al.  Surface passivation of high‐efficiency silicon solar cells by atomic‐layer‐deposited Al2O3 , 2008 .

[33]  Juan Bisquert,et al.  Impedance spectroscopy study of dye-sensitized solar cells with undoped spiro-OMeTAD as hole conductor , 2006 .

[34]  Yasuhiro Yamada,et al.  Photocarrier recombination dynamics in perovskite CH3NH3PbI3 for solar cell applications. , 2014, Journal of the American Chemical Society.

[35]  G. Garcia‐Belmonte,et al.  Interplay between fullerene surface coverage and contact selectivity of cathode interfaces in organic solar cells. , 2013, ACS nano.

[36]  J. Werner,et al.  Reply to comments on "Electronic transport in dye-sensitized nanoporous TiO2 solar cells-comparison of electrolyte and solid-state devices". On the photovoltaic action in pn-junction and dye-sensitized solar cells , 2003 .

[37]  Thomas Kirchartz,et al.  Advanced Characterization Techniques for Thin Film Solar Cells , 2016 .

[38]  Tsutomu Miyasaka,et al.  Organometal halide perovskites as visible-light sensitizers for photovoltaic cells. , 2009, Journal of the American Chemical Society.

[39]  Sang Il Seok,et al.  Solvent engineering for high-performance inorganic-organic hybrid perovskite solar cells. , 2014, Nature materials.

[40]  Juan Bisquert,et al.  Mobile cation concentration in ionically conducting glasses calculated by means of Mott–Schottky capacitance–voltage characteristics , 2003 .

[41]  Kevin Barraclough,et al.  I and i , 2001, BMJ : British Medical Journal.

[42]  B. Scrosati,et al.  The Electronic and the Ionic Contribution to the Free Energy of Alkali Metals in Intercalation Compounds , 1994 .

[43]  D. Abou‐Ras,et al.  Advanced Characterization Techniques for Thin Film Solar Cells: RAU:SOLARCELLS CHARACT. O-BK , 2011 .

[44]  E. Schiff Low-mobility solar cells: a device physics primer with application to amorphous silicon , 2003 .

[45]  J. H. Ling Energy harvesting and storage , 2009 .

[46]  Yongli Gao,et al.  Au∕LiF/tris(8-hydroxyquinoline) aluminum interfaces , 2007 .

[47]  H. Rickert Electrochemistry of solids , 1982 .

[48]  Juan Bisquert,et al.  Nanostructured Energy Devices: Equilibrium Concepts and Kinetics , 2014 .

[49]  Aaas News,et al.  Book Reviews , 1893, Buffalo Medical and Surgical Journal.

[50]  P. Würfel Physics of solar cells : from principles to new concepts , 2005 .

[51]  M. Grätzel,et al.  A low-cost, high-efficiency solar cell based on dye-sensitized colloidal TiO2 films , 1991, Nature.

[52]  Properties of chromophores determining recombination at the TiO2-dye-electrolyte interface. , 2013, Langmuir : the ACS journal of surfaces and colloids.

[53]  J. Bisquert,et al.  How the charge-neutrality level of interface states controls energy level alignment in cathode contacts of organic bulk-heterojunction solar cells. , 2012, ACS nano.

[54]  G. Neumark Theory of the Anomalous Photovoltaic Effect of ZnS , 1962 .

[55]  Peter Lund,et al.  Spectral Characteristics of Light Harvesting, Electron Injection, and Steady-State Charge Collection in Pressed TiO2 Dye Solar Cells , 2008 .

[56]  Prashant V. Kamat,et al.  Band filling with free charge carriers in organometal halide perovskites , 2014, Nature Photonics.

[57]  M. Taguchi,et al.  HITTM cells—high-efficiency crystalline Si cells with novel structure , 2000 .

[58]  Yanfa Yan,et al.  Unusual defect physics in CH3NH3PbI3 perovskite solar cell absorber , 2014 .

[59]  Antonio Luque,et al.  Understanding intermediate-band solar cells , 2012, Nature Photonics.

[60]  A. Barker,et al.  Effect of Carrier Thermalization Dynamics on Light Emission and Amplification in Organometal Halide Perovskites. , 2015, The journal of physical chemistry letters.

[61]  Zhenghong Lu,et al.  Metal/Metal‐Oxide Interfaces: How Metal Contacts Affect the Work Function and Band Structure of MoO3 , 2013 .

[62]  S. Haque,et al.  Photochemical energy conversion: from molecular dyads to solar cells. , 2006, Chemical communications.