This book covers fundamentals of organometal perovskite materials and their photovoltaics, including materials preparation and device fabrications. Special emphasis is given to halide perovskites. The opto-electronic properties of perovskite materials and recent progress in perovskite solar cells are described. In addition, comments on the issues to current and future challenges are mentioned.

Perovskite is a well-known structure with the chemical formula ABX3, where A and B are cations coordinated with 12 and 6 anions, respectively, and X is an anion. When a halogen anion is used, the monovalent A and divalent B cations can be stabilized with respect to a tolerance factor ranging from ~0.8 to 1. Since the first report on ~10% efficiency and long-term stability of solid-state perovskite solar cells (PSCs) in 2012 and two subsequent seed reports on perovskite-sensitized solar cells in 2009 and 2011, PSCs have received increasing attention. The power conversion efficiency of PSCs was certified to be more than 25% in 2020, surpassing thin-film solar cell technologies. Methylammonium or formamidinium organic ion–based lead iodide perovskite has been used for high-efficiency PSCs. The first report on solid-state PSCs triggered perovskite photovoltaics, leading to more than 23,000 publications as of October 2021. In addition, halide perovskite has shown excellent performance when applied to light-emitting diodes (LEDs), photodetectors, and resistive memory, indicating that halide perovskite is multifunctional. This book explains the electro-optical and ferroelectric properties of perovskite and details the recent progress in scalable and tandem PSCs as well as perovskite LEDs and resistive memory. It is a useful textbook and self-help study guide for advanced undergraduate- and graduate-level students of materials science and engineering, chemistry, chemical engineering, and nanotechnology; for researchers in photovoltaics, LEDs, resistive memory, and perovskite-related opto-electronics; and for general readers who wish to gain knowledge about halide perovskite.

Real insight from leading experts in the field into the causes of the unique photovoltaic performance of perovskite solar cells, describing the fundamentals of perovskite materials and device architectures. The authors cover materials research and development, device fabrication and engineering methodologies, as well as current knowledge extending beyond perovskite photovoltaics, such as the novel spin physics and multiferroic properties of this family of materials. Aimed at a better and clearer understanding of the latest developments in the hybrid perovskite field, this is a must-have for material scientists, chemists, physicists and engineers entering or already working in this booming field.

This book details the recent progress in halide perovskite photovoltaics, LEDs, and resistive memory, as well as the fundamentals of organic-inorganic halide perovskite.

Perovskite Photovoltaics and Optoelectronics Discover a one-of-a-kind treatment of perovskite photovoltaics In less than a decade, the photovoltaics of organic-inorganic halide perovskite materials has surpassed the efficiency of semiconductor compounds like CdTe and CIGS in solar cells. In Perovskite Photovoltaics and Optoelectronics: From Fundamentals to Advanced Applications, distinguished engineer Dr. Tsutomu Miyasaka delivers a comprehensive exploration of foundational and advanced topics regarding halide perovskites. It summarizes the latest information and discussion in the field, from fundamental theory and materials to critical device applications. With contributions by top scientists working in the perovskite community, the accomplished editor has compiled a resource of central importance for researchers working on perovskite related materials and devices. This edited volume includes coverage of new materials and their commercial and market potential in areas like perovskite solar cells, perovskite light-emitting diodes (LEDs), and perovskite-based photodetectors. It also includes: A thorough introduction to halide perovskite materials, their synthesis, and dimension control Comprehensive explorations of the photovoltaics of halide perovskites and their historical background Practical discussions of solid-state photophysics and carrier transfer mechanisms in halide perovskite semiconductors In-depth examinations of multi-cation anion-based high efficiency perovskite solar cells Perfect for materials scientists, crystallization physicists, surface chemists, and solid-state physicists, Perovskite Photovoltaics and Optoelectronics: From Fundamentals to Advanced Applications is also an indispensable resource for solid state chemists and device/electronics engineers.

Perovskite Photovoltaics: Basic to Advanced Concepts and Implementation examines the emergence of perovskite photovoltaics, associated challenges and opportunities, and how to achieve broader development. Consolidating developments in perovskite photovoltaics, including recent progress solar cells, this text also highlights advances and the research necessary for sustaining energy. Addressing different photovoltaics fields with tailored content for what makes perovskite solar cells suitable, and including commercialization examples of large-scale perovskite solar technology. The book also contains a detailed analysis of the implementation and economic viability of perovskite solar cells, highlighting what photovoltaic devices need to be generated by low cost, non-toxic, earth abundant materials using environmentally scalable processes. This book is a valuable resource engineers, scientists and researchers, and all those who wish to broaden their knowledge on flexible perovskite solar cells. - Includes contributions by leading solar cell academics, industrialists, researchers and institutions across the globe - Addresses different photovoltaics fields with tailored content for what makes perovskite solar cells different - Provides commercialization examples of large-scale perovskite solar technology, giving users detailed analysis on the implementation, technical challenges and economic viability of perovskite solar cells

The development of reliable, cost-effective, carbon-free energy resources is paramount in mounting a response to climate change that ensures global welfare and economic stability. While a complete decarbonized energy portfolio will include a range of renewable energy technologies, there is no question that solar solar energy should be used to meet an appreciable portion of energy demand. While solar energy has already achieved grid parity, or has a lower levelized cost than electricity from coal-fired power plants, in many U.S. states and other countries around the world, further reductions in cost are still needed. Organic-inorganic metal halide perovskite (OIHP) photovoltaics offer a promising route to reducing the dollars per watt cost of solar energy because they can be deposited via scalable, low cost methods and still achieve high performance. OIHP processing methods such as slot-die coating could be easily integrated into the existing silicon PV infrastructure to make perovskite-on-silicon tandems that outperform current modules for a minimal increase in cost. This thesis will explore several factors limiting the stability and performance of OIHPs that currently prevent their widespread deployment in the PV market. First, it will show that the thermal stability of OIHP materials can be improved through chemical substitution of cesium for the inorganic methylammonium cation. Cesium substitution also improves stability to a more pernicious degradation mechanism: phase segregation of the halide anions under illumination. Tuning chemical composition of OIHPs through halide substitution also tunes the band gap across the ideal range for perovskite-on-silicon tandem solar cells, but segregation of the different halide ions results in the formation of low band gap domains that act as recombination centers and limit the voltage of devices. Fully-inorganic perovskite semiconductors do not achieve the same high photoconversion efficiencies as OIHPs, so next, the impact of incremental cesium substitution in formamidinium lead halide perovskite materials, which have comparable thermal stability, is explored. Structural characterization is coupled with time-dependent photoluminescence to study a range of alloyed formamidinium cesium perovskites. Because cesium and formamidinium have different ionic radii, structural changes are observed as the composition of the alloys is varied, but these structural changes are not perfectly correlated with the observed changes in stability to phase segregation. While several conflicting mechanisms for phase segregation have been proposed in the literature, the experimental data presented here cannot isolate which, if any, are correct. The final chapter will highlight an alternative approach to both understanding and mitigating photo-induced phase segregation. Halide diffusion is a vacancy-mediated process, so phase segregation is necessarily tied to defect chemistry, but very few empirical studies have been done. Here, a method for probing the concentration of halide vacancies using \emph{in situ} X-ray diffraction is demonstrated. Preliminary results are presented and are in agreement with vacancy concentrations on the order of tenths of a percent predicted by first principles calculations. Altogether, this work maps out several pathways to improved stability for high-efficiency OIHP materials so that they can realize their potential in the next generation of renewable energy technologies.

Perovskite is a well-known structure with the chemical formula ABX3, where A and B are cations coordinated with 12 and 6 anions, respectively, and X is an anion. When a halogen anion is used, the monovalent A and divalent B cations can be stabilized with respect to a tolerance factor ranging from ~0.8 to 1. Since the first report on ~10% efficiency and long-term stability of solid-state perovskite solar cells (PSCs) in 2012 and two subsequent seed reports on perovskite-sensitized solar cells in 2009 and 2011, PSCs have received increasing attention. The power conversion efficiency of PSCs was certified to be more than 25% in 2020, surpassing thin-film solar cell technologies. Methylammonium or formamidinium organic ion–based lead iodide perovskite has been used for high-efficiency PSCs. The first report on solid-state PSCs triggered perovskite photovoltaics, leading to more than 23,000 publications as of October 2021. In addition, halide perovskite has shown excellent performance when applied to light-emitting diodes (LEDs), photodetectors, and resistive memory, indicating that halide perovskite is multifunctional. This book explains the electro-optical and ferroelectric properties of perovskite and details the recent progress in scalable and tandem PSCs as well as perovskite LEDs and resistive memory. It is a useful textbook and self-help study guide for advanced undergraduate- and graduate-level students of materials science and engineering, chemistry, chemical engineering, and nanotechnology; for researchers in photovoltaics, LEDs, resistive memory, and perovskite-related opto-electronics; and for general readers who wish to gain knowledge about halide perovskite.

Low-Dimensional Halide Perovskites: Structure, Properties and Applications provides an in-depth look at halide perovskite materials and their applications. Chapters cover history, fundamentals, physiochemical and optoelectronic properties, synthesis and characterization of traditional and Pb-free halide perovskites. The book concludes with sections describing the different applications of halide perovskites for solar cells, light-emitting diodes and photo detectors, as well as the challenges faced in the industrialization of halide perovskite-based devices and forward-thinking prospects for further deployment. - Discusses the applications of halide perovskites according to their dimensionality - Includes a look at current challenges for the commercialization of halide perovskites, while also previewing some possible solutions - Presents alternative environmentally-friendly materials that can used to replace the current toxic materials-based halide perovskites