Wearable Solar Cells Understand a groundbreaking new energy technology Solar energy is one of the most important paths to a sustainable future. In recent years, extensive research and development has begun to produce wearable solar cells, whose novel planar and fiber format gives them enormous flexibility and a wide range of potential uses. The possibility of a solar energy source that can be fitted to the human body promises to become an extraordinary tool for meeting various kinds of personal energy needs. Wearable Solar Cells: Mechanisms, Materials, and Devices serves as a comprehensive introduction to this cutting-edge technology and its applications. Recent research pointing towards fiber-format solar cells as a bold new frontier is summarized and explored. The result is an essential resource for both experienced researchers and newcomers to the field. Wearable Solar Cells readers will also find: Close coverage of integrated energy harvesting and storage devices Detailed discussion of dye-sensitized solar cells, polymer solar cells, perovskite solar cells, and more An authorial team with decades of combined research experience Wearable Solar Cells is ideal for materials scientists, polymer chemists, electrical engineers, solid-state physicists, and advanced students interested in these and related topics.

Provides the state-of-the-art on wearable technology for smart clothing The book gives a coherent overview of recent development on flexible electronics for smart clothing with emphasis on wearability and durability of the materials and devices. It offers detailed information on the basic functional components of the flexible and wearable electronics including sensing, systems-on-a-chip, interacting, and energy, as well as the integrating and connecting of electronics into textile form. It also provides insights into the compatibility and integration of functional materials, electronics, and the clothing technology. Flexible and Wearable Electronics for Smart Clothing offers comprehensive coverage of the technology in four parts. The first part discusses wearable organic nano-sensors, stimuli-responsive electronic skins, and flexible thermoelectrics and thermoelectric textiles. The next part examines textile triboelectric nanogenerators for energy harvesting, flexible and wearable solar cells and supercapacitors, and flexible and wearable lithium-ion batteries. Thermal and humid management for next-generation textiles, functionalization of fiber materials for washable smart wearable textiles, and flexible microfluidics for wearable electronics are covered in the next section. The last part introduces readers to piezoelectric materials and devices based flexible bio-integrated electronics, printed electronics for smart clothes, and the materials and processes for stretchable and wearable e-textile devices. -Presents the most recent developments in wearable technology such as wearable nanosensors, logic circuit, artificial intelligence, energy harvesting, and wireless communication -Covers the flexible and wearable electronics as essential functional components for smart clothing from sensing, systems-on-a-chip, interacting, energy to the integrating and connecting of electronics -Of high interest to a large and interdisciplinary target group, including materials scientists, textile chemists, and electronic engineers in academia and industry Flexible and Wearable Electronics for Smart Clothing will appeal to materials scientists, textile industry professionals, textile engineers, electronics engineers, and sensor developers.

Smartwatch? Fitness tracker? Portable ECG? Smartphone? Posture monitor? Hearing aid? MP3 player? E-reader? Wireless headset? Hiking watch? Gaming headset? Sleep monitor? Laptop computer? Tablet? Indeed, a dizzying array of portable and wearable electronic devices is available to the modern consumer. Not surprisingly, as the number of devices an individual chooses to wear or carry increases so does the energy required to power those devices. Judging by the increasing popularity of portable power banks, waiting to recharge many of these devices using standard wall outlets is no longer a standard practice. Wearable Solar Cell Systems looks at the possibilities for supporting the energy demand of these devices without the need to return to the dreaded wall outlet for recharging. While crystalline silicon dominates world markets, second- or third-generation solar cell technologies may be more suitable to wearable systems. Array size, architecture, and management must also be chosen to best serve portable and wearable devices and harvest light energy from different light sources under a broad range of input conditions. This book is intended to serve a wide audience from students who desire a basic introduction to solar (photovoltaic) cell technology to professionals seeking a holistic picture of wearable solar cells and systems.

This book examines the history of creative applications of photovoltaic (PV) solar power, including sound art, wearable technology, public art, industrial design, digital media, building integrated design, and many others. The growth in artists and designers incorporating solar power into their work reflects broader social, economic, and political events. As the cost of PV cells has come down, they have become more accessible and have found their way into a growing range of design applications and artistic practices. As climate change continues to transform our environment and becomes a greater public concern, the importance of integrating sustainable energy technologies into our culture grows as well. The book will be of interest to scholars working in art history, design history, design studies, environmental studies, environmental humanities, and sustainable energy design.

The book “Frontiers and Textile Materials will deal with the important materials that can be utilized for value-addition and functionalization of textile materials. The topics covered in this book includes the materials like enzymes, polymers, etc. that are utilized for conventional textile processing and the advanced materials like nanoparticles which are expected to change the horizons of textiles. The futuristic techniques for textile processing like plasma are also discussed.

Wearable Solar Cells Understand a groundbreaking new energy technology Solar energy is one of the most important paths to a sustainable future. In recent years, extensive research and development has begun to produce wearable solar cells, whose novel planar and fiber format gives them enormous flexibility and a wide range of potential uses. The possibility of a solar energy source that can be fitted to the human body promises to become an extraordinary tool for meeting various kinds of personal energy needs. Wearable Solar Cells: Mechanisms, Materials, and Devices serves as a comprehensive introduction to this cutting-edge technology and its applications. Recent research pointing towards fiber-format solar cells as a bold new frontier is summarized and explored. The result is an essential resource for both experienced researchers and newcomers to the field. Wearable Solar Cells readers will also find: Close coverage of integrated energy harvesting and storage devices Detailed discussion of dye-sensitized solar cells, polymer solar cells, perovskite solar cells, and more An authorial team with decades of combined research experience Wearable Solar Cells is ideal for materials scientists, polymer chemists, electrical engineers, solid-state physicists, and advanced students interested in these and related topics.

Beginning with an overview and historical background of Copper Zinc Tin Sulphide (CZTS) technology, subsequent chapters cover properties of CZTS thin films, different preparation methods of CZTS thin films, a comparative study of CZTS and CIGS solar cell, computational approach, and future applications of CZTS thin film solar modules to both ground-mount and rooftop installation. The semiconducting compound (CZTS) is made up earth-abundant, low-cost and non-toxic elements, which make it an ideal candidate to replace Cu(In,Ga)Se2 (CIGS) and CdTe solar cells which face material scarcity and toxicity issues. The device performance of CZTS-based thin film solar cells has been steadily improving over the past 20 years, and they have now reached near commercial efficiency levels (10%). These achievements prove that CZTS-based solar cells have the potential to be used for large-scale deployment of photovoltaics. With contributions from leading researchers from academia and industry, many of these authors have contributed to the improvement of its efficiency, and have rich experience in preparing a variety of semiconducting thin films for solar cells.