Captivating poems and visual art seek to bring comfort and solidarity to anyone living with Bipolar Disorder. In this remarkable debut, Shira Erlichman pens a love letter to Lithium, her medication for Bipolar Disorder. With inventiveness, compassion, and humor, she thrusts us into a world of unconventional praise. From an unexpected encounter with her grandmother’s ghost, to a bubble bath with Bjӧrk, to her plumber’s confession that he, too, has Bipolar, Erlichman buoyantly topples stigma against the mentally ill. These are necessary odes to self-acceptance, resilience, and the jagged path toward healing. With startling language, and accompanied by her bold drawings and collages, she gives us a sparkling, original view into what makes us human.
The remarkable untold story of a miracle drug, the forgotten pioneer who discovered it, and the fight to bring lithium to the masses. The DNA double helix, penicillin, the X-ray, insulin—these are routinely cited as some of the most important medical discoveries of the twentieth century. And yet, the 1949 discovery of lithium as a cure for bipolar disorder is perhaps one of the most important—yet largely unsung—breakthroughs of the modern era. In Lithium, Walter Brown, a practicing psychiatrist and professor at Brown, reveals two unlikely success stories: that of John Cade, the physician whose discovery would come to save an untold number of lives and launch a pharmacological revolution, and that of a miraculous metal rescued from decades of stigmatization. From insulin comas and lobotomy to incarceration to exile, Brown chronicles the troubling history of the diagnosis and (often ineffective) treatment of bipolar disorder through the centuries, before the publication of a groundbreaking research paper in 1949. Cade’s “Lithium Salts in the Treatment of Psychotic Excitement” described, for the first time, lithium’s astonishing efficacy at both treating and preventing the recurrence of manic-depressive episodes, and would eventually transform the lives of patients, pharmaceutical researchers, and practicing physicians worldwide. And yet, as Brown shows, it would be decades before lithium would overcome widespread stigmatization as a dangerous substance, and the resistance from the pharmaceutical industry, which had little incentive to promote a naturally occurring drug that could not be patented. With a vivid portrait of the story’s unlikely hero, John Cade, Brown also describes a devoted naturalist who, unlike many modern medical researchers, did not benefit from prestigious research training or big funding sources (Cade’s “laboratory” was the unused pantry of an isolated mental hospital). As Brown shows, however, these humble conditions were the secret to his historic success: Cade was free to follow his own restless curiosity, rather than answer to an external funding source. As Lithium makes tragically clear, medical research—at least in America—has transformed in such a way that serendipitous discoveries like Cade’s are unlikely to occur ever again. Recently described by the New York Times as the “Cinderella” of psychiatric drugs, lithium has saved countless of lives and billions of dollars in healthcare costs. In this revelatory biography of a drug and the man who fought for its discovery, Brown crafts a captivating picture of modern medical history—revealing just how close we came to passing over this extraordinary cure.
Lithium Process Chemistry: Resources, Extraction, Batteries and Recycling presents, for the first time, the most recent developments and state-of-the-art of lithium production, lithium-ion batteries, and their recycling. The book provides fundamental and theoretical knowledge on hydrometallurgy and electrochemistry in lithium-ion batteries, including terminology related to these two fields. It is of particular interest to electrochemists who usually have no knowledge in hydrometallurgy and hydrometallurgists not familiar with electrochemistry applied to Li-ion batteries. It is also useful for both teachers and students, presenting an overview on Li production, Li-ion battery technologies, and lithium battery recycling processes that is accompanied by numerous graphical presentations of different battery systems and their electrochemical performances. The book represents the first time that hydrometallurgy and electrochemistry on lithium-ion batteries are assembled in one unique source. - Provides fundamental and theoretical knowledge on hydrometallurgy and electrochemistry in lithium-ion batteries - Represents the first time that hydrometallurgy and electrochemistry on lithium-ion batteries are assembled in one unique source. - Ideal for both electrochemists who usually have no knowledge in hydrometallurgy and hydrometallurgists not familiar with electrochemistry applied to Li-ion batteries - Presents recent developments, as well as challenges in lithium production and lithium-ion battery technologies and their recycling - Covers examples of Li processes production with schematics, also including numerous graphical presentations of different battery systems and their electrochemical performances
A global energy revolution is unfolding before our eyes: ever-growing numbers of electric vehicles on our roads, laptops that last all day on a single charge and solar panels on our roofs, all reliant on lithium-ion batteries. This revolution is happening at breath-taking speed, with the potential to completely transform key industries and the way we live. For the first time in history, we can now actually store this green energy we talk so much about. Often referred to as ‘the new oil’, lithium allows large amounts of energy to be squeezed into a very small space. Demand is soaring, and the lithium business is full of drama: bitter rivalries, shady deals and exceptionally talented visionaries such as Elon Musk, who is building lithium battery giga-factories across the world. This book travels from the salt lakes of the Tibetan plateau, where Chinese government–linked companies extract lithium, to Argentina, Chile and Bolivia, which hold the world’s biggest resources of the mineral. It reveals superpowers’ struggle to secure strategic supplies, and the astonishing efforts of lone-wolf inventors and entrepreneurs. Lithium also explores the environmental impact of lithium extraction, the limits to battery electrification, and lithium battery recycling as the way forward.
This work summarizes the historical progression of the field of lithium (Li) isotope studies and provides a comprehensive yet succinct overview of the research applications toward which they have been directed. In synthesizing the historical and current research, the volume also suggests prospective future directions of study. Not even a full decade has passed since the publication of a broadly inclusive summary of Li isotope research around the globe (Tomascak, 2004). In this short time, the use of this isotope system in the investigation of geo- and cosmochemical questions has increased dramatically, due, in part, to the advent of new analytical technology at the end of the last millennium. Lithium, as a light element that forms low-charge, moderate-sized ions, manifests a number of chemical properties that make its stable isotope system useful in a wide array of geo- and cosmochemical research fields.
A guide to lithium sulfur batteries that explores their materials, electrochemical mechanisms and modelling and includes recent scientific developments Lithium Sulfur Batteries (Li-S) offers a comprehensive examination of Li-S batteries from the viewpoint of the materials used in their construction, the underlying electrochemical mechanisms and how this translates into the characteristics of Li-S batteries. The authors – noted experts in the field – outline the approaches and techniques required to model Li-S batteries. Lithium Sulfur Batteries reviews the application of Li-S batteries for commercial use and explores many broader issues including the development of battery management systems to control the unique characteristics of Li-S batteries. The authors include information onsulfur cathodes, electrolytes and other components used in making Li-S batteries and examine the role of lithium sulfide, the shuttle mechanism and its effects, and degradation mechanisms. The book contains a review of battery design and: Discusses electrochemistry of Li-S batteries and the analytical techniques used to study Li-S batteries Offers information on the application of Li-S batteries for commercial use Distills years of research on Li-S batteries into one comprehensive volume Includes contributions from many leading scientists in the field of Li-S batteries Explores the potential of Li-S batteries to power larger battery applications such as automobiles, aviation and space vehicles Written for academic researchers, industrial scientists and engineers with an interest in the research, development, manufacture and application of next generation battery technologies, Lithium Sulfur Batteries is an essential resource for accessing information on the construction and application of Li-S batteries.
Silicon Anode Systems for Lithium-Ion Batteries is an introduction to silicon anodes as an alternative to traditional graphite-based anodes. The book provides a comprehensive overview including abundance, system voltage, and capacity. It provides key insights into the basic challenges faced by the materials system such as new configurations and concepts for overcoming the expansion and contraction related problems. This book has been written for the practitioner, researcher or developer of commercial technologies. - Provides a thorough explanation of the advantages, challenge, materials science, and commercial prospects of silicon and related anode materials for lithium-ion batteries - Provides insights into practical issues including processing and performance of advanced Si-based materials in battery-relevant materials systems - Discusses suppressants in electrolytes to minimize adverse effects of solid electrolyte interphase (SEI) formation and safety limitations associated with this technology
Handbook of Lithium and Natural Calcium Chloride is concerned with two major industrial minerals: Lithium and Calcium Chloride. The geology of their deposits is first reviewed, along with discussions of most of the major deposits and theories of their origin. The commercial mining and processing plants are next described, followed by a review of the rather extensive literature on other proposed processing methods. The more important uses for lithium and calcium chloride are next covered, along with their environmental considerations. This is followed by a brief review of the production statistics for each industry, and some of their compounds' phase data and physical properties. Describes the chemistry, chemical engineering, geology and mineral processing aspects of lithium and calcium chloride Collects in one source the most important information concerning these two industrial minerals Presents new concepts and more comprehensive theories on their origin
Lithium-Ion Battery Chemistries: A Primer offers a simple description on how different lithium-ion battery chemistries work, along with their differences. It includes a refresher on the basics of electrochemistry and thermodynamics, and an understanding of the fundamental processes that occur in the lithium-ion battery. Furthermore, it reviews each of the major chemistries that are in use today, including Lithium-Iron Phosphate (LFP), Lithium-Cobalt Oxide (LCO), Lithium Manganese Oxide (LMO), Lithium-Nickel Manganese Cobalt (NMC), Lithium-Nickel Cobalt Aluminium (NCA), and Lithium-Titanate Oxide (LTO) and outlines the different types of anodes, including carbon (graphite, hard carbon, soft carbon, graphene), silicon, and tin. In addition, the book offers performance comparisons of different chemistries to help users select the right battery for the right application and provides explanations on why different chemistries have different performances and capabilities. Finally, it offers a brief look at emerging and beyond-lithium chemistries, including lithium-air, zinc-air, aluminum air, solid-state, lithium-sulfur, lithium-glass, and lithium-metal. - Presents a refresher on the basics of electrochemistry and thermodynamics, along with simple graphics and images of complex concepts - Provides a clear-and-concise description of lithium-ion chemistries and how they operate - Covers the fundamental processes that occur in lithium-ion batteries - Includes a detailed review of current and future chemistries