The national laboratories have occupied a central place in the landscape of American science for more than fifty years. Deeply researched and lucidly written, The National Labs is the first book to trace the confluence of diverse interests that created and sustained this extensive enterprise. Westwick takes us from the origins of the labs in the Manhattan Project to their role in building the hydrogen bomb, nuclear power reactors, and high-energy accelerators, to their subsequent entry into such fields as computers, meteorology, space science, molecular biology, environmental science, and alternative energy sources.
Limited by Design is the first comprehensive study of the varying roles played by the more than 16,000 research and development laboratories in the U.S. national innovation system. Michael Crow and Barry Bozeman offer policy makers and scientists a blueprint for making more informed decisions about how to best utilize and develop the capabilities of these facilities. Some labs, such as Bell Labs, Westinghouse, and Eastman Kodak, have been global players since the turn of the century. Others, such as Los Alamos National Laboratory, have been mainstays of the military/energy industrial complex since they evolved in the 1940s. These and other institutions have come to serve as the infrastructure upon which a range of industries have relied and have had a tremendous impact on U.S. social and economic history. Michael Crow and Barry Bozeman illustrate the histories, missions, structure, and behavior of individual laboratories, and explore the policy contexts in which they are embedded. In studying this large and varied collection of labs, Crow, Bozeman, and their colleagues develop a new framework for understanding the structure and behavior of laboratories that also provides a basis for rationalizing federal science and technology policy to create more effective laboratories. The book draws upon interviews and surveys collected from thousands of scientists, administrators, and policy makers, and features boxed "lab windows" throughout that provide detailed information on the variety of laboratories active in the U.S. national innovation system. Limited by Design addresses a range of questions in order to enable policy makers, university administrators, and scientists to plan effectively for the future of research and development.
Behind the scenes of the Lawrence Livermore National Laboratory, the quintessential American lab. Nobel laureate Ernest O. Lawrence and renowned physicist Edward Teller founded the Lawrence Livermore National Laboratory in 1952. A new ideas incubator, the Lab was at the heart of nuclear testing and the development of supercomputers, lasers, and other major technological innovations of the second half of the twentieth century. Many of its leaders became prominent figures in the technical and defense establishments, and by the end of the 1960s, Livermore was the peer of Los Alamos National Lab, a relationship that continues today. In The American Lab, former Livermore director C. Bruce Tarter offers unparalleled access to the inner workings of the Lab. Touching on Cold War nuclear science and the technological shift that occurred after the fall of the Berlin Wall, he traces the Lab’s evolution from its founding under University of California management through its transfer to private oversight. Along the way, he highlights important episodes in that journey, from the invention of Polaris, the first submarine-launched ballistic missile, to the Lab’s controversial role in the Star Wars program. He also describes Livermore’s significant responsibilities in stockpile stewardship, the program that ensures the safety and reliability of the US nuclear arsenal. The book portrays the lab’s extensive work on thermonuclear fusion, a potential source of unlimited energy; describes the development of the world’s largest laser fusion installation, the National Ignition Facility; and examines a number of smaller projects, such as the Lab’s participation in founding the Human Genome Project. Finally, it traces the relationship of the Lab to its federal sponsor, the Department of Energy, as it evolved from partnership to compliance with orders, a shift that affected all of the national laboratories. Drawing on oral histories, internal laboratory documents, and the author’s personal experiences from more than fifty years as a Lab employee, The American Lab is an illuminating history of the Lab and its revolutionary work.
Countering Cyber Sabotage: Introducing Consequence-Driven, Cyber-Informed Engineering (CCE) introduces a new methodology to help critical infrastructure owners, operators and their security practitioners make demonstrable improvements in securing their most important functions and processes. Current best practice approaches to cyber defense struggle to stop targeted attackers from creating potentially catastrophic results. From a national security perspective, it is not just the damage to the military, the economy, or essential critical infrastructure companies that is a concern. It is the cumulative, downstream effects from potential regional blackouts, military mission kills, transportation stoppages, water delivery or treatment issues, and so on. CCE is a validation that engineering first principles can be applied to the most important cybersecurity challenges and in so doing, protect organizations in ways current approaches do not. The most pressing threat is cyber-enabled sabotage, and CCE begins with the assumption that well-resourced, adaptive adversaries are already in and have been for some time, undetected and perhaps undetectable. Chapter 1 recaps the current and near-future states of digital technologies in critical infrastructure and the implications of our near-total dependence on them. Chapters 2 and 3 describe the origins of the methodology and set the stage for the more in-depth examination that follows. Chapter 4 describes how to prepare for an engagement, and chapters 5-8 address each of the four phases. The CCE phase chapters take the reader on a more granular walkthrough of the methodology with examples from the field, phase objectives, and the steps to take in each phase. Concluding chapter 9 covers training options and looks towards a future where these concepts are scaled more broadly.
This handbook serves as a guide to deploying battery energy storage technologies, specifically for distributed energy resources and flexibility resources. Battery energy storage technology is the most promising, rapidly developed technology as it provides higher efficiency and ease of control. With energy transition through decarbonization and decentralization, energy storage plays a significant role to enhance grid efficiency by alleviating volatility from demand and supply. Energy storage also contributes to the grid integration of renewable energy and promotion of microgrid.
The definitive history of America’s greatest incubator of innovation and the birthplace of some of the 20th century’s most influential technologies “Filled with colorful characters and inspiring lessons . . . The Idea Factory explores one of the most critical issues of our time: What causes innovation?” —Walter Isaacson, The New York Times Book Review “Compelling . . . Gertner's book offers fascinating evidence for those seeking to understand how a society should best invest its research resources.” —The Wall Street Journal From its beginnings in the 1920s until its demise in the 1980s, Bell Labs-officially, the research and development wing of AT&T-was the biggest, and arguably the best, laboratory for new ideas in the world. From the transistor to the laser, from digital communications to cellular telephony, it's hard to find an aspect of modern life that hasn't been touched by Bell Labs. In The Idea Factory, Jon Gertner traces the origins of some of the twentieth century's most important inventions and delivers a riveting and heretofore untold chapter of American history. At its heart this is a story about the life and work of a small group of brilliant and eccentric men-Mervin Kelly, Bill Shockley, Claude Shannon, John Pierce, and Bill Baker-who spent their careers at Bell Labs. Today, when the drive to invent has become a mantra, Bell Labs offers us a way to enrich our understanding of the challenges and solutions to technological innovation. Here, after all, was where the foundational ideas on the management of innovation were born.
For over a century, field stations have been important entryways for scientists to study and make important discoveries about the natural world. They are centers of research, conservation, education, and public outreach, often embedded in natural environments that range from remote to densely populated urban locations. Because they lack traditional university departmental boundaries, researchers at field stations have the opportunity to converge their science disciplines in ways that can change careers and entire fields of inquiry. Field stations provide physical space for immersive research, hands-on learning, and new collaborations that are otherwise hard to achieve in the everyday bustle of research and teaching lives on campus. But the separation from university campuses that allows creativity to flourish also creates challenges. Sometimes, field stations are viewed as remote outposts and are overlooked because they tend to be away from population centers and their home institutions. This view is exacerbated by the lack of empirical evidence that can be used to demonstrate their value to science and society. Enhancing the Value and Sustainability of Field Stations and Marine Laboratories in the 21st Century summarizes field stations' value to science, education, and outreach and evaluates their contributions to research, innovation, and education. This report suggests strategies to meet future research, education, outreach, infrastructure, funding, and logistical needs of field stations. Today's technologies - such as streaming data, remote sensing, robot-driven monitoring, automated DNA sequencing, and nanoparticle environmental sensors - provide means for field stations to retain their special connection to nature and still interact with the rest of the world in ways that can fuel breakthroughs in the environmental, physical, natural, and social sciences. The intellectual and natural capital of today's field stations present a solid platform, but many need enhancements of infrastructure and dynamic leadership if they are to meet the challenges of the complex problems facing the world. This report focuses on the capability of field stations to address societal needs today and in the future.
The world is being transformed physically and politically. Technology is the handmaiden of much of this change. But since the current sweep of global change is transforming the face of warfare, Special Operations Forces (SOF) must adapt to these circumstances. Fortunately, adaptation is in the SOF DNA. This book examines the changes affecting SOF and offers possible solutions to the complexities that are challenging many long-held assumptions. The chapters explore what has changed, what stays the same, and what it all means for U.S. SOF. The authors are a mix of leading experts in technology, business, policy, intelligence, and geopolitics, partnered with experienced special operators who either cowrote the chapters or reviewed them to ensure accuracy and relevance for SOF. Our goal is to provide insights into the changes around us and generate ideas about how SOF can adapt and succeed in the emerging operational environment.
