The United States economy relies on the productivity, entrepreneurship, and creativity of its people. To maintain its scientific and engineering leadership amid increasing economic and educational globalization, the United States must aggressively pursue the innovative capacity of all its people—women and men. However, women face barriers to success in every field of science and engineering; obstacles that deprive the country of an important source of talent. Without a transformation of academic institutions to tackle such barriers, the future vitality of the U.S. research base and economy are in jeopardy. Beyond Bias and Barriers explains that eliminating gender bias in academia requires immediate overarching reform, including decisive action by university administrators, professional societies, federal funding agencies and foundations, government agencies, and Congress. If implemented and coordinated across public, private, and government sectors, the recommended actions will help to improve workplace environments for all employees while strengthening the foundations of America's competitiveness.

Gender Differences at Critical Transitions in the Careers of Science, Engineering, and Mathematics Faculty presents new and surprising findings about career differences between female and male full-time, tenure-track, and tenured faculty in science, engineering, and mathematics at the nation's top research universities. Much of this congressionally mandated book is based on two unique surveys of faculty and departments at major U.S. research universities in six fields: biology, chemistry, civil engineering, electrical engineering, mathematics, and physics. A departmental survey collected information on departmental policies, recent tenure and promotion cases, and recent hires in almost 500 departments. A faculty survey gathered information from a stratified, random sample of about 1,800 faculty on demographic characteristics, employment experiences, the allocation of institutional resources such as laboratory space, professional activities, and scholarly productivity. This book paints a timely picture of the status of female faculty at top universities, clarifies whether male and female faculty have similar opportunities to advance and succeed in academia, challenges some commonly held views, and poses several questions still in need of answers. This book will be of special interest to university administrators and faculty, graduate students, policy makers, professional and academic societies, federal funding agencies, and others concerned with the vitality of the U.S. research base and economy.

In the United States, broad study in an array of different disciplines â€"arts, humanities, science, mathematics, engineeringâ€" as well as an in-depth study within a special area of interest, have been defining characteristics of a higher education. But over time, in-depth study in a major discipline has come to dominate the curricula at many institutions. This evolution of the curriculum has been driven, in part, by increasing specialization in the academic disciplines. There is little doubt that disciplinary specialization has helped produce many of the achievement of the past century. Researchers in all academic disciplines have been able to delve more deeply into their areas of expertise, grappling with ever more specialized and fundamental problems. Yet today, many leaders, scholars, parents, and students are asking whether higher education has moved too far from its integrative tradition towards an approach heavily rooted in disciplinary "silos". These "silos" represent what many see as an artificial separation of academic disciplines. This study reflects a growing concern that the approach to higher education that favors disciplinary specialization is poorly calibrated to the challenges and opportunities of our time. The Integration of the Humanities and Arts with Sciences, Engineering, and Medicine in Higher Education examines the evidence behind the assertion that educational programs that mutually integrate learning experiences in the humanities and arts with science, technology, engineering, mathematics, and medicine (STEMM) lead to improved educational and career outcomes for undergraduate and graduate students. It explores evidence regarding the value of integrating more STEMM curricula and labs into the academic programs of students majoring in the humanities and arts and evidence regarding the value of integrating curricula and experiences in the arts and humanities into college and university STEMM education programs.

This guide offers helpful advice on how teachers, administrators, and career advisers in science and engineering can become better mentors to their students. It starts with the premise that a successful mentor guides students in a variety of ways: by helping them get the most from their educational experience, by introducing them to and making them comfortable with a specific disciplinary culture, and by offering assistance with the search for suitable employment. Other topics covered in the guide include career planning, time management, writing development, and responsible scientific conduct. Also included is a valuable list of bibliographical and Internet resources on mentoring and related topics.

In 2001, the National Science Foundation's ADVANCE Institutional Transformation program began awarding five-year grants to colleges and universities to address a common problem: how to improve the work environment for women faculty in science and engineering. Drawing on the expertise of scientists, engineers, social scientists, specialists in organizational behavior, and university administrators, this collection is the first to describe the variety of innovative efforts academic institutions around the country have undertaken. Focusing on a wide range of topics, from how to foster women's academic success in small teaching institutions, to how to use interactive theater to promote faculty reflection about departmental culture, to how a particular department created and maintained a healthy climate for women's scientific success, the contributors discuss both the theoretical and empirical aspects of the initiatives, with emphasis on the practical issues involved in creating these approaches. The resulting evidence shows that these initiatives have the desired effects. The cases represented in this collection depict the many issues women faculty in science and engineering face, and the solutions that are presented can be widely accepted at academic institutions around the United States. The essays inTransforming Science and Engineeringillustrate that creating work environments that sustain and advance women scientists and engineers benefits women, men, and underrepresented minorities. Abigail J. Stewart is Sandra Schwartz Tangri Distinguished University Professor of Psychology and Women's Studies at the University of Michigan and author or editor of several books, includingTheorizing Feminism: Parallel Trends in the HumanitiesandSocial Sciences and Feminisms in the Academy. Janet E. Malley is a psychologist and Associate Director of the Institute for Research on Women and Gender at the University of Michigan. Danielle LaVaque-Manty is Research Associate at the Institute for Research on Women and Gender at the University of Michigan. Cover photo: Joanne Leonard With a foreword by Mary Sue Coleman, President of the University of Michigan "If you have thrown up your hands in despair after trying to retain women science and engineering in the academy, read this book. It offers detailed descriptions of a wide array of tried-and-true programs that have been tested out by the NSF ADVANCE program." ---Joan C. Williams, 1066 Foundation Chair & Distinguished Professor of Law Director, Center for WorkLife Law University of California "Solid and practical, this volume details the first years of NSF funded institutional change to remake gender dynamics inside U.S. science. What works? What doesn't? And why?" ---Londa Schiebinger, John L. Hinds Professor of History of Science and Barbara D. Finberg Director, Michelle R. Clayman Institute for Gender Research at Stanford University, and author ofHas Feminism Changed Science? "This book's time has come.Transforming Science and Engineeringis important, and lots of people can learn from what has happened in the ADVANCE universities." ---Lotte Bailyn, Professor of Management, Behavioral and Policy Sciences Department, Sloan School of Management, MIT; author ofBreaking the Mold: Redesigning Work for Productive and Satisfying Lives; and coauthor ofBeyond Work-Family Balance: Advancing Gender Equity and Workplace Performance "This collection profiles 16 NSF ADVANCE grant successes, sandwiched between an interview with Dr. Alice Hogan and Dr. Lee Harle's summary of cost-effective practices from ADVANCE programs, giving so many 'biggest bang for the buck' examples in so few pages that it will easily justify both the cost of the book and the reading time. These accounts do not continue the too-c

The information age has grown out of the work of experimental computer science, which is dedicated to the development of new hardware, software, graphics, interfaces, and other computer system technologies. While it is important to society in this larger sense, experimental computer science has found an awkward fit in university environments. This volume examines what is special about experimental computer science and what can be done to achieve a better fit for its practitioners in the academic context.

The way in which academic engineering research is financed and public expectations for the outcomes from such research are changing at an unprecedented rate. The decrease in support of defense-related research, coupled with the realization that many U.S. technological products are no longer competitive in the global market, has sent a shock wave through research universities that train engineers. This book argues for several concrete actions on the part of universities, government, and industry to ensure the flow and relevance of technical talent to meet national social and economic goals, to maintain a position of leadership in the global economy, and to preserve and enhance the nation's engineering knowledge base.