The study of the structure of molecular systems is an enduring area of research. This series is devoted to bringing together articles from leading workers in the field that draw together recent theoretical and experimental results and advances in understanding.

This guidebook introduces the reader to the visible memorabilia of science and scientists in Budapest - statues, busts, plaques, buildings, and other artefacts. According to the Hungarian-American Nobel laureate Albert Szent-Gyoergyi, this metropolis at the crossroads of Europe has a special atmosphere of respect for science. It has been the venue of numerous scientific achievements and the cradle, literally, of many individuals who in Hungary, and even more beyond its borders, became world-renowned contributors to science and culture. Six of the eight chapters of the book cover the Hungarian Nobel laureates, the Hungarian Academy of Sciences, the university, the medical school, agricultural sciences, and technology and engineering. One chapter is about selected secondary schools from which seven Nobel laureates (Szent-Gyoergyi, de Hevesy, Wigner, Gabor, Harsanyi, Olah, and Kertesz) and the five "Martians of Science" (von Karman, Szilard, Wigner, von Neumann, and Teller) had graduated. The concluding chapter is devoted to scientist martyrs of the Holocaust. A special feature in surveying Hungarian science is the contributions of scientists that left their homeland before their careers blossomed and made their seminal discoveries elsewhere, especially in Great Britain and the United States. The book covers the memorabilia referring to both emigre scientists and those that remained in Hungary. The discussion is informative and entertaining. The coverage is based on the visible memorabilia, which are not necessarily proportional with achievements. Therefore, there is a caveat that one could not compile a history of science relying solely on the presence of the memorabilia.

The title of our volume refers to what is well described by the following two quota tions: "Godcreated man in his own image"l and "Man creates God in his own image."2 Our approach to symmetry is subjective, and the term "personal" symmetry reflects this approach in our discussion of selected scientific events. We have chosen six icons to symbolize six areas: Kepler for modeling, Fuller for new molecules, Pauling for helical structures, Kitaigorodskii for packing, Bernal for quasicrystals, and Curie for dissymmetry. For the past three decades we have been involved in learning, thinking, speaking, and writing about symmetry. This involvement has augmented our principal activities in molecular structure research. Our interest in symmetry had started with a simple fascination and has evolved into a highly charged personal topic for us. At the start of this volume, we had had several authored and edited symmetry related books behind 3 us. We owe a debt of gratitude to the numerous people whose interviews are quoted 4 in this volume. We very much appreciate the kind and gracious cooperation of Edgar J. Applewhite (Washington, DC), Lawrence S. Bartell (University of Michigan), R."

Candid Science VI is the concluding volume of the series. It contains conversations with scientists from the biomedical sciences, chemistry, and physics. There are 31 Nobel laureates and 11 other luminaries among them. The scientists -- according to their loosely-defined fields -- are, in the biomedical sciences, Francis Crick, Sydney Brenner, Matthew Meselson, Paul M Nurse, R Timothy (Tim) Hunt, Seymour Benzer, Christiane Nusslein-Volhard, Werner Arber, David Baltimore, J Michael Bishop, Harold E Varmus, Peter Mansfield, Avram Hershko, Aaron Ciechanover, Irwin Rose, Alexander Varshavsky, Osamu Hayaishi; in chemistry, Ada Yonath, Isabella Karle, Jerome Karle, Yuan Tseh Lee, Darleane Hoffman; in physics, Richard L Garwin, Donald A Glaser, Nicholas Kurti, Herbert Kroemer, James Cronin, Wolfgang Panofsky, Burton Richter, Samuel Chao Chung Ting, Martin L Perl, Carlo Rubbia, Simon van der Meer, Douglas D Osheroff, Jack Steinberger, Masatoshi Koshiba, Riccardo Giacconi, Brian D Josephson, Ivar Giaever, Vitaly L Ginzburg, David Gross, and Frank Wilczek.

Candid Science VI is the concluding volume of the series. It contains conversations with scientists from the biomedical sciences, chemistry, and physics. There are 31 Nobel laureates and 11 other luminaries among them. The scientists -- according to their loosely-defined fields -- are, in the biomedical sciences, Francis Crick, Sydney Brenner, Matthew Meselson, Paul M Nurse, R Timothy (Tim) Hunt, Seymour Benzer, Christiane Nusslein-Volhard, Werner Arber, David Baltimore, J Michael Bishop, Harold E Varmus, Peter Mansfield, Avram Hershko, Aaron Ciechanover, Irwin Rose, Alexander Varshavsky, Osamu Hayaishi; in chemistry, Ada Yonath, Isabella Karle, Jerome Karle, Yuan Tseh Lee, Darleane Hoffman; in physics, Richard L Garwin, Donald A Glaser, Nicholas Kurti, Herbert Kroemer, James Cronin, Wolfgang Panofsky, Burton Richter, Samuel Chao Chung Ting, Martin L Perl, Carlo Rubbia, Simon van der Meer, Douglas D Osheroff, Jack Steinberger, Masatoshi Koshiba, Riccardo Giacconi, Brian D Josephson, Ivar Giaever, Vitaly L Ginzburg, David Gross, and Frank Wilczek.

In this book, 36 famous chemists, including 18 Nobel laureates, tell about their lives in science, the beginnings of their careers, their aspirations, and their hardships and triumphs. The reader will learn about their seminal discoveries, and the conversations in the book bring out the humanity of these great scientists. NMR spectroscopy, computational chemistry, the drama of buckminsterfullerene, the story of the Pill, the politics of atmospheric chemistry and the resonance theory, the beginnings of molecular mechanics and modern stereochemistry are examples of the topics discussed first-hand by, in all likelihood, the most appropriate persons.

In this book, 36 famous chemists, including 18 Nobel laureates, tell about their lives in science, the beginnings of their careers, their aspirations, and their hardships and triumphs. The reader will learn about their seminal discoveries, and the conversations in the book bring out the humanity of these great scientists. NMR spectroscopy, computational chemistry, the drama of buckminsterfullerene, the story of the Pill, the politics of atmospheric chemistry and the resonance theory, the beginnings of molecular mechanics and modern stereochemistry are examples of the topics discussed first-hand by, in all likelihood, the most appropriate persons.

Throughout history, women have overcome tremendous odds to make lasting contributions to science. In Meeting the Challenge, Magdolna Hargittai shares their stories. For centuries, women scientists have faced seemingly insurmountable barriers to success in their careers. Yet many have excelled in science, achieving some of the most important scientific breakthroughs in history. In her latest book, Magdolna Hargittai discusses over 120 such women scientists. The book details the lives and careers of women scientists from the past and present, from various parts of the world, and representing many different fields, including physics, chemistry, astronomy, mathematics, and medicine. Among the pioneering women profiled in the book are Nobel laureate and astronomer Andrea M. Ghez, medicinal physicist and Nobel laureate Rosalyn Yalow, Rosalind Franklin, the co-discoverer of the structure of DNA, and COVID-19 vaccine pioneer Katalin Karikó. The book also includes vignettes on the ecologist and author of Silent Spring, Rachel Carson, the primatologist Jane M. Goodall, and many others. These women demonstrate that despite the persistent idea that "science is not for women," women can and do succeed in science, even if success often requires courage and perseverance. Meeting the Challenge presents compelling human stories to inform and entertain readers and encourage those considering careers in science. By detailing the lives and achievements of many of the most important women scientists in history, the book makes a significant contribution to the history of science and provides role models for those interested in pursuing scientific careers.

Throughout the 1990s and the 2000s, Istvan, Balazs, and Magdolna Hargittai conducted hundreds of interviews with leading scientists in physics, chemistry, materials, and biomedical research. These interviews appeared in a variety of publications, including Chemical Intelligencer, Mathematical Intelligencer, and Chemical Heritage. In four-thousand pages of interviews, the Hargittais had conversations with over a hundred Nobel laureates, along with many other top minds and personalities in various scientific fields. Now, in a single volume, the Hargittais have gathered the best and most notable moments of these interviews, creating a survey of the past, present, and future of science, as told by some of the most influential members of many scientific disciplines. Figures like James D. Watson, Francis Crick, and Glenn T. Seaborg share their thoughts in these pages, in a collection that includes 68 Nobel Laureates. Without exaggeration, their backgrounds come from all over the globe: scientists from the United States, the United Kingdom, Canada, France, Germany, Israel, Russia, Sweden, Switzerland, and Taiwan are featured. These interviews discuss many of the most prominent debates and issues in today's scientific climate. Great Minds is a synthesis of scientific thought, as told by some of the most notable scientists of the twentieth and twenty-first centuries.

It is gratifying to launch the third edition of our book. Its coming to life testi?es about the task it has ful?lled in the service of the com- nity of chemical research and learning. As we noted in the Prefaces to the ?rst and second editions, our book surveys chemistry from the point of view of symmetry. We present many examples from ch- istry as well as from other ?elds to emphasize the unifying nature of the symmetry concept. Our aim has been to provide aesthetic pl- sure in addition to learning experience. In our ?rst Preface we paid tribute to two books in particular from which we learned a great deal; they have in?uenced signi?cantly our approach to the subject matter of our book. They are Weyl's classic, Symmetry, and Shubnikov and Koptsik's Symmetry in Science and Art. The structure of our book has not changed. Following the Int- duction (Chapter 1), Chapter 2 presents the simplest symmetries using chemical and non-chemical examples. Molecular geometry is discussed in Chapter 3. The next four chapters present gro- theoretical methods (Chapter 4) and, based on them, discussions of molecular vibrations (Chapter 5), electronic structures (Chapter 6), and chemical reactions (Chapter 7). For the last two chapters we return to a qualitative treatment and introduce space-group sym- tries (Chapter 8), concluding with crystal structures (Chapter 9). For the third edition we have further revised and streamlined our text and renewed the illustrative material.

It is gratifying to launch the third edition of our book. Its coming to life testi?es about the task it has ful?lled in the service of the com- nity of chemical research and learning. As we noted in the Prefaces to the ?rst and second editions, our book surveys chemistry from the point of view of symmetry. We present many examples from ch- istry as well as from other ?elds to emphasize the unifying nature of the symmetry concept. Our aim has been to provide aesthetic pl- sure in addition to learning experience. In our ?rst Preface we paid tribute to two books in particular from which we learned a great deal; they have in?uenced signi?cantly our approach to the subject matter of our book. They are Weyl's classic, Symmetry, and Shubnikov and Koptsik's Symmetry in Science and Art. The structure of our book has not changed. Following the Int- duction (Chapter 1), Chapter 2 presents the simplest symmetries using chemical and non-chemical examples. Molecular geometry is discussed in Chapter 3. The next four chapters present gro- theoretical methods (Chapter 4) and, based on them, discussions of molecular vibrations (Chapter 5), electronic structures (Chapter 6), and chemical reactions (Chapter 7). For the last two chapters we return to a qualitative treatment and introduce space-group sym- tries (Chapter 8), concluding with crystal structures (Chapter 9). For the third edition we have further revised and streamlined our text and renewed the illustrative material.

'The statuary and monuments catalogued in this impressive body of work are accompanied by descriptions of the subjects their work and achievements.'Chemistry WorldMoscow is the center of science and higher education of Russia and is also an international hub of science. There have been milestone achievements of science in Russia (and the Soviet Union), especially in the areas of physics, chemistry, mathematics, the conquest of space, various technologies and medicine. However, the scientists and inventors often created in isolation and have become less known than their discoveries would justify. At the same time, there is no other city in the world that has so many memorials honoring scientists as Moscow. There is a caveat in that political considerations have often influenced who was remembered and who was not. This book presents statues, memorial plaques, and historical buildings. Not only celebrated excellences are mentioned, but also some of the greats that perished during the years of terror. The book is full of human drama and 750 photos illustrate the narrative. Science in Moscow follows Budapest Scientific and New York Scientific and is the third in the series about memorials of scientists in great cities of the world.

Magdolna Hargittai uses over fifteen years of in-depth conversation with female physicists, chemists, biomedical researchers, and other scientists to form cohesive ideas on the state of the modern female scientist. The compilation, based on sixty conversations, examines unique challenges that women with serious scientific aspirations face. In addition to addressing challenges and the unjustifiable underrepresentation of women at the higher levels of academia, Hargittai takes a balanced approach by discussing how some of the most successful of these women have managed to obtain professional success and personal happiness. Women Scientists portrays scientists from different backgrounds, different geographical regions-eighteen countries from four continents-and leaders from a variety of professional backgrounds, including eight Nobel laureate women. The book is divided into three sections: "Husband and Wife Teams," "Women at the Top," and "In High Positions." Hargittai uses her own experience to introduce her first section on the lives of prominent scientific couples and addresses the joys and disadvantages of husband and wife teams. The second section is a comprehensive exploration of the struggles and triumphs of "women at the top." Hargittai introduces women from countries where relatively little has been written about female scientists. The final section focuses on women scientists involved with science administration and leadership. Hargittai's biographical sketches role models for budding scientists.The book is a much needed account of female presence and influence in the sciences.

This book introduces the reader to the statues, busts, and memorial plaques of scientists, explorers, medicine men and women, and inventors found in the bustling capital of the United Kingdom, London. The former capital of the British Empire, London remains a world center of trade, navigation, finance and many more. It is also a hub of science, the seat of the Royal Society, Royal Institution, Science Museum, British Museum, Natural History Museum, and of great institutions of higher education. The historical figures depicted in these memorials are responsible for creating great institutions, milestone discoveries, contributions to the scientific and technological revolutions, fighting against epidemics, advancing medicine, and contributing to the progress seen during the past four hundred years. This is a guidebook for the visitor and the Londoner alike. It presents memorials that everybody is familiar with and others that the authors discovered during their years of painstaking research. The 750 images and the text, interlarded with anecdotes, is both informative and entertaining.

The title of our volume refers to what is well described by the following two quota tions: "Godcreated man in his own image"l and "Man creates God in his own image."2 Our approach to symmetry is subjective, and the term "personal" symmetry reflects this approach in our discussion of selected scientific events. We have chosen six icons to symbolize six areas: Kepler for modeling, Fuller for new molecules, Pauling for helical structures, Kitaigorodskii for packing, Bernal for quasicrystals, and Curie for dissymmetry. For the past three decades we have been involved in learning, thinking, speaking, and writing about symmetry. This involvement has augmented our principal activities in molecular structure research. Our interest in symmetry had started with a simple fascination and has evolved into a highly charged personal topic for us. At the start of this volume, we had had several authored and edited symmetry related books behind 3 us. We owe a debt of gratitude to the numerous people whose interviews are quoted 4 in this volume. We very much appreciate the kind and gracious cooperation of Edgar J. Applewhite (Washington, DC), Lawrence S. Bartell (University of Michigan), R."