Structures in Science

Structures in Science
Author: Theo A.F. Kuipers
Publisher: Springer Science & Business Media
Total Pages: 440
Release: 2012-12-06
Genre: Science
ISBN: 9401597391

Although there is an abundance of highly specialized monographs, learned collections and general introductions to the philosophy of science, only a few 25 years. synthetic monographs and advanced textbooks have appeared in the last The philosophy of science seems to have lost its self-confidence. The main reason for such a loss is that the traditional analytical, logical-empiricist approaches to the philosophy of science had to make a number of concessions, especially in response to the work of Popper, Kuhn and Lakatos. With Structures in Science I intend to present both a synthetic mono graph and an advanced textbook that accommodates and integrates the insight of these philosophers, in what I like to call a neo-classical approach. The resulting monograph elaborates several important topics from one or more perspectives, by distinguishing various kinds of research programs, and various ways of explaining and reducing laws and concepts, and by summarizing an integrated explication (presented in From Instrumentalism to Constructive Realism, ICR) of the notions of confirmation, empirical progress and truth approximation.

Super Structures

Super Structures
Author: Mark Denny
Publisher: Johns Hopkins University Press+ORM
Total Pages: 391
Release: 2010-06-07
Genre: Technology & Engineering
ISBN: 0801899567

An “extraordinary guide to the hidden secrets of modern man-made miracles . . . Highly recommended” —from the author of Froth!: The Science of Beer (Midwest Book Review). Ever wonder how a graceful and slender bridge can support enormous loads over truly astonishing spans? Why domes and free-standing arches survive earthquakes that flatten the rest of a city? Physicist Mark Denny looks at the large structures around us—tall buildings, long bridges, and big dams—and explains how they were designed and built and why they sometimes collapse, topple, or burst. Denny uses clear, accessible language to explain the physics behind such iconic structures as the Parthenon, the Eiffel Tower, the Forth Rail Bridge in Edinburgh, and Hoover Dam. His friendly approach allows readers to appreciate the core principles that keep these engineering marvels upright without having to master complex mathematical equations. Employing history, humor, and simple physics to consider such topics as when to use screws or nails, what trusses are, why iron beams are often I-shaped, and why medieval cathedrals have buttresses, Denny succeeds once again in making physics fun. Praise for Mark Denny “Denny’s wry humor is fun to read and made me laugh out loud.” —Mark Kidger, author of Astronomical Enigmas “Denny largely sheds the complexity of mathematical constructs, distilling their most salient features into a more qualitative understanding of radar and sonar systems.” —Choice “Indeed, Denny’s writing is anything but dry and boring. He adeptly explains complex subject matter and does so with relatively simple language and minimal use of symbolic notation.” —Bat Research News

Science of Crystal Structures

Science of Crystal Structures
Author: Istvan Hargittai
Publisher: Springer
Total Pages: 331
Release: 2015-09-09
Genre: Science
ISBN: 3319198270

A volume which includes entries on quasicrystals, icosahedral packing, other packing considerations, extended structures, data treatment and data mining is presented by luminaries from the crystallography community. Several of the contributions are from the schools of such trend-setting crystallographers as J. Desmond Bernal and Aleksandr I. Kitaigorodskii. Internationally renowned scientists contributed such as Tom L. Blundell, Johann Jacob Burckhardt, John L. Finney, Jenny P. Glusker, Nobel laureate Herbert A. Hauptman, the 2014 Ewald-Prize winner A. Janner, Aminoff-Prize winner Isabella Karle, Nobel laureate Jerome Karle, Buckley-Prize winner Alan L. Mackay, Ewald-Prize winner David Sayre, Vladimir Shevchenko, and J. Fraser Stoddart. A few frontier topics dominate the selected material. Pioneers of the direct methods describe the phase problem and how it was solved, including the mathematical approach and the utilization of experience with gas-phase electron diffraction. The reviews by Herbert Hauptman, Jerome and Isabella Karle, and David Sayre reach to the present day in assessing the possibilities of X-ray crystallography. Another focus topic is the investigation of systems that are outside the so-called classical system of crystals. They include quasicrystals, imperfect and very small crystals, supramolecular species, crystal structures without lattice, clusters, nanomaterials among others. Application of synchrotron and cryoprotection techniques, the free-electron laser flash technique and others are mentioned in addition to X-ray crystallography. The relationship between structural and materials properties are examined and uncovered. The broader topics of the so-called generalized crystallography include polymers, clusters, polydisperse chain assemblies, and giant icosahedral fullerenes. There are some key contributions related to the structural investigation of biological macromolecules.

Edible Structures

Edible Structures
Author: José Miguel Aguilera
Publisher: CRC Press
Total Pages: 465
Release: 2012-10-18
Genre: Medical
ISBN: 1439898901

Nature converts molecules into edible structures, most of which are then transformed into products in factories and kitchens. Tasty food structures enter our mouths and different sensations invade our bodies. By the time these structures reach our cells, they have been broken back down into molecules that serve as fuel and raw materials for our bodies. Drawing from the physical and engineering sciences, food technology, nutrition, and gastronomy, Edible Structures: The Basic Science of What We Eat examines the importance of food structures—the supramolecular assemblies and matrices that are created by nature and when we cook—rather than the basic chemical compounds that are the more traditional focus of study. The central objectives of this book are to address the pressing food trends of this century, including: Growing evidence that flavorful food structures are important for the delivery of the nutritious and healthful food molecules from which they are made A need to understand and control how food structures are created and presented as products that respond to nutritional requirements Opportunities to design certain foods to better suit the needs of modern lifestyles The empowerment of consumers and the appearance of the axis that connects the food we eat with our brain, digestive system, and the cells in our body The separation between a knowledgeable gourmet "elite" and the rest of the population who simply want to eat quick meals as cheaply as possible Entertaining and informative, Edible Structures: The Basic Science of What We Eat uses scientific yet understandable terms throughout to facilitate the communication between experts and the educated public, especially those who are curious, love to cook and innovate in the kitchen and/or want to enjoy good food. The language and concepts presented in this book give the reader some access to specialized texts and scientific journals, and above all, to the best and most current information available on the Internet and other media.

Structures of Scientific Collaboration

Structures of Scientific Collaboration
Author: Wesley Shrum
Publisher: MIT Press
Total Pages: 295
Release: 2007
Genre: Academic-industrial collaboration
ISBN: 0262195593

How technology and bureaucracy shape collaborative scientific research projects: an empirical study of multiorganizational collaboration in the physical sciences. Collaboration among organizations is rapidly becoming common in scientific research as globalization and new communication technologies make it possible for researchers from different locations and institutions to work together on common projects. These scientific and technological collaborations are part of a general trend toward more fluid, flexible, and temporary organizational arrangements, but they have received very limited scholarly attention. Structures of Scientific Collaboration is the first study to examine multi-organizational collaboration systematically, drawing on a database of 53 collaborations documented for the Center for History of Physics of the American Institute of Physics. By integrating quantitative sociological analyses with detailed case histories, Shrum, Genuth, and Chompalov pioneer a new and truly interdisciplinary method for the study of science and technology. Scientists undertake multi-organizational collaborations because individual institutions often lack sufficient resources--including the latest technology--to achieve a given research objective. The authors find that collaborative research depends on both technology and bureaucracy; scientists claim to abhor bureaucracy, but most collaborations use it constructively to achieve their goals. The book analyzes the structural elements of collaboration (among them formation, size and duration, organization, technological practices, and participant experiences) and the relationships among them. The authors find that trust, though viewed as positive, is not necessarily associated with successful projects; indeed, the formal structures of bureaucracy reduce the need for high levels of trust--and make possible the independence so valued by participating scientists.

Bridges

Bridges
Author: David Blockley
Publisher: Oxford University Press
Total Pages: 329
Release: 2012-04-26
Genre: Architecture
ISBN: 0199645728

Bridges are remarkable structures. Often vast, immense, and sometimes beautiful, they can be icons of cities. David Blockley explains how to read a bridge, how they stand up, and how engineers design them to be so strong. He examines the engineering problems posed by bridges, and considers their cultural, aesthetic, and historical importance.

Build It!

Build It!
Author: Adrienne Mason
Publisher:
Total Pages: 40
Release: 2006
Genre: Juvenile Nonfiction
ISBN:

Introduces structures, including their function, the materials they are made of, and how their parts are joined together.