| Record ID | marc_columbia/Columbia-extract-20221130-034.mrc:10209691:6016 |
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LEADER: 06016cam a2200649Mi 4500
001 16622023
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006 m o d
007 cr |n|||||||||
008 180519s2018 nju ob 001 0 eng d
035 $a(OCoLC)on1036781636
035 $a(NNC)16622023
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019 $a1078944847$a1090386089$a1134571566
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082 04 $a620/.5$223
049 $aZCUA
100 1 $aZocchi, Giovanni,$eauthor.
245 10 $aMolecular machines :$ba materials science approach /$cGoivanni Zocchi.
264 1 $aPrinceton :$bPrinceton University Press,$c2018.
300 $a1 online resource (189 pages)
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
588 0 $aPrint version record.
520 $aMolecular Machines presents a dynamic new approach to the physics of enzymes and DNA from the perspective of materials science. Unified around the concept of molecular deformability--how proteins and DNA stretch, fold, and change shape--this book describes the complex molecules of life from the innovative perspective of materials properties and dynamics, in contrast to structural or purely chemical approaches. It covers a wealth of topics, including nonlinear deformability of enzymes and DNA; the chemo-dynamic cycle of enzymes; supra-molecular constructions with internal stress; nano-rheology and viscoelasticity; and chemical kinetics, Brownian motion, and barrier crossing. Essential reading for researchers in materials science, engineering, and nanotechnology, the book also describes the landmark experiments that have established the materials properties and energy landscape of large biological molecules. Molecular Machines is also ideal for the classroom. It gives graduate students a working knowledge of model building in statistical mechanics, making it an essential resource for tomorrow's experimentalists in this cutting-edge field. In addition, mathematical methods are introduced in the bio-molecular context--for example, DNA conformational transitions are used to illustrate the transfer matrix formalism. The result is a generalized approach to mathematical problem solving that enables students to apply their findings more broadly. Molecular Machines represents the next leap forward in nanoscience, as researchers strive to harness proteins, enzymes, and DNA as veritable machines in medicine, technology, and beyond.
504 $aIncludes bibliographical references (pages 165-172) and index.
505 0 $aCover; Title; Copyright; CONTENTS; Preface; Acknowledgments; Dedication; 1 Brownian Motion; 1.1 Random Walk; 1.2 Polymer as a Simple Random Walk; 1.3 Direct Calculation of p(R); 1.4 The Langevin Approach; 1.5 Correlation Functions; 1.6 Barrier Crossing; 1.7 What is Equilibrium?; 2 Statics of DNA Deformations; 2.1 Introduction; 2.2 DNA Melting; 2.3 Zipper Model; 2.4 Experimental Melting Curves; 2.5 Base Pairing and Base Stacking as Separate Degrees of Freedom; 2.6 Hamiltonian Formulation of the Zipper Model; 2.7 2 × 2Model: Cooperativity from Local Rules; 2.8 Nearest Neighbor Model.
505 8 $a2.9 Connection to Nonlinear Dynamics2.10 Linear and Nonlinear Elasticity of DNA; 2.11 Bending Modulus and Persistence Length; 2.12 Measurements of DNA Elasticity: Long Molecules; 2.13 Measurements of DNA Elasticity: Short Molecules; 2.14 The Euler Instability; 2.15 The DNA Yield Transition; 3 Kinematics of Enzyme Action; 3.1 Introduction; 3.2 Michaelis-Menten Kinetics; 3.3 The Method of the DNA Springs; 3.4 Force and Elastic Energy in the Enzyme-DNA Chimeras; 3.5 Injection of Elastic Energy vs. Activity Modulation; 3.6 Connection to Nonlinear Dynamics: Two Coupled Nonlinear Springs.
505 8 $a4 Dynamics of Enzyme Action4.1 Introduction; 4.2 Enzymes are Viscoelastic; 4.3 Nonlinearity of the Enzyme's Mechanics; 4.4 Timescales; 4.5 Enzymatic Cycle and Viscoelasticity: Motors; 4.6 Internal Dissipation; 4.7 Origin of the Restoring Force g; 4.8 Models Based on Chemical Kinetics (Fisher and Kolomeisky, 1999); 4.9 Different Levels of Microscopic Description; 4.10 Connection to Information Flow; 4.11 Normal Mode Analysis; 4.12 Many States of the Folded Protein: Spectroscopy; 4.13 Interesting Topics in Nonequilibrium Thermodynamics Relating to Enzyme Dynamics; Bibliography.
505 8 $aChapter 1: Brownian MotionChapter 2: Statics of DNA Deformations; Chapter 3: Kinematics of Enzyme Action; Chapter 4: Dynamics of Enzyme Action; Index.
650 0 $aMolecular machinery.
650 0 $aNanoscience.
650 0 $aNanotechnology.
650 6 $aMachinerie moléculaire.
650 6 $aNanosciences.
650 7 $aTECHNOLOGY & ENGINEERING$xEngineering (General)$2bisacsh
650 7 $aTECHNOLOGY & ENGINEERING$xReference.$2bisacsh
650 7 $aMolecular machinery.$2fast$0(OCoLC)fst01983326
650 7 $aNanoscience.$2fast$0(OCoLC)fst01032629
650 7 $aNanotechnology.$2fast$0(OCoLC)fst01032639
655 0 $aElectronic books.
655 4 $aElectronic books.
776 08 $iPrint version:$aZocchi, Giovanni.$tMolecular Machines : A Materials Science Approach.$dPrinceton : Princeton University Press, ©2018$z9780691173863
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio16622023$zACADEMIC - General Engineering & Project Administration
852 8 $blweb$hEBOOKS