Nanosystems: Molecular Machinery, Manufacturing, and Computation"Devices enormously smaller than before will remodel engineering,chemistry, medicine, and computer technology. How can we understandmachines that are so small? Nanosystems covers it all: powerand strength, friction and wear, thermal noise and quantumuncertainty. This is the book for starting the next century ofengineering." - Marvin Minsky MIT Science magazine calls Eric Drexler "Mr. Nanotechnology."For years, Drexler has stirred controversy by declaring thatmolecular nanotechnology will bring a sweeping technologicalrevolution - delivering tremendous advances in miniaturization,materials, computers, and manufacturing of all kinds. Now, he'swritten a detailed, top-to-bottom analysis of molecular machinery -how to design it, how to analyze it, and how to build it.Nanosystems is the first scientifically detailed description ofdevelopments that will revolutionize most of the industrialprocesses and products currently in use. This groundbreaking work draws on physics and chemistry toestablish basic concepts and analytical tools. The book thendescribes nanomechanical components, devices, and systems,including parallel computers able to execute 1020 instructions persecond and desktop molecular manufacturing systems able to makesuch products. Via chemical and biochemical techniques, proximalprobe instruments, and software for computer-aided moleculardesign, the book charts a path from present laboratory capabilitiesto advanced molecular manufacturing. Bringing together physics,chemistry, mechanical engineering, and computer science,Nanosystems provides an indispensable introduction to theemerging field of molecular nanotechnology. |
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Page 169
... magnitude p = hk = hw / v1 = E / Vs ( 7.26 ) where k in this section is to be taken as the magnitude of the wave vector ( in rad / m ) and v , is the speed of sound ( here again approximated as constant for all frequencies and modes ) ...
... magnitude p = hk = hw / v1 = E / Vs ( 7.26 ) where k in this section is to be taken as the magnitude of the wave vector ( in rad / m ) and v , is the speed of sound ( here again approximated as constant for all frequencies and modes ) ...
Page 202
... magnitude for Al is ~ -0.1 nm , and feasible compressive loads can extend to > 5 nN , which would once again yield a characteristic energy of ~ 500 maJ . ( Section 8.5.2a and 8.5.4 develop more realistic estimates for certain systems ...
... magnitude for Al is ~ -0.1 nm , and feasible compressive loads can extend to > 5 nN , which would once again yield a characteristic energy of ~ 500 maJ . ( Section 8.5.2a and 8.5.4 develop more realistic estimates for certain systems ...
Page 384
... magnitude with increasing molec- ular size , polarizability , and dipole moments . Feasible hydrostatic pressures ( i.e. , those that do not cause the liquid to solidify ) tend to decrease with the same variables . The magnitudes of ...
... magnitude with increasing molec- ular size , polarizability , and dipole moments . Feasible hydrostatic pressures ( i.e. , those that do not cause the liquid to solidify ) tend to decrease with the same variables . The magnitudes of ...
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approximation assembly assumed atoms barrier bond carbon Chapter chemical chemistry classical complex components compression computational constraints continuum models covalent density described devices diamond diamondoid structures discussed displacement drive effects elastic electronic electrostatic energy dissipation engineering entropy equilibrium estimated Figure force free energy frequency function gears geometry hydrogen input interactions interface intersystem crossing knob ligand logic rod macroscale magnitude manufacturing systems mass mechanochemical mechanosynthesis modulus moieties molecular manufacturing molecular mechanics molecular nanotechnology molecules motion nanomechanical systems nanometer nanoscale nonbonded nonbonded interactions operations oscillator parameters phonon pi bond position potential energy potential energy surface protein quantum mechanical radiation radical range rates reaction reactive reagent reagent moieties receptor resulting rotation scale Section shear sigma bonds sliding solution-phase specific speed stability statistical mechanics steric stiffness substantial surface synthesis temperature theoretical applied science thermal tion transition transition state theory typical values vibrational volume yields