Nanosystems: molecular machinery, manufacturing, and computation
"Written by a leading researcher in the field and one of its founders, Nanosystems is the first technical introduction to molecular nanotechnology - an emerging field that has sparked increasing interest and controversy. This groundbreaking book describes fundamental physical principles, compon...
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| Format: | Buch |
| Sprache: | English |
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New York, NY [u.a.]
Wiley
1992
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| Schriftenreihe: | A Wiley interscience publication
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| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Zusammenfassung: | "Written by a leading researcher in the field and one of its founders, Nanosystems is the first technical introduction to molecular nanotechnology - an emerging field that has sparked increasing interest and controversy. This groundbreaking book describes fundamental physical principles, components and devices, then examines applications including computers of unprecedented power and manufacturing systems able to build such products molecule by molecule." "Nanosystems presents a comprehensive overview of how molecular manufacturing will make products by using nanoscale (billionths of a meter) mechanical and robotic technologies to guide the placement of molecules and atoms. Working with these fundamental building blocks of matter will enable designers to approach the limits of the possible: to build the smallest devices, the fastest computers, the strongest materials, and the highest quality products. By manipulating common molecules at high frequency, molecular manufacturing will make these products quickly, inexpensively, and on a large scale. Molecular manufacturing is the key to implementing molecular nanotechnologies, building systems to complex atomic specifications." "This landmark work first presents the basic principles of physics and chemistry required to understand molecular machines. Then, Dr. Drexler describes computational models of molecules as mechanical systems, the effects of statistical mechanics, quantum uncertainty, damage mechanisms, and energy dissipation, and the fundamentals of mechanosynthesis - the use of mechanical devices to guide molecular reactions." "Nanosystems then applies the analytical tools and concepts developed in the first section to the design of nanomechanical components, devices, and systems. It describes nanomechanical gears, bearings, motors, sensors, logic gates, submicron 1000 MIPS computers (consuming 10[superscript -8] times as much power as comparable computers today), and systems able to join simple molecules to build complex products. The last section discusses how chemical, biochemical, and proximal probe technologies can be used to build complex molecular objects and how this capability can be used to implement molecular manufacturing." "Bringing together physics, chemistry, mechanical engineering, and computer science, Nanosystems provides an indispensable introduction to the emerging field of molecular nanotechnology."--BOOK JACKET |
| Beschreibung: | Literaturverz. S. 535 - 546 |
| Beschreibung: | XX, 556 S. Ill., graph. Darst. 26 cm |
| ISBN: | 0471575186 9780471575184 047157547X |
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| 245 | 1 | 0 | |a Nanosystems |b molecular machinery, manufacturing, and computation |c K. Eric Drexler |
| 264 | 1 | |a New York, NY [u.a.] |b Wiley |c 1992 | |
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| 490 | 0 | |a A Wiley interscience publication | |
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| 520 | 1 | |a "Written by a leading researcher in the field and one of its founders, Nanosystems is the first technical introduction to molecular nanotechnology - an emerging field that has sparked increasing interest and controversy. This groundbreaking book describes fundamental physical principles, components and devices, then examines applications including computers of unprecedented power and manufacturing systems able to build such products molecule by molecule." "Nanosystems presents a comprehensive overview of how molecular manufacturing will make products by using nanoscale (billionths of a meter) mechanical and robotic technologies to guide the placement of molecules and atoms. Working with these fundamental building blocks of matter will enable designers to approach the limits of the possible: to build the smallest devices, the fastest computers, the strongest materials, and the highest quality products. By manipulating common molecules at high frequency, molecular manufacturing will make these products quickly, inexpensively, and on a large scale. Molecular manufacturing is the key to implementing molecular nanotechnologies, building systems to complex atomic specifications." "This landmark work first presents the basic principles of physics and chemistry required to understand molecular machines. Then, Dr. Drexler describes computational models of molecules as mechanical systems, the effects of statistical mechanics, quantum uncertainty, damage mechanisms, and energy dissipation, and the fundamentals of mechanosynthesis - the use of mechanical devices to guide molecular reactions." | |
| 520 | |a "Nanosystems then applies the analytical tools and concepts developed in the first section to the design of nanomechanical components, devices, and systems. It describes nanomechanical gears, bearings, motors, sensors, logic gates, submicron 1000 MIPS computers (consuming 10[superscript -8] times as much power as comparable computers today), and systems able to join simple molecules to build complex products. The last section discusses how chemical, biochemical, and proximal probe technologies can be used to build complex molecular objects and how this capability can be used to implement molecular manufacturing." "Bringing together physics, chemistry, mechanical engineering, and computer science, Nanosystems provides an indispensable introduction to the emerging field of molecular nanotechnology."--BOOK JACKET | ||
| 650 | 7 | |a Ciencias da engenharia |2 larpcal | |
| 650 | 7 | |a Moleculaire nanotechnologie |2 gtt | |
| 650 | 4 | |a Nanotechnology | |
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Datensatz im Suchindex
| _version_ | 1804122569454911488 |
|---|---|
| adam_text | Titel: Nanosystems
Autor: Drexler, K. Eric
Jahr: 1992
Contents
Preface xvii
The intended readership. The nature of the subject.
Criticism of criticism. Use of tenses. Citations and apologies.
Acknowledgments.
Chapter 1 Introduction and Overview 1
1.1. Why molecular manufacturing? 1
1.2. What is molecular manufacturing? 1
Example: a nanomechanical bearing. A chemical perspective on
molecular manufacturing. Exposition vs. implementation sequence.
1.3. Comparisons 7
Conventional fabrication and mechanical engineering.
Microfabrication and microtechnology. Solution-phase chemistry.
Biochemistry and molecular biology.
1.4. The approach in this volume 10
Disciplinary ränge, level, and presentation. Levels of abstraction
and approximation. Scope and assumptions.
Objectives and nonobjectives.
1.5. Overview of following chapters 1 7
Overview of Part I. Overview of Part II. Overview of Part III.
Overview of Appendices. Open problems.
Part I Physical Principles
Chapter 2 Classical Magnitudes and Scaling Laws 23
2.1. Overview 23
2.2. Approximation and classical continuum modeis 23
2.3. Scaling of classical mechanical Systems 24
Basic assumptions. Magnitudes and scaling. Major corrections.
2.4. Scaling of classical electromagnetic Systems 28
Basic assumptions. Major corrections. Magnitudes and
scaling: steady-state Systems. Magnitudes and scaling:
time-varying Systems.
viii Contents
2.5. Scaling of classical thermal systems 32
Basic assumptions. Major corrections. Magnitudes and scaling.
2.6. Beyond classical continuum models 34
2.7. Conclusions 34
Chapter 3 Potential Energy Surfaces 36
3.1. Overview 36
3.2. Quantum theory and approximations 37
Overview of quantum mechanics. The Born-Oppenheimer PES.
Molecular orbital methods.
3.3. Molecular mechanics 42
The molecular mechanics approach. The MM2 model.
Energy, force, and stiffness under large loads.
3.4. Potentials for chemical reactions 61
Relationship to other methods. Bond cleavage
and radical coupling. Abstraction reactions.
3.5. Continuum representations of surfaces 63
Continuum models of van der Waals attraction.
Transverse-continuum models of surfaces. Molecular models
and bounded continuum models.
3.6. Conclusions 69
3.7. Further reading 69
Chapter 4 Molecular Dynamics 71
4.1. Overview 71
4.2. Nonstatistical mechanics 71
Vibrational motions. Reactions and transition rates.
Generalized trajectories.
4.3. Statistical mechanics 73
Detailed dynamics vs. statistical mechanics. Basic results
in equilibrium statistical mechanics. The configuration-space
picture. Equilibrium vs. nonequilibrium processes. Entropy
and information. Uncertainty in nanomechanical systems.
Mean-force potentials.
4.4. PES revisited: accuracy requirements 85
Physical accuracy. Chemical accuracy. Accurate energies
and nanomechanical design.
4.5. Conclusions 89
4.6. Further reading 89
Chapter 5 Positional Uncertainty 90
5.1. Overview 90
5.2. Positional uncertainty in engineering 90
Contents ix
5.3. Thermally excited harmonic oscillators 91
Classical treatment. Quantum mechanical treatment.
5.4. Elastic extension of thermally excited rods 94
Classical continuum treatment. Quantum mechanical treatments.
5.5. Elastic bending of thermally excited rods 104
Classical treatment. Semicontinuum quantum mechanical
treatment. Engineering approximations. Shear and bending
in the quantum limit.
5.6. Piston displacement in a gas-filled cylinder 111
Weighting in terms of potential energy and available states.
Weighting in terms of a mean-force potential. Weighting in terms of
the Helmholtz free energy. Comparison and quantum effects.
5.7. Longitudinal variance from transverse deformation 113
General approach. Coupling and variance. Rods with tension
and transverse constraints. Rods with freely sliding ends
and no transverse constraint.
5.8. Elasticity, entropy, and vibrational modes 118
Neglect of vibrational modes in classical elastic springs.
Conservative scaling of variance with temperature.
5.9. Conclusions 119
Chapter 6 Transitions, Errors, and Damage 120
6.1. Overview 120
6.2. Transitions between potential wells 121
Transition state theories. Classical transition state theories.
Quantum transition state theories. Tunneling.
6.3. Placement errors 130
Time-dependent PES models. Error models.
Switched-coupling error models.
6.4. Thermomechanical damage 1 34
Overview. Machine- vs. solution-phase stability.
Thermal bond cleavage. Thermomechanical bond cleavage.
Other chemical damage mechanisms. The stability of surfaces.
Thermal ionization and charge separation.
6.5. Photochemical damage 150
Energetic photons. Overview of photochemical processes.
Design for photochemical stability. Photochemical shielding.
6.6. Radiation damage 154
Radiation and radiation dosage. Classical radiation target theory.
Effects of track structure. Radiation shielding.
6.7. Component and system lifetimes 156
Component lifetimes. System lifetimes.
6.8. Conclusions 160
x Contents
Chapter 7 Energy Dissipation 161
7.1. Overview 161
7.2. Radiation from forced oscillations 162
Overview. Acoustic waves and the equal-speed approximation.
Oscillating force at a point. Oscillating torque at a point.
Oscillating pressure in a volume. Moving disturbances.
7.3. Phonons and phonon scattering 169
Phonon momentum and pressure. The Debye model
of the phonon energy density. Phonon scattering drag.
Scattering from harmonic oscillators. Scattering
from alignment bands in bearings. Shear-reflection drag.
Interracial phonon-phonon scattering.
7.4. Thermoelastic damping and phonon viscosity 179
Thermoelastic damping. Phonon viscosity.
Application to moving parts and alignment bands.
7.5. Compression of potential wells 181
Square well compression. Harmonic well compression.
Multidimensional systems.
7.6. Transitions among time-dependent wells 186
Overview. Energy dissipation ir merging wells. Free expansion and
symmetrical well merging. Asymmetrical well merging. Optimal
well merging under uncertainty.
7.7. Conclusions 189
Chapter 8 Mechanosynthesis 191
8.1. Overview 191
Mechanochemistry: terms and concepts. Scope and approach.
8.2. Perspectives on solution-phase organic synthesis 193
The scale and scope of chemistry. The prominence of qualitative
results in organic synthesis. A survey of synthetic achievements.
8.3. Solution-phase synthesis and mechanosynthesis 196
Analytical approach. Basic constraints
imposed by mechanosynthesis. Basic capabilities provided
by mechanosynthesis. Preview: molecular manufacturing
and reliability constraints. Summary of the comparison.
8.4. Reactive species 212
Overview. Ionic species. Unsaturated hydrocarbons.
Carbon radicals. Carbenes. Organometallic reagents.
8.5. Forcible mechanochemical processes 220
Overview. General considerations. Tensile bond cleavage.
Abstraction. Alkene and alkyne radical additions.
Pi-bond torsion. Radical displacements. Carbene additions and
insertions. Alkene and alkyne cycloadditions.
Transition-metal reactions.
Contents xi
8.6. Mechanosynthesis of diamondoid structures 238
Why examine the synthesis of diamond? Why examine
multiple synthesis strategies? Diamond surfaces. Stepwise
synthesis processes. Strand deposition processes.
Cluster-based strategies. Toward less diamondlike diamondoids.
Mechanosynthesis of nondiamondoid structures.
8.7. Conclusions 248
Part II Components and Systems
Chapter 9 Nanoscale Structural Components 253
9.1. Overview 253
9.2. Components in context 253
9.3. Materials and models for nanoscale components 254
Classes of materials. Materials vs. molecular structures.
The bounded continuum approach.
9.4. Surface effects on component properties 258
Materials and stiffness. Assigning sizes.
Computational experiments on rod modulus.
9.5. Shape control in irregular structures 262
Control of shape and detail of specification. Estimates of the
number of diamondoid structures. Exclusion of structures
by geometrical constraints. Exclusion of structures by
molecular binding requirements. Kaehler brackets.
9.6. Components of high rotational symmetry 267
Strained-shell structures. Curved-shell structures.
Special-case structures.
9.7. Adhesive interfaces 270
Van der Waals attraction and interlocking structures.
Ionic and hydrogen bonding. Covalent interfacial bonding.
9.8. Conclusions 271
Chapter 10 Mobile Interfaces and Moving Parts 273
10.1. Overview 273
10.2. Spatial Fourier transforms of nonbonded potentials 274
Barrier heights and sums of sinusoids.
10.3. Sliding of irregular objects over regular surfaces 277
Motivation: a random-walk model of barrier heights.
A Monte Carlo analysis of barrier heights. Implications
for constraints on structure. Energy dissipation models.
Static friction. Coupled sites.
10.4. Symmetrical sleeve bearings 284
Models of symmetrical sleeve bearings. Spatial frequencies
and symmetry operations. Properties of unloaded bearings.
Properties of loaded bearings. Bearing stiffness
xjj Contents
in the transverse-continuum approximation. Mechanisms
of energy dissipation. Sleeve bearings in molecular detail.
Less symmetrical sleeve bearings.
10.5. Further applications of sliding-interface bearings 301
Nuts and screws. Rods in sleeves. Constant force springs.
10.6. Atomic-axle bearings 303
Bonded bearings. Atomic-point bearings.
10.7. Gears, rollers, belts, and cams 304
Spur gears. Helical gears. Rack-and-pinion gears and roller
bearings. Bevel gears. Worm gears. Belt-and-roller systems.
Cams. Planetary gear systems.
10.8. Barriers in extended systems 312
Sliding of irregular objects over irregular surfaces.
10.9. Dampers, detents, clutches, and ratchets 314
Dampers. Detents. Clutches. Ratchets and reversibility.
10.10. Perspective: nanomachines and macromachines 315
Similarities between nanomachines and macromachines.
Differences between nanomachines and macromachines.
10.11. Bounded continuum models revisited 318
10.12. Conclusions 318
Chapter 11 Intermediate Subsystems 320
11.1. Overview 320
11.2. Mechanical measurement devices 320
Well partitioning and indicator latching. Force discrimination.
Shape and position discrimination. Reliability through
iterated measurements.
11.3. Stiff, high gear-ratio mechanisms 323
Harmonic drives. Toroidal worm drives.
11.4. Fluids, seals, and pumps 326
Fluid micromechanics. Walls and seals.
Pumps and vacuum systems.
11.5. Convective cooling systems 330
Murray s Law and fractal plumbing. Coolant design.
Cooling capacity in a macroscopic volume.
11.6. Electromechanical devices 333
Conducting paths. Insulating layers and tunneling contacts.
Modulated tunneling junctions. Electrostatic actuators.
Electrostatic motors.
11.7. DC motors and generators 336
Charge carriers and charge density. Electrode charging
mechanism. Motor power and power density.
Energy dissipation and efficiency. Motor start-up.
Speed regulation.
11.8. Conclusions 341
Contents xiii
Chapter 12 Nanomechanical Computational Systems
12.1. Overview 342
12.2. Digital signal transmission with mechanical rods 342
Electronic analogies. Signal propagation speed.
12.3. Gates and logic rods 343
Electronic analogies. Components and general kinematics.
A bounded continuum model. Dynamics and energy dissipation
in mobile rods. Dynamics and energy dissipation in blocked rods.
Fluctuations in stored energy. Thermal excitation and error rates.
Summary observations based on the exemplar calculations.
12.4. Registers 355
Kinematics of an efficient class of register. Device size and
packing. Energy dissipation estimates.
Fluctuations in stored energy.
12.5. Combinational logic and finite-state machines 359
Finite-state machine structure and kinematics. Finite-state machine
timing and alternatives. Fan-in, fan-out, and geometric issues.
Signal propagation with acoustic transmission lines.
12.6. Survey of other devices and subsystems 363
Gates for non-PLA combinational logic. Carry chains.
Random-access memory. Mass storage systems.
Interfaces to macroscale systems.
12.7. CPU-scale systems: clocking and power supply 367
Clocking based on oscillating drive rods. A CPU-scale drive system
architecture. Energy flows and clock skew.
Power requirements. Power supply and energy buffering.
12.8. Cooling and computational capacity 370
12.9. Conclusion 371
Chapter 13 Molecular Sorting, Processing, and Assembly 372
13.1. Overview 372
13.2. Sorting and ordering molecules 373
Modulated receptors for selective transport.
Cascades of modulated receptors. Ordered input streams.
13.3. Transformation and assembly with molecular mills 386
Reactive encounters using belt and roller systems.
Interfacing mechanisms. Reagent preparation.
Reagent application. Size and mass estimates.
Error rates and fail-stop systems. Estimates of energy dissipation.
Mechanochemical power generation.
13.4. Assembly operations using molecular manipulators 398
A bounded-continuum design for a stiff manipulator.
Self-aligning tips and compliant manipulators.
Error rates and sensitivities. Larger manipulator mechanisms.
13.5. Conclusions 409
xjv Contents
Chapter 14 Molecular Manufacturing Systems 411
14.1. Overview 411
14.2. Assembly operations at intermediate scales 411
joining building blocks. Reliability issues.
14.3. Architectural issues 415
Combining parts to make large systems.
Delivering products to an external environment.
Redundancy, reliability, and system lifetimes.
14.4. An exemplar manufacturing-system architecture 421
General approach. Products, building blocks,
and assembly sequences. Throughput, delays, and internal
inventories. Mass and volume. System lifetime.
Feedstock materials. Byproducts. Energy output
and dissipation. Information requirements.
Manufacture of manufacturing systems.
14.5. Comparison to conventional manufacturing 428
Feedstocks and energy requirements. Byproducts and recycling.
Internal component sizes and frequencies. Productivity.
Some feasible product characteristics. Manufacturing costs.
14.6. Design and complexity 434
Part counts and automation in design and computation.
Design of components and small systems. Automated generation
of synthesis and assembly procedures. Shape description languages
and part arrays. Compilers. Relative complexities.
14.7. Conclusions 441
Part III Implementation Strategies
Chapter 15 Macromolecular Engineering 445
15.1. Overview 445
15.2. Macromolecular objects via biotechnology 445
Motivation. DNA, RNA, and protein. Protein folding: prediction vs.
design. Rational design and evolutionary approaches.
Material and device properties.
15.3. Macromolecular objects via solution synthesis 449
Motivation. Basic design principles. Alternatives to standard
proteins. Strategies for stabilizing specific folds.
Consequences for design. Trade-offs and applications.
15.4. Macromolecular objects via mechanosynthesis 458
Motivation. Tip-array geometry and forces.
Molecular tips and supports in AFM. Attachment
of supporting molecules. Imaging with molecular tips.
Solution-phase mechanosynthesis. Summary.
15.5. Conclusions 467
Contents xv
Chapter 16 Paths to Molecular Manufacturing 469
16.1. Overview 469
16.2. Backward chaining to identify strategies 469
Forward vs. backward chaining. Evaluating paths
to molecular manufacturing. Overview of the backward chain.
16.3. Smaller, simpler systems (stages 3-4) 471
Macroscopic via microscopic manufacturing systems.
Acoustic power and control. Simpler manipulators.
Inert internal environment. Sorting and ordering molecules.
Minimal diamondoid-material systems.
16.4. Softer, smaller, solution-phase systems (stages 2-3) 481
Diamondoid via nondiamondoid systems. Inert environments from
solvent-based systems. Solution-synthesized pressure-threshold
actuators. Smaller liquid-based mechanisms.
16.5. Development time: some considerations 485
Determinants of the development time.
Stage la: Brownian assembly of medium-scale blocks.
Stage 1 b: Mechanosynthetic assembly of small building blocks.
Stage 2: First-generation solution-based systems.
Stage 3: Inert environments, diamondoid materials.
16.6. Conclusions 488
Appendix A Methodological Issues in Theoretical
Applied Science 489
A.1. The role of theoretical applied science 489
A.2. Basic issues 491
Establishing upper vs. lower bounds. Are there objective,
physical limits to device performance? Certainties, probabilities, and
possibilities.
A.3. Science, engineering, and theoretical applied science 493
Science and engineering. Engineering vs.
theoretical applied science.
A.4. Issues in theoretical applied science 494
Product manufacturability. Product performance.
Direct experimentation. Accurate modeling. Physical
specification. Confidence despite reduced detail.
Unique answers (and confidence from uncertainty ).
Reliable reasoning.
A.5. A sketch of some epistemological issues 503
Philosophy of science (i.e., of physics). Philosophy of engineering.
Philosophy of theoretical applied science.
A.6. Theoretical applied science as intellectual scaffolding 505
Scaffolding for molecular manufacturing.
A.7. Conclusions 506
xvi Contents
Appendix B Related Research 507
B.I. Overview 507
B.2. How related fields have been divided 507
Scientific goals vs. technological goals. Top-down vs.
bottom-up approaches. Immediate goals vs. long-term prospects.
B.3. Mechanical engineering and microtechnology 508
B.4. Chemistry 508
B.5. Molecular biology 510
B.6. Protein engineering 510
B.7. Proximal probe technologies 511
B.8. Feynman s 1959 talk 511
B.9. Conclusions 512
Afterword 513
Symbols, Units, and Constants 514
Glossary 519
References 535
Index 547
|
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| discipline | Informatik Elektrotechnik / Elektronik / Nachrichtentechnik Maschinenbau |
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| id | DE-604.BV008184217 |
| illustrated | Illustrated |
| indexdate | 2024-07-09T17:15:58Z |
| institution | BVB |
| isbn | 0471575186 9780471575184 047157547X |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-005401331 |
| oclc_num | 26503231 |
| open_access_boolean | |
| owner | DE-91 DE-BY-TUM DE-91G DE-BY-TUM DE-19 DE-BY-UBM DE-898 DE-BY-UBR DE-526 DE-634 DE-83 DE-473 DE-BY-UBG DE-188 DE-210 DE-1043 |
| owner_facet | DE-91 DE-BY-TUM DE-91G DE-BY-TUM DE-19 DE-BY-UBM DE-898 DE-BY-UBR DE-526 DE-634 DE-83 DE-473 DE-BY-UBG DE-188 DE-210 DE-1043 |
| physical | XX, 556 S. Ill., graph. Darst. 26 cm |
| publishDate | 1992 |
| publishDateSearch | 1992 |
| publishDateSort | 1992 |
| publisher | Wiley |
| record_format | marc |
| series2 | A Wiley interscience publication |
| spelling | Drexler, K. Eric 1955- Verfasser (DE-588)114321043 aut Nanosystems molecular machinery, manufacturing, and computation K. Eric Drexler New York, NY [u.a.] Wiley 1992 XX, 556 S. Ill., graph. Darst. 26 cm txt rdacontent n rdamedia nc rdacarrier A Wiley interscience publication Literaturverz. S. 535 - 546 "Written by a leading researcher in the field and one of its founders, Nanosystems is the first technical introduction to molecular nanotechnology - an emerging field that has sparked increasing interest and controversy. This groundbreaking book describes fundamental physical principles, components and devices, then examines applications including computers of unprecedented power and manufacturing systems able to build such products molecule by molecule." "Nanosystems presents a comprehensive overview of how molecular manufacturing will make products by using nanoscale (billionths of a meter) mechanical and robotic technologies to guide the placement of molecules and atoms. Working with these fundamental building blocks of matter will enable designers to approach the limits of the possible: to build the smallest devices, the fastest computers, the strongest materials, and the highest quality products. By manipulating common molecules at high frequency, molecular manufacturing will make these products quickly, inexpensively, and on a large scale. Molecular manufacturing is the key to implementing molecular nanotechnologies, building systems to complex atomic specifications." "This landmark work first presents the basic principles of physics and chemistry required to understand molecular machines. Then, Dr. Drexler describes computational models of molecules as mechanical systems, the effects of statistical mechanics, quantum uncertainty, damage mechanisms, and energy dissipation, and the fundamentals of mechanosynthesis - the use of mechanical devices to guide molecular reactions." "Nanosystems then applies the analytical tools and concepts developed in the first section to the design of nanomechanical components, devices, and systems. It describes nanomechanical gears, bearings, motors, sensors, logic gates, submicron 1000 MIPS computers (consuming 10[superscript -8] times as much power as comparable computers today), and systems able to join simple molecules to build complex products. The last section discusses how chemical, biochemical, and proximal probe technologies can be used to build complex molecular objects and how this capability can be used to implement molecular manufacturing." "Bringing together physics, chemistry, mechanical engineering, and computer science, Nanosystems provides an indispensable introduction to the emerging field of molecular nanotechnology."--BOOK JACKET Ciencias da engenharia larpcal Moleculaire nanotechnologie gtt Nanotechnology Nanotechnologie (DE-588)4327470-5 gnd rswk-swf Nanotechnologie (DE-588)4327470-5 s DE-604 HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=005401331&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Drexler, K. Eric 1955- Nanosystems molecular machinery, manufacturing, and computation Ciencias da engenharia larpcal Moleculaire nanotechnologie gtt Nanotechnology Nanotechnologie (DE-588)4327470-5 gnd |
| subject_GND | (DE-588)4327470-5 |
| title | Nanosystems molecular machinery, manufacturing, and computation |
| title_auth | Nanosystems molecular machinery, manufacturing, and computation |
| title_exact_search | Nanosystems molecular machinery, manufacturing, and computation |
| title_full | Nanosystems molecular machinery, manufacturing, and computation K. Eric Drexler |
| title_fullStr | Nanosystems molecular machinery, manufacturing, and computation K. Eric Drexler |
| title_full_unstemmed | Nanosystems molecular machinery, manufacturing, and computation K. Eric Drexler |
| title_short | Nanosystems |
| title_sort | nanosystems molecular machinery manufacturing and computation |
| title_sub | molecular machinery, manufacturing, and computation |
| topic | Ciencias da engenharia larpcal Moleculaire nanotechnologie gtt Nanotechnology Nanotechnologie (DE-588)4327470-5 gnd |
| topic_facet | Ciencias da engenharia Moleculaire nanotechnologie Nanotechnology Nanotechnologie |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=005401331&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| work_keys_str_mv | AT drexlerkeric nanosystemsmolecularmachinerymanufacturingandcomputation |