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Nanolithography: The Art of Fabricating Nanoelectronic and Nanophotonic Devices and Systems: Woodhead Publishing Series in Electronic and Optical Materials

Editat de M. Feldman
en Limba Engleză Hardback – 13 noi 2013
Integrated circuits, and devices fabricated using the techniques developed for integrated circuits, have steadily gotten smaller, more complex, and more powerful. The rate of shrinking is astonishing – some components are now just a few dozen atoms wide. This book attempts to answer the questions, “What comes next?” and “How do we get there?”

Nanolithography outlines the present state of the art in lithographic techniques, including optical projection in both deep and extreme ultraviolet, electron and ion beams, and imprinting. Special attention is paid to related issues, such as the resists used in lithography, the masks (or lack thereof), the metrology needed for nano-features, modeling, and the limitations caused by feature edge roughness. In addition emerging technologies are described, including the directed assembly of wafer features, nanostructures and devices, nano-photonics, and nano-fluidics.

This book is intended as a guide to the researcher new to this field, reading related journals or facing the complexities of a technical conference. Its goal is to give enough background information to enable such a researcher to understand, and appreciate, new developments in nanolithography, and to go on to make advances of his/her own.

  • Outlines the current state of the art in alternative nanolithography technologies in order to cope with the future reduction in size of semiconductor chips to nanoscale dimensions
  • Covers lithographic techniques, including optical projection, extreme ultraviolet (EUV), nanoimprint, electron beam and ion beam lithography
  • Describes the emerging applications of nanolithography in nanoelectronics, nanophotonics and microfluidics
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Specificații

ISBN-13: 9780857095008
ISBN-10: 0857095005
Pagini: 592
Dimensiuni: 155 x 233 x 38 mm
Greutate: 1 kg
Editura: ELSEVIER SCIENCE
Seria Woodhead Publishing Series in Electronic and Optical Materials


Cuprins

  • Contributor contact details
  • Woodhead Publishing Series in Electronic and Optical Materials
  • Preface
  • 1: Optical projection lithography
    • Abstract
    • 1.1 Introduction
    • 1.2 Lithography technology and trends
    • 1.3 Fundamentals of optical lithography
    • 1.4 Image evaluation
    • 1.5 Projection lithography systems
    • 1.6 Wavelengths for optical lithography
    • 1.7 Lithography in the deep ultraviolet (UV)
    • 1.8 Resolution enhancement technology
    • 1.9 Immersion lithography
    • 1.10 Multiple patterning optical lithography
    • 1.11 Conclusion
  • 2: Extreme ultraviolet (EUV) lithography
    • Abstract
    • 2.1 Introduction
    • 2.2 EUV sources
    • 2.3 EUV optics
    • 2.4 EUV masks
    • 2.5 EUV resists
    • 2.6 EUV integration and implementation challenges
    • 2.7 Conclusion and future trends
    • 2.8 Acknowledgments
  • 3: Electron beam lithography
    • Abstract
    • 3.1 Introduction
    • 3.2 Using pixel parallelism to address the throughput bottleneck
    • 3.3 The tradeoff between resolution and throughput
    • 3.4 Distributed systems
    • 3.5 Ultimate lithographic resolution
    • 3.6 Electron-beam patterning of photomasks for optical lithography
    • 3.7 Conclusion
    • 3.8 Acknowledgements
  • 4: Focused ion beams for nano-machining and imaging
    • Abstract
    • 4.1 Introduction
    • 4.2 An adumbrated history of focused ion beams (FIBs)
    • 4.3 Sources of ions: a quartet of types
    • 4.4 Charged particle optics
    • 4.5 Ion-matter interactions
    • 4.6 Milling
    • 4.7 Deposition
    • 4.8 Imaging
    • 4.9 Spectroscopy
    • 4.10 Conclusion and future trends
  • 5: Masks for micro- and nanolithography
    • Abstract
    • 5.1 Introduction
    • 5.2 Mask materials
    • 5.3 Mask process
    • 5.4 Mask metrology
    • 5.5 Defects and masks
    • 5.6 Conclusion
  • 6: Maskless photolithography
    • Abstract
    • 6.1 Introduction
    • 6.2 The use of photons as opposed to charged particles
    • 6.3 Forms of maskless photolithography
    • 6.4 Zone-plate-array lithography (ZPAL)
    • 6.5 Proximity-effect correction
    • 6.6 Extending the resolution of ZPAL
    • 6.7 Commercialization of ZPAL by LumArray, Inc.
    • 6.8 Conclusion
  • 7: Chemistry and processing of resists for nanolithography
    • Abstract
    • 7.1 Introduction
    • 7.2 Resists for optical lithography: synthesis and radiation induced chemistry of resists as a function of exposure technology
    • 7.3 Chemically amplified resist process considerations
    • 7.4 Chemically amplified resists for 193 nm lithography
    • 7.5 Resists for extreme ultraviolet lithography (EUVL)
    • 7.6 Resists for electron beam lithography
    • 7.7 Resists for selected forward looking lithographic technologies
    • 7.8 Resist resolution limitations
    • 7.9 Conclusion
  • 8: Directed assembly nanolithography
    • Abstract
    • 8.1 Introduction
    • 8.2 Block copolymers in lithography
    • 8.3 Directed self-assembly of block copolymers
    • 8.4 Programmable three-dimensional lithography
    • 8.5 Conclusion
  • 9: Nanoimprint lithography
    • Abstract
    • 9.1 Introduction
    • 9.2 An overview of imprint lithography
    • 9.3 Soft lithography
    • 9.4 Thermal imprint lithography
    • 9.5 Alternative thermal imprint processes
    • 9.6 Ultraviolet (UV) nanoimprint lithography overview
    • 9.7 Jet and flash imprint lithography
    • 9.8 Roll to roll imprint lithography
    • 9.9 Defectivity
    • 9.10 Conclusions
    • 9.11 Acknowledgments
  • 10: Nanostructures: fabrication and applications
    • Abstract
    • 10.1 Introduction
    • 10.2 Characterization of nanostructures
    • 10.3 Methods to create nanostructures: top-down fabrication of nanostructures
    • 10.4 Methods to create nanostructures: bottom-up fabrication of nanostructures
    • 10.5 Properties of nanostructures
    • 10.6 Applications of nanostructures
  • 11: Nanophotonics: devices for manipulating light at the nanoscale
    • Abstract
    • 11.1 Introduction
    • 11.2 Photonic crystals
    • 11.3 Ring resonators
    • 11.4 Extraordinary optical transmission through subwavelength apertures
    • 11.5 Optical nanoantennas
    • 11.6 Plasmonic focusing
    • 11.7 Near-field optical microscopy
    • 11.8 Plasmonic waveguides
    • 11.9 Enhancement of nonlinear processes
    • 11.10 Application in photovoltaics
    • 11.11 Conclusion
  • 12: Nanodevices: fabrication, prospects for low dimensional devices and applications
    • Abstract
    • 12.1 Introduction
    • 12.2 Motivation for nanodevices
    • 12.3 Nanofabrication: creating the building blocks for devices
    • 12.4 Prospects for low dimensional devices
    • 12.5 Beyond the bottom-up: hybrid nanoelectronics
    • 12.6 Conclusion and future trends
  • 13: Microfluidics: technologies and applications
    • Abstract
    • 13.1 Introduction
    • 13.2 Current trends in microfluidics
    • 13.3 Present state of technology
    • 13.4 Applications
    • 13.5 Future trends
    • 13.6 Conclusion
    • 13.7 Sources of further information and advice
  • 14: Modeling of nanolithography processes
    • Abstract
    • 14.1 Introduction
    • 14.2 Optical lithography modeling
    • 14.3 The optical system in optical lithography modeling
    • 14.4 Photoresist model
    • 14.5 Model critical dimension (CD) extraction
    • 14.6 Difficulties in modeling
    • 14.7 Extreme ultraviolet (EUV)/electron beam lithography modeling
    • 14.8 Conclusion
  • 15: Mask-substrate alignment via interferometric moiré fringes
    • Abstract
    • 15.1 Introduction
    • 15.2 Background to alignment methods
    • 15.3 Fundamentals of interferometric-spatial-phase imaging (ISPI)
    • 15.4 Implementation of moiré
    • 15.5 Characteristics of moiré fringe formation
    • 15.6 Performance of ISPI
    • 15.7 Backside ISPI
    • 15.8 Conclusion and future trends
  • 16: Sidewall roughness in nanolithography: origins, metrology and device effects
    • Abstract
    • 16.1 Introduction
    • 16.2 Metrology and characterization
    • 16.3 Process and material effects: modeling and simulation
    • 16.4 Process and material effects: experimental results
    • 16.5 Impact on device performance
    • 16.6 Conclusions
  • 17: New applications and emerging technologies in nanolithography
    • Abstract
    • 17.1 Introduction
    • 17.2 Applications of high-resolution patterning to new device structures: advances in tunneling structures
    • 17.3 Geometry control of the tunnel junctions
    • 17.4 The quantum dot placement problem
    • 17.5 Conclusion
    • 17.6 Acknowledgments
  • Index