The volumes VIII, IX and X examine the physical and technical foundation for recent progress in applied scanning probe techniques. This is the first book to summarize the state-of-the-art of this technique. The field is progressing so fast that there is a need for a set of volumes every 12 to 18 months to capture latest developments. These volumes constitute a timely comprehensive overview of SPM applications.

The volumes VIII, IX and X examine the physical and technical foundation for recent progress in applied scanning probe techniques. This is the first book to summarize the state-of-the-art of this technique. The field is progressing so fast that there is a need for a set of volumes every 12 to 18 months to capture latest developments. These volumes constitute a timely and comprehensive overview of SPM applications.

The Nobel Prize of 1986 on Sc- ningTunnelingMicroscopysignaled a new era in imaging. The sc- ning probes emerged as a new - strument for imaging with a p- cision suf?cient to delineate single atoms. At ?rst there were two - the Scanning Tunneling Microscope, or STM, and the Atomic Force Mic- scope, or AFM. The STM relies on electrons tunneling between tip and sample whereas the AFM depends on the force acting on the tip when it was placed near the sample. These were quickly followed by the M- netic Force Microscope, MFM, and the Electrostatic Force Microscope, EFM. The MFM will image a single magnetic bit with features as small as 10nm. With the EFM one can monitor the charge of a single electron. Prof. Paul Hansma at Santa Barbara opened the door even wider when he was able to image biological objects in aqueous environments. At this point the sluice gates were opened and a multitude of different instruments appeared. There are signi?cant differences between the Scanning Probe Microscopes or SPM, and others such as the Scanning Electron Microscope or SEM. The probe microscopes do not require preparation of the sample and they operate in ambient atmosphere, whereas, the SEM must operate in a vacuum environment and the sample must be cross-sectioned to expose the proper surface. However, the SEM can record 3D image and movies, features that are not available with the scanning probes.

This volume examines the physical and technical foundation for recent progress in applied near-field scanning probe techniques. It constitutes a timely comprehensive overview of SPM applications, now that industrial applications span topographic and dynamical surface studies of thin-film semiconductors, polymers, paper, ceramics, and magnetic and biological materials. After laying the theoretical background of static and dynamic force microscopies, including sensor technology and tip characterization, contributions detail applications such as macro- and nanotribology, polymer surfaces, and roughness investigations. The final part on industrial research addresses special applications of scanning force nanoprobes such as atomic manipulation and surface modification, as well as single electron devices based on SPM. Scientists and engineers either using or planning to use SPM techniques will benefit from the international perspective assembled in the book.

The first volume in the series was released in January 2004 and the second to fourth volumes in early 2006. The field is now progressing so fast that there is a need for one volume every 12 to 18 months to capture latest developments.

Volume VII presents 9 chapters on a variety of new and emerging techniques and refinements of SPM applications.

The volumes V, VI and VII will examine the physical and technical foundation for recent progress in applied scanning probe techniques. These volumes constitute a timely comprehensive overview of SPM applications. This is the first book summarizing the state-of-the-art of this technique. The chapters are written by leading researchers and application scientists from all over the world and from various industries to provide a broader perspective.

The Nobel Prize of 1986 on Sc- ningTunnelingMicroscopysignaled a new era in imaging. The sc- ning probes emerged as a new - strument for imaging with a p- cision suf?cient to delineate single atoms. At ?rstthere were two -the ScanningTunnelingMicroscope,or STM,andtheAtomicForceMic- scope, or AFM. The STM relies on electrons tunneling between tip and sample whereas the AFM depends on the force acting on the tip when itwasplacednearthesample.These were quickly followed by the M- netic Force Microscope, MFM, and the Electrostatic Force Microscope, EFM.TheMFMwillimageasinglemagneticbitwithfeaturesassmallas10nm. WiththeEFMonecanmonitorthechargeofasingleelectron.Prof.PaulHansma atSantaBarbaraopenedthedoorevenwiderwhenhewasabletoimagebiological objects in aqueous environments. At this point the sluice gates were opened and amultitudeofdifferentinstrumentsappeared. There are signi?cant differences between the Scanning Probe Microscopes or SPM, and others such as the Scanning Electron Microscope or SEM. The probe microscopes do not require preparation of the sample and they operate in ambient atmosphere, whereas, the SEM must operate in a vacuum environment and the sample must be cross-sectioned to expose the proper surface. However, the SEM canrecord3Dimage andmovies, featuresthatarenotavailable withthescanning probes. TheNearFieldOpticalMicroscopeorNSOMisalsomemberofthisfamily.At thistimetheinstrumentsuffersfromtwolimitations;1)mostoftheopticalenergy is lost as it traverses the cut-off region of the tapered ?ber and 2) the resolution is insuf?cient for many purposes. We are con?dent that NSOM's with a reasonable opticalthroughputandaresolutionof10nmwillsoonappear.TheSNOMwillthen enterthemainstreamofscanningprobes. VI Foreword In the Harmonic Force Microscope or HFM, the cantilever is driven at the resonantfrequencywiththeamplitudeadjustedsothatthetipimpactsthesampleon each cycle. Theforcesbetween tipandsample generate multiple harmonics inthe motionofthecantilever.Thestrengthoftheseharmonicscanbeusedtocharacterize thephysicalpropertiesofthesurface.

The Nobel Prize of 1986 on Sc- ning Tunneling Microscopy sig- led a new era in imaging. The sc- ning probes emerged as a new i- trument for imaging with a pre- sion suf?cient to delineate single atoms. At ?rst there were two - the Scanning Tunneling Microscope, or STM, and the Atomic Force Mic- scope, or AFM. The STM relies on electrons tunneling between tip and sample whereas the AFM depends on the force acting on the tip when it was placed near the sample. These were quickly followed by the - gneticForceMicroscope,MFM,and the Electrostatic Force Microscope, EFM. The MFM will image a single magnetic bit with features as small as 10nm. With the EFM one can monitor the charge of a single electron. Prof. Paul Hansma at Santa Barbara opened the door even wider when he was able to image biological objects in aqueous environments. At this point the sluice gates were opened and a multitude of different instruments appeared. There are signi?cant differences between the Scanning Probe Microscopes or SPM, and others such as the Scanning Electron Microscope or SEM. The probe microscopes do not require preparation of the sample and they operate in ambient atmosphere, whereas, the SEM must operate in a vacuum environment and the sample must be cross-sectioned to expose the proper surface. However, the SEM can record 3D image and movies, features that are not available with the scanning probes.

Essentials from the series "Applied Scanning Probe Methods" are put together in the area of bio and biorelated systems. The contributions spread over all 13 volumes are now combined in this one volume. Thus, the reader will easily find a comprehensive overview of SPM applications for biosystems.

For scientists and professionals in academic and industry dealing with surface analytics of plant science, living cells, nanomedicine, cosmetics and biomimetics.

The volumes VIII, IX and X examine the physical and technical foundation for recent progress in applied scanning probe techniques. This is the first book to summarize the state-of-the-art of this technique. The field is progressing so fast that there is a need for a set of volumes every 12 to 18 months to capture latest developments. These volumes constitute a timely comprehensive overview of SPM applications.

The volumes V, VI and VII will examine the physical and technical foundation for recent progress in applied scanning probe techniques. These volumes constitute a timely comprehensive overview of SPM applications. This is the first book summarizing the state-of-the-art of this technique. The chapters are written by leading researchers and application scientists from all over the world and from various industries to provide a broader perspective.

The first volume in the series was released in January 2004 and the second to fourth volumes in early 2006. The field is now progressing so fast that there is a need for one volume every 12 to 18 months to capture latest developments.

Volume VII presents 9 chapters on a variety of new and emerging techniques and refinements of SPM applications.

The volumes VIII, IX and X examine the physical and technical foundation for recent progress in applied scanning probe techniques. This is the first book to summarize the state-of-the-art of this technique. The field is progressing so fast that there is a need for a set of volumes every 12 to 18 months to capture latest developments. These volumes constitute a timely comprehensive overview of SPM applications.

With the increasing demand for optimization of energy storage, maintenance of the environment, and effective production, control on nanostructures of catalysts and optimization of their organization have become key to achieving high efficiency and specificity in energy and material conversion systems. This book emphasizes and summarizes the novel design of soft matters (molecules, polymers, assembled motifs, etc.) for nanocatalysts and nanocatalyst supports. The diversity or specialty of soft matters offers a new perspective and great promise for the development of new nanocatalytic systems for future requirements. Soft matters can provide a simple and well-defined space for the discovery of new catalysts. This book covers nonmetallic organocatalysts, organometallic compounds, dendrimers, ionic liquids, enzymes, polymers, various organized nanoarchitectures for supporting catalysts, and molecular dynamics in catalytic surface reactions. It gives readers a complete picture of the catalysis systems based on soft matters and is a useful reference for advanced undergraduate- and graduate-level students and researchers in chemistry, biology, materials science, nanoscience, polymer science, and catalysis.

The Nobel Prize of 1986 on Sc- ningTunnelingMicroscopysignaled a new era in imaging. The sc- ning probes emerged as a new - strument for imaging with a p- cision suf?cient to delineate single atoms. At ?rstthere were two -the ScanningTunnelingMicroscope, or STM, andtheAtomicForceMic- scope, or AFM. The STM relies on electrons tunneling between tip and sample whereas the AFM depends on the force acting on the tip when itwasplacednearthesample.These were quickly followed by the M- netic Force Microscope, MFM, and the Electrostatic Force Microscope, EFM.TheMFMwillimageasinglemagneticbitwithfeaturesassmallas10nm. WiththeEFMonecanmonitorthechargeofasingleelectron.Prof.PaulHansma atSantaBarbaraopenedthedoorevenwiderwhenhewasabletoimagebiological objects in aqueous environments. At this point the sluice gates were opened and amultitudeofdifferentinstrumentsappeared. There are signi?cant differences between the Scanning Probe Microscopes or SPM, and others such as the Scanning Electron Microscope or SEM. The probe microscopes do not require preparation of the sample and they operate in ambient atmosphere, whereas, the SEM must operate in a vacuum environment and the sample must be cross-sectioned to expose the proper surface. However, the SEM canrecord3Dimage andmovies, featuresthatarenotavailable withthescanning probes. TheNearFieldOpticalMicroscopeorNSOMisalsomemberofthisfamily.At thistimetheinstrumentsuffersfromtwolimitations;1)mostoftheopticalenergy is lost as it traverses the cut-off region of the tapered ?ber and 2) the resolution is insuf?cient for many purposes. We are con?dent that NSOM's with a reasonable opticalthroughputandaresolutionof10nmwillsoonappear.TheSNOMwillthen enterthemainstreamofscanningprobes. VI Foreword In the Harmonic Force Microscope or HFM, the cantilever is driven at the resonantfrequencywiththeamplitudeadjustedsothatthetipimpactsthesampleon each cycle. Theforcesbetween tipandsample generate multiple harmonics inthe motionofthecantilever.Thestrengthoftheseharmonicscanbeusedtocharacterize thephysicalpropertiesofthesurface.

Essentials from the series "Applied Scanning Probe Methods" are put together in the area of bio and biorelated systems. The contributions spread over all 13 volumes are now combined in this one volume. Thus, the reader will easily find a comprehensive overview of SPM applications for biosystems. For scientists and professionals in academic and industry dealing with surface analytics of plant science, living cells, nanomedicine, cosmetics and biomimetics.