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037 |a urn:nbn:de:bsz:ch1-qucosa-74453 
041 |a eng 
082 |a 530 
100 |a Smith, Elliot John 
245 |a Self-assembled rolled-up devices: towards on-chip sensor technologies 
336 |b txt 
338 |b nc 
533 |a Online-Ausg.  |d 2011  |e Online-Ressource (Text)  |f Universitätsbibliothek Chemnitz 
502 |b Dissertation  |c Technischen Universität Chemnitz  |d 2011 
520 |a By implementing the rolled-up microfabrication method based on strain engineering, several systems are investigated within the contents of this thesis. The structural morphing of planar geometries into three-dimensional structures opens up many doors for the creation of unique material configurations and devices. An exploration into several novel microsystems, encompassing various scientific subjects, is made and methods for on-chip integration of these devices are presented. The roll-up of a metal and oxide allows for a cylindrical hollow-core structure with a cladding layer composed of a multilayer stack, plasmonic metamaterial. This structure can be used as a platform for a number of optical metamaterial devices. By guiding light radially through this structure, a theoretical investigation into the system makeup of a rolled-up hyperlens, is given. Using the same design, but rather propagating light parallel to the cylinder, a novel device known as a metamaterial optical fiber is defined. This fiber allows light to be guided classically and plasmonically within a single device. These fibers are developed experimentally and are integrated into preexisting on-chip structures and characterized. A system known as lab-in-a-tube is introduced. The idea of lab-in-a-tube combines various rolled-up components into a single all-encompassing biosensor that can be used to detect and monitor single bio-organisms. The first device specifically tailored to this system is developed, flexible split-wall microtube resonator sensors. A method for the capturing of embryonic mouse cells into on-chip optical resonators is introduced. The sensor can optically detect, via photoluminescence, living cells confined within the resonator through the compression and expansion of a nanogap built within its walls. The rolled-up fabrication method is not limited to the well-investigated systems based on the roll-up from semiconductor material or from a photoresist layer. A new approach, relying on the delamination of polymers, is presented. This offers never-before-realized microscale structures and configurations. This includes novel magnetic configurations and flexible fluidic sensors which can be designed for on-chip and roving detector applications. 
650 |a Aufrolltechnologie 
650 |a Integration Auf Dem Chip 
650 |a Lab-In-A-Tube 
650 |a Hyperlinse 
650 |a Metamaterialfaser 
650 |a Biosensor 
650 |a Optischer Ringresonator 
650 |a Mikrohelixspule 
650 |a Radialmagnetisierung 
650 |a Korkenzieher-Magnetisierung 
650 |a Hohlstub-Magnetisierung 
650 |a Polymer Ablösung 
650 |a Rolled-Up 
650 |a On-Chip Integration 
650 |a Lab-In-A-Tube 
650 |a Hyperlens 
650 |a Metamaterial Optical Fiber 
650 |a Biosensor 
650 |a Optical Ring Resonator 
650 |a Micro-Helix Coil 
650 |a Radial-Magnetization 
650 |a Corkscrew-Magnetization 
650 |a Hollow-Bar-Magnetization 
650 |a Polymer Delamination 
650 |a Nanostruktur 
650 |a Mikrostruktur 
650 |a Biophysik 
650 |a Optik 
650 |a Magnetisierung 
650 |a Optischer Resonator 
650 |a Lab On A Chip 
655 |a Hochschulschrift  |2 gnd-content 
700 |a Schmidt, Oliver G. 
700 |a Schmidt, Oliver G. 
700 |a Bratschitsch, Rudolf 
856 4 0 |q text/html  |u https://nbn-resolving.org/urn:nbn:de:bsz:ch1-qucosa-74453  |z Online-Zugriff 
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contents By implementing the rolled-up microfabrication method based on strain engineering, several systems are investigated within the contents of this thesis. The structural morphing of planar geometries into three-dimensional structures opens up many doors for the creation of unique material configurations and devices. An exploration into several novel microsystems, encompassing various scientific subjects, is made and methods for on-chip integration of these devices are presented. The roll-up of a metal and oxide allows for a cylindrical hollow-core structure with a cladding layer composed of a multilayer stack, plasmonic metamaterial. This structure can be used as a platform for a number of optical metamaterial devices. By guiding light radially through this structure, a theoretical investigation into the system makeup of a rolled-up hyperlens, is given. Using the same design, but rather propagating light parallel to the cylinder, a novel device known as a metamaterial optical fiber is defined. This fiber allows light to be guided classically and plasmonically within a single device. These fibers are developed experimentally and are integrated into preexisting on-chip structures and characterized. A system known as lab-in-a-tube is introduced. The idea of lab-in-a-tube combines various rolled-up components into a single all-encompassing biosensor that can be used to detect and monitor single bio-organisms. The first device specifically tailored to this system is developed, flexible split-wall microtube resonator sensors. A method for the capturing of embryonic mouse cells into on-chip optical resonators is introduced. The sensor can optically detect, via photoluminescence, living cells confined within the resonator through the compression and expansion of a nanogap built within its walls. The rolled-up fabrication method is not limited to the well-investigated systems based on the roll-up from semiconductor material or from a photoresist layer. A new approach, relying on the delamination of polymers, is presented. This offers never-before-realized microscale structures and configurations. This includes novel magnetic configurations and flexible fluidic sensors which can be designed for on-chip and roving detector applications.
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spelling Smith, Elliot John, Self-assembled rolled-up devices: towards on-chip sensor technologies, txt, nc, Online-Ausg. 2011 Online-Ressource (Text) Universitätsbibliothek Chemnitz, Dissertation Technischen Universität Chemnitz 2011, By implementing the rolled-up microfabrication method based on strain engineering, several systems are investigated within the contents of this thesis. The structural morphing of planar geometries into three-dimensional structures opens up many doors for the creation of unique material configurations and devices. An exploration into several novel microsystems, encompassing various scientific subjects, is made and methods for on-chip integration of these devices are presented. The roll-up of a metal and oxide allows for a cylindrical hollow-core structure with a cladding layer composed of a multilayer stack, plasmonic metamaterial. This structure can be used as a platform for a number of optical metamaterial devices. By guiding light radially through this structure, a theoretical investigation into the system makeup of a rolled-up hyperlens, is given. Using the same design, but rather propagating light parallel to the cylinder, a novel device known as a metamaterial optical fiber is defined. This fiber allows light to be guided classically and plasmonically within a single device. These fibers are developed experimentally and are integrated into preexisting on-chip structures and characterized. A system known as lab-in-a-tube is introduced. The idea of lab-in-a-tube combines various rolled-up components into a single all-encompassing biosensor that can be used to detect and monitor single bio-organisms. The first device specifically tailored to this system is developed, flexible split-wall microtube resonator sensors. A method for the capturing of embryonic mouse cells into on-chip optical resonators is introduced. The sensor can optically detect, via photoluminescence, living cells confined within the resonator through the compression and expansion of a nanogap built within its walls. The rolled-up fabrication method is not limited to the well-investigated systems based on the roll-up from semiconductor material or from a photoresist layer. A new approach, relying on the delamination of polymers, is presented. This offers never-before-realized microscale structures and configurations. This includes novel magnetic configurations and flexible fluidic sensors which can be designed for on-chip and roving detector applications., Aufrolltechnologie, Integration Auf Dem Chip, Lab-In-A-Tube, Hyperlinse, Metamaterialfaser, Biosensor, Optischer Ringresonator, Mikrohelixspule, Radialmagnetisierung, Korkenzieher-Magnetisierung, Hohlstub-Magnetisierung, Polymer Ablösung, Rolled-Up, On-Chip Integration, Hyperlens, Metamaterial Optical Fiber, Optical Ring Resonator, Micro-Helix Coil, Radial-Magnetization, Corkscrew-Magnetization, Hollow-Bar-Magnetization, Polymer Delamination, Nanostruktur, Mikrostruktur, Biophysik, Optik, Magnetisierung, Optischer Resonator, Lab On A Chip, Hochschulschrift gnd-content, Schmidt, Oliver G., Bratschitsch, Rudolf, text/html https://nbn-resolving.org/urn:nbn:de:bsz:ch1-qucosa-74453 Online-Zugriff
spellingShingle Smith, Elliot John, Self-assembled rolled-up devices: towards on-chip sensor technologies, By implementing the rolled-up microfabrication method based on strain engineering, several systems are investigated within the contents of this thesis. The structural morphing of planar geometries into three-dimensional structures opens up many doors for the creation of unique material configurations and devices. An exploration into several novel microsystems, encompassing various scientific subjects, is made and methods for on-chip integration of these devices are presented. The roll-up of a metal and oxide allows for a cylindrical hollow-core structure with a cladding layer composed of a multilayer stack, plasmonic metamaterial. This structure can be used as a platform for a number of optical metamaterial devices. By guiding light radially through this structure, a theoretical investigation into the system makeup of a rolled-up hyperlens, is given. Using the same design, but rather propagating light parallel to the cylinder, a novel device known as a metamaterial optical fiber is defined. This fiber allows light to be guided classically and plasmonically within a single device. These fibers are developed experimentally and are integrated into preexisting on-chip structures and characterized. A system known as lab-in-a-tube is introduced. The idea of lab-in-a-tube combines various rolled-up components into a single all-encompassing biosensor that can be used to detect and monitor single bio-organisms. The first device specifically tailored to this system is developed, flexible split-wall microtube resonator sensors. A method for the capturing of embryonic mouse cells into on-chip optical resonators is introduced. The sensor can optically detect, via photoluminescence, living cells confined within the resonator through the compression and expansion of a nanogap built within its walls. The rolled-up fabrication method is not limited to the well-investigated systems based on the roll-up from semiconductor material or from a photoresist layer. A new approach, relying on the delamination of polymers, is presented. This offers never-before-realized microscale structures and configurations. This includes novel magnetic configurations and flexible fluidic sensors which can be designed for on-chip and roving detector applications., Aufrolltechnologie, Integration Auf Dem Chip, Lab-In-A-Tube, Hyperlinse, Metamaterialfaser, Biosensor, Optischer Ringresonator, Mikrohelixspule, Radialmagnetisierung, Korkenzieher-Magnetisierung, Hohlstub-Magnetisierung, Polymer Ablösung, Rolled-Up, On-Chip Integration, Hyperlens, Metamaterial Optical Fiber, Optical Ring Resonator, Micro-Helix Coil, Radial-Magnetization, Corkscrew-Magnetization, Hollow-Bar-Magnetization, Polymer Delamination, Nanostruktur, Mikrostruktur, Biophysik, Optik, Magnetisierung, Optischer Resonator, Lab On A Chip, Hochschulschrift
title Self-assembled rolled-up devices: towards on-chip sensor technologies
title_auth Self-assembled rolled-up devices: towards on-chip sensor technologies
title_full Self-assembled rolled-up devices: towards on-chip sensor technologies
title_fullStr Self-assembled rolled-up devices: towards on-chip sensor technologies
title_full_unstemmed Self-assembled rolled-up devices: towards on-chip sensor technologies
title_short Self-assembled rolled-up devices: towards on-chip sensor technologies
title_sort self-assembled rolled-up devices: towards on-chip sensor technologies
title_unstemmed Self-assembled rolled-up devices: towards on-chip sensor technologies
topic Aufrolltechnologie, Integration Auf Dem Chip, Lab-In-A-Tube, Hyperlinse, Metamaterialfaser, Biosensor, Optischer Ringresonator, Mikrohelixspule, Radialmagnetisierung, Korkenzieher-Magnetisierung, Hohlstub-Magnetisierung, Polymer Ablösung, Rolled-Up, On-Chip Integration, Hyperlens, Metamaterial Optical Fiber, Optical Ring Resonator, Micro-Helix Coil, Radial-Magnetization, Corkscrew-Magnetization, Hollow-Bar-Magnetization, Polymer Delamination, Nanostruktur, Mikrostruktur, Biophysik, Optik, Magnetisierung, Optischer Resonator, Lab On A Chip, Hochschulschrift
topic_facet Aufrolltechnologie, Integration Auf Dem Chip, Lab-In-A-Tube, Hyperlinse, Metamaterialfaser, Biosensor, Optischer Ringresonator, Mikrohelixspule, Radialmagnetisierung, Korkenzieher-Magnetisierung, Hohlstub-Magnetisierung, Polymer Ablösung, Rolled-Up, On-Chip Integration, Hyperlens, Metamaterial Optical Fiber, Optical Ring Resonator, Micro-Helix Coil, Radial-Magnetization, Corkscrew-Magnetization, Hollow-Bar-Magnetization, Polymer Delamination, Nanostruktur, Mikrostruktur, Biophysik, Optik, Magnetisierung, Optischer Resonator, Lab On A Chip, Hochschulschrift
url https://nbn-resolving.org/urn:nbn:de:bsz:ch1-qucosa-74453
urn urn:nbn:de:bsz:ch1-qucosa-74453
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