The Experts below are selected from a list of 13104 Experts worldwide ranked by ideXlab platform
John G. Georgiadis - One of the best experts on this subject based on the ideXlab platform.
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High-resolution electrohydrodynamic jet printing
Nature Materials, 2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through fine microcapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in common with related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1 mu m demonstrate potential applications in printed electronics.
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ARTICLES High-resolution electrohydrodynamic jet
2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through finemicrocapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in commonwith related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1µmdemonstrate potential applications in printed electronics. Printing approaches used in the Graphic Arts, particularly those based on ink-jet techniques, are of interest for applications in high-resolution manufacturing owing to attractive features that include (1) the possibility for purely additive operation, in which functional inks are deposited only where they are needed, (2) th
Jang-ung Park - One of the best experts on this subject based on the ideXlab platform.
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High-resolution electrohydrodynamic jet printing
Nature Materials, 2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through fine microcapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in common with related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1 mu m demonstrate potential applications in printed electronics.
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ARTICLES High-resolution electrohydrodynamic jet
2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through finemicrocapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in commonwith related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1µmdemonstrate potential applications in printed electronics. Printing approaches used in the Graphic Arts, particularly those based on ink-jet techniques, are of interest for applications in high-resolution manufacturing owing to attractive features that include (1) the possibility for purely additive operation, in which functional inks are deposited only where they are needed, (2) th
Kira Barton - One of the best experts on this subject based on the ideXlab platform.
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High-resolution electrohydrodynamic jet printing
Nature Materials, 2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through fine microcapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in common with related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1 mu m demonstrate potential applications in printed electronics.
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ARTICLES High-resolution electrohydrodynamic jet
2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through finemicrocapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in commonwith related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1µmdemonstrate potential applications in printed electronics. Printing approaches used in the Graphic Arts, particularly those based on ink-jet techniques, are of interest for applications in high-resolution manufacturing owing to attractive features that include (1) the possibility for purely additive operation, in which functional inks are deposited only where they are needed, (2) th
Andrew G. Alleyne - One of the best experts on this subject based on the ideXlab platform.
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High-resolution electrohydrodynamic jet printing
Nature Materials, 2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through fine microcapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in common with related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1 mu m demonstrate potential applications in printed electronics.
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ARTICLES High-resolution electrohydrodynamic jet
2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through finemicrocapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in commonwith related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1µmdemonstrate potential applications in printed electronics. Printing approaches used in the Graphic Arts, particularly those based on ink-jet techniques, are of interest for applications in high-resolution manufacturing owing to attractive features that include (1) the possibility for purely additive operation, in which functional inks are deposited only where they are needed, (2) th
Chang-young Lee - One of the best experts on this subject based on the ideXlab platform.
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High-resolution electrohydrodynamic jet printing
Nature Materials, 2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through fine microcapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in common with related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1 mu m demonstrate potential applications in printed electronics.
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ARTICLES High-resolution electrohydrodynamic jet
2007Co-Authors: Jang-ung Park, Matt Hardy, Kurt Adair, Deep Kishore Mukhopadhyay, Kira Barton, Andrew G. Alleyne, Chang-young Lee, Michael S Strano, Seong Jun Kang, John G. GeorgiadisAbstract:Efforts to adapt and extend Graphic Arts printing techniques for demanding device applications in electronics, biotechnology and microelectromechanical systems have grown rapidly in recent years. Here, we describe the use of electrohydrodynamically induced fluid flows through finemicrocapillary nozzles for jet printing of patterns and functional devices with submicrometre resolution. Key aspects of the physics of this approach, which has some features in commonwith related but comparatively low-resolution techniques for Graphic Arts, are revealed through direct high-speed imaging of the droplet formation processes. Printing of complex patterns of inks, ranging from insulating and conducting polymers, to solution suspensions of silicon nanoparticles and rods, to single-walled carbon nanotubes, using integrated computer-controlled printer systems illustrates some of the capabilities. High-resolution printed metal interconnects, electrodes and probing pads for representative circuit patterns and functional transistors with critical dimensions as small as 1µmdemonstrate potential applications in printed electronics. Printing approaches used in the Graphic Arts, particularly those based on ink-jet techniques, are of interest for applications in high-resolution manufacturing owing to attractive features that include (1) the possibility for purely additive operation, in which functional inks are deposited only where they are needed, (2) th
