Your search keyword '"Hagleitner, Christoph"' showing total 10 results

1. Nanoelectromechanical digital logic circuits using curved cantilever switches with amorphous-carbon-coated contacts

Author

Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, Hagleitner, Christoph, Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, and Hagleitner, Christoph

Abstract

Nanoelectromechanical (NEM) switches have the potential to complement or replace traditional CMOS transistors in the area of ultra-low-power digital electronics. This paper reports the demonstration of prototype circuits including the first 3-stage ring oscillator built using cell-level digital logic elements based on curved NEM switches. The ring oscillator core occupies an area of 30 mu m x 10 mu m using 6 NEM switches. Each NEM switch device has a footprint of 5 mu m x 3 mu m, an air gap of 60 mu m and is coated with amorphous carbon (a-C) for reliable operation. The ring oscillator operates at a frequency of 6.7 MHz, and confirms the simulated inverter propagation delay of 25 ns. The successful fabrication and measurement of this demonstrator are key milestones on the way towards an optimized, scaled technology with sub-nanosecond switching times, lower operating voltages and VLSI implementation., QC 20150918

Published

2015

2. Nanoelectromechanical digital logic circuits using curved cantilever switches with amorphous-carbon-coated contacts

Author

Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, Hagleitner, Christoph, Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, and Hagleitner, Christoph

Abstract

Nanoelectromechanical (NEM) switches have the potential to complement or replace traditional CMOS transistors in the area of ultra-low-power digital electronics. This paper reports the demonstration of prototype circuits including the first 3-stage ring oscillator built using cell-level digital logic elements based on curved NEM switches. The ring oscillator core occupies an area of 30 mu m x 10 mu m using 6 NEM switches. Each NEM switch device has a footprint of 5 mu m x 3 mu m, an air gap of 60 mu m and is coated with amorphous carbon (a-C) for reliable operation. The ring oscillator operates at a frequency of 6.7 MHz, and confirms the simulated inverter propagation delay of 25 ns. The successful fabrication and measurement of this demonstrator are key milestones on the way towards an optimized, scaled technology with sub-nanosecond switching times, lower operating voltages and VLSI implementation., QC 20150918

Published

2015

3. Nanoelectromechanical digital logic circuits using curved cantilever switches with amorphous-carbon-coated contacts

Author

Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, Hagleitner, Christoph, Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, and Hagleitner, Christoph

Abstract

Nanoelectromechanical (NEM) switches have the potential to complement or replace traditional CMOS transistors in the area of ultra-low-power digital electronics. This paper reports the demonstration of prototype circuits including the first 3-stage ring oscillator built using cell-level digital logic elements based on curved NEM switches. The ring oscillator core occupies an area of 30 mu m x 10 mu m using 6 NEM switches. Each NEM switch device has a footprint of 5 mu m x 3 mu m, an air gap of 60 mu m and is coated with amorphous carbon (a-C) for reliable operation. The ring oscillator operates at a frequency of 6.7 MHz, and confirms the simulated inverter propagation delay of 25 ns. The successful fabrication and measurement of this demonstrator are key milestones on the way towards an optimized, scaled technology with sub-nanosecond switching times, lower operating voltages and VLSI implementation., QC 20150918

Published

2015

4. Nanoelectromechanical digital logic circuits using curved cantilever switches with amorphous-carbon-coated contacts

Author

Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, Hagleitner, Christoph, Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, and Hagleitner, Christoph

Abstract

Nanoelectromechanical (NEM) switches have the potential to complement or replace traditional CMOS transistors in the area of ultra-low-power digital electronics. This paper reports the demonstration of prototype circuits including the first 3-stage ring oscillator built using cell-level digital logic elements based on curved NEM switches. The ring oscillator core occupies an area of 30 mu m x 10 mu m using 6 NEM switches. Each NEM switch device has a footprint of 5 mu m x 3 mu m, an air gap of 60 mu m and is coated with amorphous carbon (a-C) for reliable operation. The ring oscillator operates at a frequency of 6.7 MHz, and confirms the simulated inverter propagation delay of 25 ns. The successful fabrication and measurement of this demonstrator are key milestones on the way towards an optimized, scaled technology with sub-nanosecond switching times, lower operating voltages and VLSI implementation., QC 20150918

Published

2015

5. Nanoelectromechanical digital logic circuits using curved cantilever switches with amorphous-carbon-coated contacts

Author

Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, Hagleitner, Christoph, Ayala, Christopher L., Grogg, Daniel, Bazigos, Antonios, Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Niklaus, Frank, and Hagleitner, Christoph

Abstract

Nanoelectromechanical (NEM) switches have the potential to complement or replace traditional CMOS transistors in the area of ultra-low-power digital electronics. This paper reports the demonstration of prototype circuits including the first 3-stage ring oscillator built using cell-level digital logic elements based on curved NEM switches. The ring oscillator core occupies an area of 30 mu m x 10 mu m using 6 NEM switches. Each NEM switch device has a footprint of 5 mu m x 3 mu m, an air gap of 60 mu m and is coated with amorphous carbon (a-C) for reliable operation. The ring oscillator operates at a frequency of 6.7 MHz, and confirms the simulated inverter propagation delay of 25 ns. The successful fabrication and measurement of this demonstrator are key milestones on the way towards an optimized, scaled technology with sub-nanosecond switching times, lower operating voltages and VLSI implementation., QC 20150918

Published

2015

6. Amorphous carbon active contact layer for reliable nanoelectromechanical switches

Author

Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, Duerig, Urs T., Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, and Duerig, Urs T.

Abstract

This paper reports an amorphous carbon (a-C) contact coating for ultra-low-ower curved nanoelectromechanical (NEM) switches. a-C addresses important problems in miniaturization and low-ower operation of mechanical relays: i) the surface energy is lower than that of metals, ii) active formation of highly localized a-C conducting filaments offers a way to form nanoscale contacts, and iii) high reliability is achieved through the excellent wear properties of a-C, demonstrated in this paper with more than 100 million hot switching cycles. Finally, a full inverter using a-C contacts is fabricated to demonstrate the viability of the concept., QC 20140521

Published

2014

7. Amorphous carbon active contact layer for reliable nanoelectromechanical switches

Author

Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, Duerig, Urs T., Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, and Duerig, Urs T.

Abstract

This paper reports an amorphous carbon (a-C) contact coating for ultra-low-ower curved nanoelectromechanical (NEM) switches. a-C addresses important problems in miniaturization and low-ower operation of mechanical relays: i) the surface energy is lower than that of metals, ii) active formation of highly localized a-C conducting filaments offers a way to form nanoscale contacts, and iii) high reliability is achieved through the excellent wear properties of a-C, demonstrated in this paper with more than 100 million hot switching cycles. Finally, a full inverter using a-C contacts is fabricated to demonstrate the viability of the concept., QC 20140521

Published

2014

8. Amorphous carbon active contact layer for reliable nanoelectromechanical switches

Author

Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, Duerig, Urs T., Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, and Duerig, Urs T.

Abstract

This paper reports an amorphous carbon (a-C) contact coating for ultra-low-ower curved nanoelectromechanical (NEM) switches. a-C addresses important problems in miniaturization and low-ower operation of mechanical relays: i) the surface energy is lower than that of metals, ii) active formation of highly localized a-C conducting filaments offers a way to form nanoscale contacts, and iii) high reliability is achieved through the excellent wear properties of a-C, demonstrated in this paper with more than 100 million hot switching cycles. Finally, a full inverter using a-C contacts is fabricated to demonstrate the viability of the concept., QC 20140521

Published

2014

9. Amorphous carbon active contact layer for reliable nanoelectromechanical switches

Author

Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, Duerig, Urs T., Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, and Duerig, Urs T.

Abstract

This paper reports an amorphous carbon (a-C) contact coating for ultra-low-ower curved nanoelectromechanical (NEM) switches. a-C addresses important problems in miniaturization and low-ower operation of mechanical relays: i) the surface energy is lower than that of metals, ii) active formation of highly localized a-C conducting filaments offers a way to form nanoscale contacts, and iii) high reliability is achieved through the excellent wear properties of a-C, demonstrated in this paper with more than 100 million hot switching cycles. Finally, a full inverter using a-C contacts is fabricated to demonstrate the viability of the concept., QC 20140521

Published

2014

10. Amorphous carbon active contact layer for reliable nanoelectromechanical switches

Author

Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, Duerig, Urs T., Grogg, Daniel, Ayala, Christopher L., Drechsler, Ute, Sebastian, A., Koelmans, W. W., Bleiker, Simon J., Fernandez-Bolanos, Montserrat, Hagleitner, Christoph, Despont, Michel, and Duerig, Urs T.

Abstract

This paper reports an amorphous carbon (a-C) contact coating for ultra-low-ower curved nanoelectromechanical (NEM) switches. a-C addresses important problems in miniaturization and low-ower operation of mechanical relays: i) the surface energy is lower than that of metals, ii) active formation of highly localized a-C conducting filaments offers a way to form nanoscale contacts, and iii) high reliability is achieved through the excellent wear properties of a-C, demonstrated in this paper with more than 100 million hot switching cycles. Finally, a full inverter using a-C contacts is fabricated to demonstrate the viability of the concept., QC 20140521

Published

2014