Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 7 Coulomb Blockade and the Single-electron Transistor Lecture given by Qiliang Li.

Published byAsher Curtis Stokes Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter 7 Coulomb Blockade and the Single-electron Transistor Lecture given by Qiliang Li."— Presentation transcript:

1 Chapter 7 Coulomb Blockade and the Single-electron Transistor Lecture given by Qiliang Li

2 7.2 Single-Electron Transistor Adding gate control on a Coulomb-Blockade structure – single-electron tunneling transistor or simply single-electron transistor (SET) Vg > 0 will depress the Fermi level, Ef Vg < 0 will raise Ef Above, below and lie up with Ef of right/left side

3

4 The net charge on the island:

5 Solved:

6 An electron tunnel into the island from b, the change of stored energy is

7 Similarly for an electron from island to Junction a:

8 Assume initially island is charge neutral (n=0), an electron tunnels into the island through junction b

9 Now the island is has one electron (n=1), the electron tunnels off from the island into junction a:

10 To observe a current from junction b to a, both condition need to be met: Current > 0

11 Coulomb diamonds Charge stability diagram Shaded regions: no tunneling is allowed

12

13 SET has potential for high-speed, high-density and low-power dissipation.

14 7.3 Other SET and FET structures Carbon nanotube FET

15 InP nanowire FET for single electron tunneling

16

17

18 Benzene Molecule as a resonant tunneling transistor

19 Molecular SET

Download ppt "Chapter 7 Coulomb Blockade and the Single-electron Transistor Lecture given by Qiliang Li."

Similar presentations

6.1 Transistor Operation 6.2 The Junction FET

6.1 Transistor Operation 6.2 The Junction FET
The one that is lower in energy is called the bonding orbital, The one higher in energy is called an antibonding orbital. These two.

The one that is lower in energy is called the bonding orbital, The one higher in energy is called an antibonding orbital. These two.
Chapter 6 Electrostatic Boundary-Value Problems

Chapter 6 Electrostatic Boundary-Value Problems
QUANTUM TRANSPORT IN THE TUNNELING AND COTUNNELING REGIMENS Javier F. Nossa M.

QUANTUM TRANSPORT IN THE TUNNELING AND COTUNNELING REGIMENS Javier F. Nossa M.
Roadmap of Microelectronic Industry. Scaling of MOSFET Reduction of channel length L  L/α Integration density  α 2 Speed  α; Power/device  1/α 2 Power.

Roadmap of Microelectronic Industry. Scaling of MOSFET Reduction of channel length L  L/α Integration density  α 2 Speed  α; Power/device  1/α 2 Power.
ECE 4339: Physical Principles of Solid State Devices

ECE 4339: Physical Principles of Solid State Devices
Coulomb blockade and single-electron transistors

Coulomb blockade and single-electron transistors
Modeling Read-Out for Solid-State Quantum Computers in Silicon Vincent Conrad Supervisors: C.Pakes & L. Hollenberg.

Modeling Read-Out for Solid-State Quantum Computers in Silicon Vincent Conrad Supervisors: C.Pakes & L. Hollenberg.
Single Electron Transistor

Single Electron Transistor
Origin of Coulomb Blockade Oscillations in Single-Electron Transistors

Origin of Coulomb Blockade Oscillations in Single-Electron Transistors
Single-electron Devices Speaker: Qiaoyan Yu ECE423 12-16-2006.

Single-electron Devices Speaker: Qiaoyan Yu ECE
Lecture 4 - Coulomb blockade & SET Fulton TA and Dolan GJ, Phys. Rev. Lett. 59 (1987) 109.

Lecture 4 - Coulomb blockade & SET Fulton TA and Dolan GJ, Phys. Rev. Lett. 59 (1987) 109.
PY4007 – Quantum wires nanoparticle V1V1 V2V2 0 V C,R 1 C,R 2 C,R 3 A small conductive nanoparticle is connected via 3 tunnelling junctions to voltage.

PY4007 – Quantum wires nanoparticle V1V1 V2V2 0 V C,R 1 C,R 2 C,R 3 A small conductive nanoparticle is connected via 3 tunnelling junctions to voltage.
Warren J. Hehre. The electrostatic potential is the energy of interaction of a point positive charge (an electrophile) with the nuclei and.

Warren J. Hehre. The electrostatic potential is the energy of interaction of a point positive charge (an electrophile) with the nuclei and.
Emerging Nanotechnology Devices

Emerging Nanotechnology Devices
Ballistic and quantum transports in carbon nanotubes.

Ballistic and quantum transports in carbon nanotubes.
REVIEW OF ELECTRICITY IT’S LIKE A LESSON THAT ASSUMES YOU ALREADY LEARNED THIS STUFF!

REVIEW OF ELECTRICITY IT’S LIKE A LESSON THAT ASSUMES YOU ALREADY LEARNED THIS STUFF!
Base Pairing in DNA. Red = O Grey = C White = H Purple = K Ionic Radii Li + = 0.68 Å Na + = 0.97 Å K + = 1.33 Å Rb + = 1.47 Å Cavity Size (O-O Dist.)

Base Pairing in DNA. Red = O Grey = C White = H Purple = K Ionic Radii Li + = 0.68 Å Na + = 0.97 Å K + = 1.33 Å Rb + = 1.47 Å Cavity Size (O-O Dist.)
Molecular Geometries and Bonding © 2009, Prentice-Hall, Inc. Molecular Shapes The shape of a molecule plays an important role in its reactivity. By noting.

Molecular Geometries and Bonding © 2009, Prentice-Hall, Inc. Molecular Shapes The shape of a molecule plays an important role in its reactivity. By noting.
© 2012 Pearson Education, Inc. Chapter 9 Molecular Geometries and Bonding Theories John D. Bookstaver St. Charles Community College Cottleville, MO Lecture.

© 2012 Pearson Education, Inc. Chapter 9 Molecular Geometries and Bonding Theories John D. Bookstaver St. Charles Community College Cottleville, MO Lecture.

Similar presentations

Ads by Google