Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lecture VII Tunneling. Tunneling An electron of such an energy will never appear here! classically E kin = 1 eV 0 V-2 Vx.

Published byArline Spencer Modified over 8 years ago

Similar presentations

Presentation on theme: "Lecture VII Tunneling. Tunneling An electron of such an energy will never appear here! classically E kin = 1 eV 0 V-2 Vx."— Presentation transcript:

1 Lecture VII Tunneling

2 Tunneling An electron of such an energy will never appear here! classically E kin = 1 eV 0 V-2 Vx

3 Potential barriers and tunneling According to Newtonian mechanics, if the total energy is E, a particle that is on the left side of the barrier can go no farther than x=0. If the total energy is greater than U 0, the particle can pass the barrier.

4 Tunneling – quantum approach Schroedinger eq. for region x>L Solution:

5 Potential barriers and tunneling Two solutions: or Normalization condition: Solution: The probability to find a particle in the region II within

6 Potential barriers and tunneling

7 example Let electrons of kinetic energy E=2 eV hit the barrier height of energy U 0 = 5 eV and the width of L=1.0 nm. Find the percent of electrons passing through the barrier? T=7.1·10 -8 insulator semiconductor metal A If L=0.5 nm.then T=5.2 ·10 -4 !

8 Scanning tunneling electron miscroscope

9

10

11

12 Image downloaded from IBM, Almaden, Calif. It shows 48 Fe atoms arranged on a Cu (111) surface Scanning tunneling electron miscroscope

13  particle decay Approximate potential - energy function for an  particle in a nucleus.

14 Tunneling Nuclear fusion ( synteza ) is another example of tunneling effect E.g. The proton – proton cycle

Download ppt "Lecture VII Tunneling. Tunneling An electron of such an energy will never appear here! classically E kin = 1 eV 0 V-2 Vx."

Similar presentations

Physical Chemistry 2nd Edition

Physical Chemistry 2nd Edition
Monday, Nov. 11, 2013PHYS 3313-001, Fall 2013 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #17 Monday, Nov. 11, 2013 Dr. Jaehoon Yu Alpha Particle.

Monday, Nov. 11, 2013PHYS , Fall 2013 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #17 Monday, Nov. 11, 2013 Dr. Jaehoon Yu Alpha Particle.
A 14-kg mass, attached to a massless spring whose force constant is 3,100 N/m, has an amplitude of 5 cm. Assuming the energy is quantized, find the quantum.

A 14-kg mass, attached to a massless spring whose force constant is 3,100 N/m, has an amplitude of 5 cm. Assuming the energy is quantized, find the quantum.
1 Chapter 40 Quantum Mechanics April 6,8 Wave functions and Schrödinger equation 40.1 Wave functions and the one-dimensional Schrödinger equation Quantum.

1 Chapter 40 Quantum Mechanics April 6,8 Wave functions and Schrödinger equation 40.1 Wave functions and the one-dimensional Schrödinger equation Quantum.
Tunneling e.g consider an electron of energy 5.1 eV approaching an energy barrier of height 6.8 eV and thickness L= 750 pm What is T? L Classically.

Tunneling e.g consider an electron of energy 5.1 eV approaching an energy barrier of height 6.8 eV and thickness L= 750 pm What is T? L Classically.
Exam 2 Mean was 67 with an added curve of 5 points (total=72) to match the mean of exam 1. Max after the curve = 99 Std Dev = 15 Grades and solutions are.

Exam 2 Mean was 67 with an added curve of 5 points (total=72) to match the mean of exam 1. Max after the curve = 99 Std Dev = 15 Grades and solutions are.
1 atom many atoms ++++++++++ Potential energy of electrons in a metal Potential energy  = work function  “Finite square well.”

1 atom many atoms Potential energy of electrons in a metal Potential energy  = work function  “Finite square well.”
Tunneling. Energy Barrier  Kinetic energy is used to overcome potential energy. More for motion past barrier Less creates turning point  Objects with.

Tunneling. Energy Barrier  Kinetic energy is used to overcome potential energy. More for motion past barrier Less creates turning point  Objects with.
PH 103 Dr. Cecilia Vogel Lecture 19. Review Outline  Uncertainty Principle  Tunneling  Atomic model  Nucleus and electrons  The quantum model  quantum.

PH 103 Dr. Cecilia Vogel Lecture 19. Review Outline  Uncertainty Principle  Tunneling  Atomic model  Nucleus and electrons  The quantum model  quantum.
Physics 452 Quantum mechanics II Winter 2012 Karine Chesnel.

Physics 452 Quantum mechanics II Winter 2012 Karine Chesnel.
LECTURE 19 BARRIER PENETRATION TUNNELING PHENOMENA PHYSICS 420 SPRING 2006 Dennis Papadopoulos.

LECTURE 19 BARRIER PENETRATION TUNNELING PHENOMENA PHYSICS 420 SPRING 2006 Dennis Papadopoulos.
PHYS Quantum Mechanics

PHYS Quantum Mechanics
Infinite Potential Well … bottom line

Infinite Potential Well … bottom line
Chapter 40 Quantum Mechanics.

Chapter 40 Quantum Mechanics.
LECTURE 16 THE SCHRÖDINGER EQUATION. GUESSING THE SE.

LECTURE 16 THE SCHRÖDINGER EQUATION. GUESSING THE SE.
Lecture 10 Energy production. Summary We have now established three important equations: Hydrostatic equilibrium: Mass conservation: Equation of state:

Lecture 10 Energy production. Summary We have now established three important equations: Hydrostatic equilibrium: Mass conservation: Equation of state:
Project topics due today. Next HW due in one week

Project topics due today. Next HW due in one week
WHAT IS A QUANTUM THEORY ? Quantum theory is the theoretical basis of modern physics that explains the nature and behavior of matter and energy on the.

WHAT IS A QUANTUM THEORY ? Quantum theory is the theoretical basis of modern physics that explains the nature and behavior of matter and energy on the.
Lecture 4. Application to the Real World Particle in a “Finite” Box (Potential Well) Tunneling through a Finite Potential Barrier References Engel, Ch.

Lecture 4. Application to the Real World Particle in a “Finite” Box (Potential Well) Tunneling through a Finite Potential Barrier References Engel, Ch.
Reflection and Transmission at a Potential Step Outline - Review: Particle in a 1-D Box - Reflection and Transmission - Potential Step - Reflection from.

Reflection and Transmission at a Potential Step Outline - Review: Particle in a 1-D Box - Reflection and Transmission - Potential Step - Reflection from.

Similar presentations

Ads by Google