7.6 The quantum tunneling of particles through potential barriers (Page 9/22)

Page 9 / 22

Figure a is an illustration of a tunneling diode. The quantum dot is a small region of gallium arsenide embedded in aluminum arsenide. Additional small regions of gallium arsenide are also embedded on either side of the quantum dot, separated from it by a small barrier of aluminum arsenide. The left end of the structure is attached to a negative electrode, and the right to a positive electrode. Figure b is a graph of the potential U as a function of x with no bias. The potential is constant except in two narrow regions where it has a larger constant value. The electron energy, represented by a dashed line, is between the lower and higher values of U, closer to the lower one. Two allowed energy levels, labeled as E sub dot, are shown. Both are higher than the electron energy and less than the maximum value of U. Figure c shows the potential U of x with a voltage bias across the device. The potential has the same constant value to the left of the barriers as in figure a, but decreases linearly between the barriers. U is constant again to the right of the barriers but at a lower value than before. The allowed energies are also pulled down, and the lower one now coincides with the energy of the electron. — Resonant-tunneling diode: (a) A quantum dot of gallium arsenide embedded in aluminum arsenide. (b) Potential well consisting of two potential barriers of a quantum dot with no voltage bias. Electron energies $E_{electron}$ in aluminum arsenide are not aligned with their energy levels $E_{dot}$ in the quantum dot, so electrons do not tunnel through the dot. (c) Potential well of the dot with a voltage bias across the device. A suitably tuned voltage difference distorts the well so that electron-energy levels in the dot are aligned with their energies in aluminum arsenide, causing the electrons to tunnel through the dot.

Summary

A quantum particle that is incident on a potential barrier of a finite width and height may cross the barrier and appear on its other side. This phenomenon is called ‘quantum tunneling.’ It does not have a classical analog.
To find the probability of quantum tunneling, we assume the energy of an incident particle and solve the stationary Schrӧdinger equation to find wave functions inside and outside the barrier. The tunneling probability is a ratio of squared amplitudes of the wave past the barrier to the incident wave.
The tunneling probability depends on the energy of the incident particle relative to the height of the barrier and on the width of the barrier. It is strongly affected by the width of the barrier in a nonlinear, exponential way so that a small change in the barrier width causes a disproportionately large change in the transmission probability.
Quantum-tunneling phenomena govern radioactive nuclear decays. They are utilized in many modern technologies such as STM and nano-electronics. STM allows us to see individual atoms on metal surfaces. Electron-tunneling devices have revolutionized electronics and allow us to build fast electronic devices of miniature sizes.

Key equations

Normalization condition in one dimension	$P (x = − \infty, + \infty) = \int_{− \infty}^{\infty} \| Ψ (x, t) \|^{2} d x = 1$
Probability of finding a particle in a narrow interval of position in one dimension $(x, x + d x)$	$P (x, x + d x) = Ψ^{*} (x, t) Ψ (x, t) d x$
Expectation value of position in one dimension	$⟨ x ⟩ = \int_{− \infty}^{\infty} Ψ^{*} (x, t) x Ψ (x, t) d x$
Heisenberg’s position-momentum uncertainty principle	$Δ x Δ p \geq \frac{ℏ}{2}$
Heisenberg’s energy-time uncertainty principle	$Δ E Δ t \geq \frac{ℏ}{2}$
Schrӧdinger’s time-dependent equation	$- \frac{ℏ^{2}}{2 m} \frac{\partial^{2} Ψ (x, t)}{\partial x^{2}} + U (x, t) Ψ (x, t) = i ℏ \frac{\partial^{2} Ψ (x, t)}{\partial t}$
General form of the wave function for a time-independent potential in one dimension	$Ψ (x, t) = ψ (x) e^{− i ω t}$
Schrӧdinger’s time-independent equation	$- \frac{ℏ^{2}}{2 m} \frac{d^{2} ψ (x)}{d x^{2}} + U (x) ψ (x) = E ψ (x)$
Schrӧdinger’s equation (free particle)	$- \frac{ℏ^{2}}{2 m} \frac{\partial^{2} ψ (x)}{\partial x^{2}} = E ψ (x)$
Allowed energies (particle in box of length L )	$E_{n} = n^{2} \frac{π^{2} ℏ^{2}}{2 m L^{2}}, n = 1, 2, 3, . . .$
Stationary states (particle in a box of length L )	$ψ_{n} (x) = \sqrt{\frac{2}{L}} sin \frac{n π x}{L}, n = 1, 2, 3, . . .$
Potential-energy function of a harmonic oscillator	$U (x) = \frac{1}{2} m ω^{2} x^{2}$
Stationary Schrӧdinger equation	$- \frac{ℏ}{2 m} \frac{d^{2} ψ (x)}{d x^{2}} + \frac{1}{2} m ω^{2} x^{2} ψ (x) = E ψ (x)$
The energy spectrum	$E_{n} = (n + \frac{1}{2}) ℏ ω, n = 0, 1, 2, 3, . . .$
The energy wave functions	$ψ_{n} (x) = N_{n} e^{− β^{2} x^{2} / 2} H_{n} (β x), n = 0, 1, 2, 3, . . .$
Potential barrier	$U (x) = {\begin{matrix} 0, & when x < 0 \\ U_{0}, & when 0 \leq x \leq L \\ 0, & when x > L \end{matrix}$
Definition of the transmission coefficient	$T (L, E) = \frac{\| ψ_{tra} (x) \|^{2}}{\| ψ_{in} (x) \|^{2}}$
A parameter in the transmission coefficient	$β^{2} = \frac{2 m}{ℏ^{2}} (U_{0} - E)$
Transmission coefficient, exact	$T (L, E) = \frac{1}{{cosh}^{2} β L + {(γ / 2)}^{2} {sinh}^{2} β L}$
Transmission coefficient, approximate	$T (L, E) = 16 \frac{E}{U_{0}} (1 - \frac{E}{U_{0}}) e^{− 2 β L}$

Questions & Answers

how does Neisseria cause meningitis

Nyibol Reply

what is microbiologist

Muhammad Reply

what is errata

Muhammad

is the branch of biology that deals with the study of microorganisms.

Ntefuni Reply

What is microbiology

Mercy Reply

studies of microbes

Louisiaste

when we takee the specimen which lumbar,spin,

Ziyad Reply

How bacteria create energy to survive?

Muhamad Reply

Bacteria doesn't produce energy they are dependent upon their substrate in case of lack of nutrients they are able to make spores which helps them to sustain in harsh environments

_Adnan

But not all bacteria make spores, l mean Eukaryotic cells have Mitochondria which acts as powerhouse for them, since bacteria don't have it, what is the substitution for it?

Muhamad

they make spores

Louisiaste

what is sporadic nd endemic, epidemic

Aminu Reply

the significance of food webs for disease transmission

Abreham

food webs brings about an infection as an individual depends on number of diseased foods or carriers dully.

Mark

explain assimilatory nitrate reduction

Esinniobiwa Reply

Assimilatory nitrate reduction is a process that occurs in some microorganisms, such as bacteria and archaea, in which nitrate (NO3-) is reduced to nitrite (NO2-), and then further reduced to ammonia (NH3).

Elkana

This process is called assimilatory nitrate reduction because the nitrogen that is produced is incorporated in the cells of microorganisms where it can be used in the synthesis of amino acids and other nitrogen products

Elkana

Examples of thermophilic organisms

Shu Reply

Give Examples of thermophilic organisms

Shu

advantages of normal Flora to the host

Micheal Reply

Prevent foreign microbes to the host

Abubakar

they provide healthier benefits to their hosts

ayesha

They are friends to host only when Host immune system is strong and become enemies when the host immune system is weakened . very bad relationship!

Mark

what is cell

faisal Reply

cell is the smallest unit of life

Fauziya

cell is the smallest unit of life

Akanni

Innocent

cell is the structural and functional unit of life

Hasan

is the fundamental units of Life

Musa

what are emergency diseases

Micheal Reply

There are nothing like emergency disease but there are some common medical emergency which can occur simultaneously like Bleeding,heart attack,Breathing difficulties,severe pain heart stock.Hope you will get my point .Have a nice day ❣️

_Adnan

define infection ,prevention and control

Innocent

I think infection prevention and control is the avoidance of all things we do that gives out break of infections and promotion of health practices that promote life

Lubega

Heyy Lubega hussein where are u from?

_Adnan

en français

Adama

which site have a normal flora

ESTHER Reply

Many sites of the body have it Skin Nasal cavity Oral cavity Gastro intestinal tract

Safaa

skin

Asiina

skin,Oral,Nasal,GIt

Sadik

How can Commensal can Bacteria change into pathogen?

Sadik

How can Commensal Bacteria change into pathogen?

Sadik

all

Tesfaye

by fussion

Asiina

what are the advantages of normal Flora to the host

Micheal

what are the ways of control and prevention of nosocomial infection in the hospital

Micheal

what is inflammation

Shelly Reply

part of a tissue or an organ being wounded or bruised.

Wilfred

what term is used to name and classify microorganisms?

Micheal Reply

Binomial nomenclature

adeolu

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Source: OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4

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