Properly solution image 1and 2 Use the Schrödinger equation to calculate the energy of a 1-dimensional particle-in-a-box system inwhich the normalized wave function is 4' =sin(6x). The box boundaries are at x=0 and x=T/3. Thepotential energy is zero when 0 < xs and co outside of these boundaries. What is the value of quantum number, n, for a 1-dimensional particle-in-a-box system in which thenormalized wave function is 4' = 2 sin (*).The box boundaries are at x=0 and x=3Tn. The potentialenergy is zero when 0 < x< 3n and ∞ outside of these boundaries.

Problem 1 Wavefunction of particle in a box is given by, ψx=2LsinnπxL

Use the Schrödinger equation to calculate the energy of a 1-dimensional particle-in-a-box system in which the normalized wave function is 4 = Esin(6x). The box boundaries are at x=0 and x=n/3. The potential energy is zero when 0 < x< and co outside of these boundaries.

Use the Schrödinger equation to calculate the energy of a 1-dimensional particle-in-a-box system in which the normalized wave function is 4 = Esin(6x). The box boundaries are at x=0 and x=n/3. The potential energy is zero when 0 < x< and co outside of these boundaries.

Physics for Scientists and Engineers with Modern Physics

10th Edition

ISBN:9781337553292

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter40: Quantum Mechanics

Section: Chapter Questions

Problem 17P

See similar textbooks

Related questions

Q: What is the degeneracy of the 4th excited state of a 3-dimensional isotropic harmonic oscillator?

Q: -A system is defined by the wavefunction: 27nx (x) = A cos for 4 (a) Determine the normalization…

Q: 1. A particle in the infinite square well has the initial wave function L 2Ax, Y(x,0) = L |A(L – x),…

A: As per guidelines we are suppose to do only first three subpart form multipart question kindly post…

Q: Consider an atom with only two states: a ground state with energy 0, and an excited state with…

Q: What is the physical interpretation of the wave function in the Schrodinger Equation?

A: Wave function ψ is a mathematical function that describe certain properties of the wave. However…

Q: Schrodinger’s equation is an example of an eigenvalue equation. Which of the following functions is…

A: The correct option is d)

Q: The wave function for an electron in an infinite potential well is given as follows; TX sin L 4,(x)…

Q: A potential barrier of height V extends from x = 0 to positive x. Inside this barrier the normalized…

A: (a) Probability of finding the particle inside the barrier

Q: If p=-iħ d/dx is the linear momentum operator. What is its eigenvalue if it is affected on a…

A: if any operator operates on wave function, than the result should be some constant multiplied by…

Q: The wave function for a quantum particle confined to moving in a one-dimensional box located between…

A: The wave function for a quantum particle confined to moving in a one-dimensional box located between…

Q: Show that the wavelength predicted for a particle in a one-dimensional box of length L from the de…

A: For a box of length L and V=0 in this length, we can write Schrodinger equation -h2mdψ2dx2=Eψ…

Q: The wavefunction of an electron is given by 1≤x≤ 16 y(x) = c = 0 x 16 where c is a positive real…

A: Probability of given wave function

Q: Find expectation value of position and for an electron in the ground state of hydrogen across the…

A: ..

Q: equation for the particle in a one-dimensional box, the quantization of energy levels results when…

A: Schrodinger wave equation for the particle in a one dimensional box is : δ2ψδx+8π2mh2E-vψ=0

Q: For a "particle in a box" of length, L, the wavelength for the nth level is given by An 2L %3D 2п…

Q: A particle of mass m in a harmonic oscillator potential with angular frequency w is in the state (1)…

A: Given A particle of mass m in a harmonic oscillator potential with angular frequency ω is in the…

Q: Find the Probability (in %) that a particle trapped in a box, L units wide can be found between…

Q: The ground-state energy of an electron trapped in a onedimensional infinite potential well is 2.6…

Q: The Potential energy describing and particle of mass (m) is V(x)= orxa The wave function describing…

A: In the given question, The potential energy describing a particle of mass (m) is V(x) = -∞ for…

Q: Using the time-independent Schrödinger equation, find the potential V(x) and energy E for which the…

Q: The eigenfunctions satisfy the condition | Vi (x)m(x)dx = &nm , &nm = 1 if n %3D %3D = m , otherwise…

Q: Q2:A) A linear harmonic oscillator Is in a state which is a superpostion of the ground state and the…

Q: The energy absorbed in the transition from n=1 to n=2 for a 1-dimensional harmonic oscillator is hv.…

A: Given that: Transition from n=2 to n=1

Q: Which is the Schrodinger equation for a 1D harmonic oscillator:

A: The harmonic oscillator Hamiltonian is given by, H=p22m+12kx2 Here, m is the mass, k is the force…

Q: Consider a trial function v = x(L-x) for a particle in a one dimensional box of length L. Apply the…

A: We have trial wave function ψ=x(L-x) where L is the length of the box. We need to find to find…

Q: The wavefunction of the particle in its ground state is w(x)= Ae 2a, Calculate the first %3D order…

A: The first-order energy correction is given by: ∫ψ*(x)H'ψ(x)dx∫ψ*ψdx where ψ(x) is the wavefunction…

Q: An electron having total energy E = 4.50 eV approaches a rectangular energy barrier with U = 5.00 eV…

A: (a) To determine the transmission coefficient, first, it needs to determine the constant α by the…

Q: An electron is trapped in a one-dimensional infinite potential well that is 100 pm wide, the…

A: Given : potential well, L = 100 × 10-12 m ∆x = 5.0 × 10-12 m

Q: The ground state energy of an electron in a one-dimensional trap with zero potential energy in the…

A: Given : Initial potential energy at the wall, E1 = 2.0 eV Let the initial width of potential well be…

Q: The one-dimensional harmonic oscillator has a potential V(x) = ka² /2. We Henote the solutions of…

A: Please find solution to part a

Q: The number of methods for arranging two semi-classical systems on a power slice of 4 states is: O 4…

Q: An electron is trapped in a one-dimensional infinite potential well. For what (a) higher quantum…

Q: Consider the wavefunction for a particle in a one-dimensional box when the level is n = 6. Calculate…

Q: For a particle in a 1-dimensional infinitely deep box of length L, the normalized wave function or…

A: We have to find the probability of finding the particle.

Q: The first four Hermite polynomials of the quantum oscillator are H0 = 1, H1 = 2x, H2 = 4x2 − 2, H3 =…

Q: What is the independent wave function for a particle in a box x=0,L

Q: A particle, which is initially (t = 0) in the ground state of an infinite, one-dimensional potential…

A: The ground state and first excited state of the given infinite one-dimensional potential box can be…

Q: Calculate the average or expectation value of the position of a particle in a one-dimensional box…

Q: In the probabilistic interpretation of the wave function y, the quantity 2ly| represents the…

Q: An electron of mass m in a cubic box of side length (L) is perturbed in the direction and magnitude…

Q: Find the excitation energy from the ground level to the third excited level for an electron confined…

Q: Show that normalizing the particle-in-a-box wave function ψ_n (x)=A sin⁡(nπx/L) gives A=√(2/L).

Concept explainers

Refraction of Light

Refraction is a change in the direction of light rays when they travel from one medium to another. It is the bending of light when it goes through different media.

Angle of Refraction

Light is considered by many scientists to have dual nature, both particle nature and wave nature. First, Particle nature is one in which we consider a stream of packets of energy called photons. Second, Wave nature is considering light as electromagnetic radiation whereas part of it is perceived by humans. Visible spectrum defined by humans lies in a range of 400 to 700 nm wavelengths.

Index of Refraction of Diamond

Diamond, the world’s hardest naturally occurring material and mineral known, is a solid form of the element carbon. The atoms are arranged in a crystal structure called diamond cubic. They exist in a huge variety of colours. Also, they are one of the best conductors of heat and have a very high melting point.

Question

Properly solution image 1and 2

Use the Schrödinger equation to calculate the energy of a 1-dimensional particle-in-a-box system in
which the normalized wave function is 4' =
sin(6x). The box boundaries are at x=0 and x=T/3. The
potential energy is zero when 0 < xs and co outside of these boundaries.

What is the value of quantum number, n, for a 1-dimensional particle-in-a-box system in which the
normalized wave function is 4' = 2 sin (*).
The box boundaries are at x=0 and x=3Tn. The potential
energy is zero when 0 < x< 3n and ∞ outside of these boundaries.

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Step 3

VIEW

Step by step

Solved in 3 steps

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

$Refraction of light$

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.

Similar questions

Suppose a wave function is discontinuous at some point. Can this function represent a quantum state of some physical particle? Why? Why not?
What is the ground state energy (in eV) of an a -particle confined to a one-dimensional box the size of the uranium nucleus that has a radius of approximately 15.0 fm?
What is the ground state energy (in eV) of a proton confined to a one-dimensional box the size of the uranium nucleus that has a radius of approximately 15.0 fm?
Consider an infinite square well with wall boundaries x=0 and x=L. Show that the function (x)=Asinkx is the solution to the stationary Schrödinger equation for the particle in a box only if k=2mE/h. Explain why this is an acceptable wave function only if k is an integer multiple of /L.
A muon, a quantum particle with a mass approximately 2(X) times that of an electron, is incident on a potential barrier of height 10.0 eV. The kinetic energy of the impacting muon is 5.5 ev and only about 0.10% of the squared amplitude of its incoming wave function filters through the barrier. What is the barrier's width?
If the ground state energy of a simple harmonic oscillator is 1.25 eV, what is the frequency of its motion?
Verify that given by Equation 7.57 is a solution of Schrödinger's equation for the quantum harmonic oscillator. n(x)=Nne2x2/2Hn(x),n=0,1,2,3,...
Show that the two lowest energy states of the simple harmonic oscillator, 0(x) and 1(x) from Equation 7.57, satisfy Equation 7.55. n(x)=Nne2x2/2Hn(x),n=0,1,2,3,.... h2md2(x)dx2+12m2x2(x)=E(x).
A particle with mass m moving along the x-axis and its quantum state is represented by the following wave function: (x,t)={0,x0Ax e ax e iEt/h,x0, where a a=2.01010m1. (a) Find the normalization constant. (b) Find the probability that the particle can be found on the interval 0xL. (c) Find the expectation value of position. (d) Find the expectation value of kinetic energy.
A particle with mass m is described by the following wave function: (x)=Acoskx+Bsinkx, where A, B, and k are constants. Assuming that the particle is free, show that this function is the solution of the stationary SchrÖdinger equation for this particle and find the energy that the particle has in this state.
Can a quantum particle 'escape' from an infinite potential well like that in a box? Why? Why not?
Use Heisenberg's uncertainty principle to estimate the ground state energy of a particle oscillating on an spring with angular frequency, =k/m, where k is the spring constant and m is the mass.