Find the energy spectrum and wave functions of the stationary states of a particle in the potential indicated in the figure
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Find the energy levels and wave functions of a particle in a potential field:Investigate cases of rational and irrational frequency ratios
Potential energy function,
V(x) = (1/2)mw2x2
Assuming the time-independent Schrödinger equation, show that the following wave functions are solutions describing the one-dimensional harmonic behaviour of a particle of mass m, where ?2-h/v/mK, and where co and ci are constants. Calculate the energies of the particle when it is in wave-functions ?0(x) and V1 (z) What is the general expression for the allowed energies En, corresponding to wave- functions Un(x), of this one-dimensional quantum oscillator? 6 the states corresponding to the...
1. A particle is described by wave function: = A exp(-alphax^2). Find the potential energy V(x) with V(0)=0. And what is the energy of the particle?
Quantum Mechanics.
Find the energies, degenerations and wave functions for the first
three energy levels (ground state
and first two excited states) of a system of two identical
particles with spin , which move in a
one-
dimensional infinite well of size .
Find corrections of energies to first order in if an
attracting potential of contact
is added.
Show that in the case of "spinless" fermions, the previous
perturbation has no effect.
Step by step process with good handwriting,...
a) The wave-functions of the states [) and (o) are given by y(x) and (x), respectively. Derive the expression for the inner product (4) in terms of the wave- functions Q(x) and (x). What is the physical meaning of y(x) and (x)/2? b) Fig. 1 shows a sketch of y(x). Sketch y(x) such that the states [4) and (o) are orthogonal: (14) = 0. (x) M Figure 1 c) Assume a particle has a wave-function y(x) sketched in Fig. 2....
Quantum Mechanics. Find the energies, degenerations and wave functions for the first three energy levels (ground state and first two excited states) of a system of two identical particles with spin , which move in a one- dimensional infinite well of size . Find corrections of energies to first order in if an attracting potential of contact is added. Show that in the case of "spinless" fermions, the previous perturbation has no effect. Step by step process with good handwriting,...
1 Schrödinger Equation At the stationary regime (without temporal dependence), the wave function of a stationary quantum particle confined in a rectangular box of sides a, b and c satisfies the Schrödinger equation (1) h2 Vay = EU (1) 2m where E is the energy at the stationary state of the particle and one of vertices is located at the coordinated origin. It is required that the wave function is annulled at the borders of the box. (a) Using this...
1 Schrödinger Equation At the stationary regime (without temporal dependence), the wave function of a stationary quantum particle confined in a rectangular box of sides a, b and c satisfies the Schrödinger equation (1) h2 Vay = EU (1) 2m where E is the energy at the stationary state of the particle and one of vertices is located at the coordinated origin. It is required that the wave function is annulled at the borders of the box. (a) Using this...
1. The wave-functions of the states [4) and (0) are given by y(x) and Q(x), respectively. Derive the expression for the inner product (14) in terms of the wave- functions Q(x) and (x). What is the physical meaning of y(x) and (x)/2? 2. Fig. 1 shows a sketch of y(x). Sketch y(x) such that the states (4) and (o) are orthogonal: (014) = 0. (x) M Figure 1 3. Assume a particle has a wave-function y(x) sketched in Fig. 2....
1. The wave-functions of the states [4) and (0) are given by y(x) and Q(x), respectively. Derive the expression for the inner product (14) in terms of the wave- functions Q(x) and (x). What is the physical meaning of y(x) and (x)/2? 2. Fig. 1 shows a sketch of y(x). Sketch y(x) such that the states (4) and (o) are orthogonal: (014) = 0. (x) M Figure 1 3. Assume a particle has a wave-function y(x) sketched in Fig. 2....