2015-9-20 Chang-Kui Duan, Institute of Modern Physics, CUPT 1 Harmonic oscillator and coherent states Reading materials: 1.Chapter 7 of Shankar’s PQM.

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Presentation transcript:

Chang-Kui Duan, Institute of Modern Physics, CUPT 1 Harmonic oscillator and coherent states Reading materials: 1.Chapter 7 of Shankar’s PQM. 1.Energy eigen states by algebra method 2.Wavefunction 3.Coherent state 4.The most classical quantum system

Chang-Kui Duan, Institute of Modern Physics, CUPT 2 Algebra method for eigen states Defining dimensionless coordinate position and momentum are now on equal foot. Classical dynamics: The Hamiltonian of a harmonic oscillator is Cyclic trajectory in the phase space.

Chang-Kui Duan, Institute of Modern Physics, CUPT 3 Quantum mechanics: Let us “rotate” the coordinates by an imaginary angle so that the cyclic rotation in the phase space is automatically taken into account by the transformation Note: Do you still remember how to write a circularly polarized light (whose electric field rotates) in terms of linear polarization? The Hamiltonian becomes How to get the eigen states and the eigen values?

Chang-Kui Duan, Institute of Modern Physics, CUPT 4 So there must be a ground state 1. The energy spectrum must be lower bounded, for 2. There should be no continuum state, i.e., the eigenstate wavefunction should be normalized to one. Otherwise the energy of the state cannot be finite due to the infinite potential diverging at the remote positions. 3. Theorem: In one-dimension space, a discrete state cannot be degenerate (see Shankar, PQM page 176 for a proof). A few general properties to be used:

Chang-Kui Duan, Institute of Modern Physics, CUPT 5 If there is an eigenstate Repeating the process, we get a series of eigen states Their energies form an equally space ladder

Chang-Kui Duan, Institute of Modern Physics, CUPT 6 The energy ladder has to be lower bounded, so we must have So the ground state energy is given by All the other eigen states can be obtained by

Chang-Kui Duan, Institute of Modern Physics, CUPT 7 matrix forms in the eigen state basis:

Chang-Kui Duan, Institute of Modern Physics, CUPT 8 matrix forms in the eigen state basis: The dimensionless position and momentum operators are

Chang-Kui Duan, Institute of Modern Physics, CUPT 9 Wavefunctions Let us first consider the ground state: In the dimensional coordinates: The solution is So the ground state wavefunction in the real space is: A nice property of Gaussian function is that its Fourier transformation is also a Gaussian function. The wavefunction in the q-representation would have the same form (remember Y and Q are inter-exchangeable. A wavepacket centered at the potential minimum.

Chang-Kui Duan, Institute of Modern Physics, CUPT 10 Now consider the excited states: Thus the wavefunction in real space is The above equation actually defines the generation of Hermite polynomials. The wavefunction in the momentum-representation is defining a nice property of the F.T. of Hermite polynomials.

Chang-Kui Duan, Institute of Modern Physics, CUPT 11 Regarded as boson Now that all the eigen states of a harmonic oscillator are equally spaced., we can take the rising from one state to the next one as the addition of one particle with the same energy to a mode. The ground state contains no particle and hence is the vacuum state. Simple one mode can have an arbitrary number of particles, this particle is a boson. Vacuum state The state with n bosons, called a Fock state The operator annihilating one boson The operator creating one boson The boson particle number operator The energy of the boson The energy of the vacuum

Chang-Kui Duan, Institute of Modern Physics, CUPT 12 Coherent state A coherent state of a harmonic oscillator is defined as In terms of the position and momentum operators, it is

Chang-Kui Duan, Institute of Modern Physics, CUPT 13 Coherent state in Fock state basis To derive the wave function of the coherent state in the Fock state basis, we use the Baker-Hausdorff theorem so the condition for the theorem is satisfied.

Chang-Kui Duan, Institute of Modern Physics, CUPT 14 Coherent state in Fock state basis The expansion is

Chang-Kui Duan, Institute of Modern Physics, CUPT 15 The state is normalized (of course) as can be checked directly: Coherent state is an eigen state of the annihilation operator: Removing one boson does NOT change a coherent state! However, adding one boson changes the state

Chang-Kui Duan, Institute of Modern Physics, CUPT 16 The expectation value of the boson number is Boson number distribution (Poisson distribution)

Chang-Kui Duan, Institute of Modern Physics, CUPT 17 To understand the nature of the coherent state, let us consider first a few special case: The real space wave function of this state is Or in the momentum representation The state is the ground state with the momentum distribution shifted by

Chang-Kui Duan, Institute of Modern Physics, CUPT 18 The real space wave function of this state is The wave function in the momentum representation is The state is the ground state with the real-space distribution shifted by

Chang-Kui Duan, Institute of Modern Physics, CUPT 19 For more, do the homework. Baker-Hausdorff theorem

Chang-Kui Duan, Institute of Modern Physics, CUPT 20 Quantum fluctuation According to Heisenberg principle Fock states

Chang-Kui Duan, Institute of Modern Physics, CUPT 21 In particular, for the vacuum state The vacuum state has minimum quantum fluctuation (the most classical state)

Chang-Kui Duan, Institute of Modern Physics, CUPT 22 Quantum fluctuation: Coherent state For a coherent state The center of the wavepacket in the phase space is at

Chang-Kui Duan, Institute of Modern Physics, CUPT 23 A coherent state has minimum quantum fluctuation. The variance can be obtained by calculating This justify our viewing a coherent state as a wavepacket centered at a point in the phase space and a most classical state.

Chang-Kui Duan, Institute of Modern Physics, CUPT 24 Completeness condition: The coherent states for all complex numbers form a complete basis Coherent states as a basis

Chang-Kui Duan, Institute of Modern Physics, CUPT 25 The Hilbert space has been expanded by a discrete set of states (the Fock states). But the complex numbers form a continuum. So the coherent states must be over complete, i.e., more than enough, since they are not orthogonal:

Chang-Kui Duan, Institute of Modern Physics, CUPT 26 The most classical quantum system

Chang-Kui Duan, Institute of Modern Physics, CUPT 27 We have seen that a coherent state can be viewed as a shift in the phase space from the vacuum state. The vacuum state, of course, is also a coherent state. What if we do the shift from a coherent state other than the vacuum? Repeatedly using Baker-Hausdorff theorem: It is still a coherent state, up to a trivial phase factor.

Chang-Kui Duan, Institute of Modern Physics, CUPT 28 A shift in the phase space from a coherent state is still a coherent state, the total shift from the vacuum is just the sum of the two shifts. Thus we can define a shift operator

Chang-Kui Duan, Institute of Modern Physics, CUPT 29 Time evolution of a coherent state If we have an initial coherent state: The time evolution is simply It is a coherent state with its shift from the vacuum rotating in the phase space like a classical oscillator.

Chang-Kui Duan, Institute of Modern Physics, CUPT 30 Harmonic oscillator driven by a force Let us consider the motion of a harmonic oscillator starting from the ground state In the form of boson operators: Suppose the state at a certain time is The Schroedinger equation is Consider an infinitesimal time increase

Chang-Kui Duan, Institute of Modern Physics, CUPT 31 The first term is a free evolution of the state. The second term is the shift operator which shift a state in the phase space along the position axis. The evolution from the initial state in a finite time is

Chang-Kui Duan, Institute of Modern Physics, CUPT 32 So, if the initial is a coherent state, say, the vacuum state, the state after a finite time of evolution is still a coherent state And we have the shift for an infinitesimal time increase to be The equation of motion is: i.e., The same as the classical eqns. for position and momentum!

Chang-Kui Duan, Institute of Modern Physics, CUPT 33 Conclusion: A harmonic oscillator driven by a classical force from the ground state is always in a coherent state. We have seen that the coherent state follows basically the equations for the classical eqns for position and momentum. It could be taken as a reproduction of the classical dynamics from quantum mechanics. The coherent state could be understood as classical particle, though it is quite a wavepacket (it is just so small that we had not enough resolution to tell it from a particle). So, if we have only classical forces and harmonic oscillators, there is no way to obtain a “real” quantum state from the vacuum or the ground state. That is why we call harmonic oscillators the most classical quantum systems.