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I have been playing with an implementation of Visscher's explicit method for solving the time dependent Schrodinger equation (Are there simple ways to numerically solve the time-dependent Schödinger equation?)

Presumably if I want to simulate two identical, non-interacting particles I need to duplicate the simulation array for each particle.

How do I then modify the computation to take into account Fermion/Boson effects, i.e. that Fermions can't occupy the same space (ignoring spin), while Bosons are "encouraged" to do so?

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It is not that bosons are "encouraged" to occupy the same place, that is quite wrong. Here is an article on the spin-statistics theorem which describes the relationship between particle statistics and the transformation of the wave function under permutations of identical particles. This kind of thing requires more knowledge of quantum mechanics, so I recommend reading an introductory QM textbook.

In short, if you have two identical particles, and your wave function is $\psi(x_1,x_2)$, then $$ \psi(x_1,x_2) = \pm \psi(x_2,x_1), $$ and this is the relation you should impose on the discretized wave function. You will get a vector of values $\psi_{jk}$ (where $x_j$ are the points in discretized space), and so when you write down the numerical method applied to $\psi_{jk}$, you also require that $\psi_{jk}=\pm \psi_{jk}$, and adjust the numerical method to take account of this (anti-)symmetry.

Also, bear in mind that for non-interacting particles, the PDE separates, and the solution will be of the form $$\frac12\big(\psi_1(x_1)\psi_2(x_2)\pm \psi_1(x_2)\psi_2(x_1)\big),$$ where each $\psi_{i}$ solves the one-particle Schrodinger equation.

What you are asking is more a question of physics than scientific computing.

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  • $\begingroup$ This may be a dumb question, but just to clarify, do these effects mean that two particles cannot be independent even if they are non interacting? Thus it is impossible to visualise the superposed state of 2 particles on a 2d surface (as you can by using the PDE for one particle); a 2-d 2-particle system has a 4 dimensional structure? $\endgroup$ – Sideshow Bob Oct 8 '14 at 8:40
  • $\begingroup$ @SideshowBob No, if they are identical and non-interacting, then all this is says is that the wave function is (anti-)symmetric in its two arguments, which is the property relevant to a numerical method. I don't understand your second question. All this is discussed in standard textbooks. $\endgroup$ – Kirill Oct 8 '14 at 11:38
  • $\begingroup$ With nobody to discuss textbooks with I have a hard time understanding so thanks for your input :) I'll rephrase the last bit. For two distinguishable non interacting particles, presumably $\psi(x_1,x_2)=\psi_1(x_1)\psi_2(x_2)$. But for indistinguishable particles this is not true. Is that correct? $\endgroup$ – Sideshow Bob Oct 8 '14 at 13:48
  • $\begingroup$ @SideshowBob Yes, you can check that by writing down the PDE satisfied by $\psi(x_1,x_2)$ and seeing that it separates. Try physics.stackexchange.com. $\endgroup$ – Kirill Oct 8 '14 at 14:12

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