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I am trying to visualize the time dependence of a free particle given an initial wave-function using Python and I just wanted to know if I could use the in built FFT implementation from NumPy to find the coefficients of the integral

$$ \Psi(x,\,t)=\frac{1}{2\pi}\int_{-\infty}^\infty\phi(k)\exp\left[i\left(kx-\frac{\hbar k^2}{2m}t\right)\right]\,\mathrm{d}k $$

In the textbook I am basing this off of, they solve for $\phi(k)$ by finding the fourier transform analytically given an initial function $\Psi(x, 0)$. Logically, it seems like doing a discrete fourier transform to simulate a fourier transform on an array of values representing $\Psi(x, 0)$ is okay, but I'm wondering if there are some subtleties I might be missing that actually changes the interpretation of my results when using a discrete fourier transform to find $\phi(k)$ instead of a continuous one. More generally, I guess, is other than the fact one is applied to a discrete rather than continuous set of variables, what is the difference between a Discrete Fourier Transform and a Continuous Fourier Transform.

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Welcome to scicomp!

Do you want to plot or do you want to do a simulation?

There is no problem with doing numerical simulation within a discretized fourier space. It comes with a couple of advantages and disadvantages.

Once you fourier transformed your profile, which in your case is a wave-amplitude, then calculating derivatives is very easy. You can simply multiply with $i~k_j$, with $k_j$ being your wavenumber for that particular coefficient. So calculating derivatives is very convenient in a DFT-code. (a laplace operator is basically $(i k_j)^2$)!)

The transformation from real space to fourier space can be done via the FFT algorithm and takes $O(N LOG(N))$ operations if i remember correctly. There are performant libraries to take care of this.

One problem of course is that you can not calculate nonlinearities directly. If you have an array of coefficients $r_i$ in real space, and you want to calculate a nonlinearity, then you can simply calculate $(r_i)^2$ etc. In fourier space that is not possible. Therefore in navier stokes codes for example the nonlinearity is calculated in real space, and then may be re-transformed back for the rest of the numerical treatment.

Another constraint is that you are limited to periodic or quasi-periodic problems. Since the very basis for your computation are essentially sine- and cosine functions, there is no good way to resolve any boundary conditions or discontinuities. If you want to look at one free particle within a large empty domain you should be fine though.

What kind of time-dependence do you mean? You are stating the initial condition, but not really the dynamics of what you want to do!

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  • $\begingroup$ Thanks, that's really helpful! I guess I'm actually plotting, not simulating. By time-dependence, I mean I just want to plot the wavefunction at different values of t. $\endgroup$ – Lawrence Wang Oct 11 at 19:49
  • $\begingroup$ Well then you just create an array with the wavenumbers $\psi(k)$, multiply it with the correct time dependend phase, as your equation states, and transform to real space. Then just plot the profile $\endgroup$ – MPIchael Oct 12 at 7:55

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