I have been fighting with a very weird bug for almost a month. Asking you guys is my last hope. I wrote a program in C that integrates the 2d Cahn–Hilliard equation using the Implicit Euler (IE) scheme in Fourier (or reciprocal) space:

Where the "hats" mean that we are in Fourier space: h_q(t_n+1) and h_q(t_n) are the FTs of h(x,y) at times t_n and t_(n+1), N[h_q] is the nonlinear operator applied to h_q, in Fourier space, and L_q is the linear one, again in Fourier space. I don't want to go too much into the details of the numerical method I am using, since I am sure that the problem is not coming from there (I tried using other schemes).

My code is actually quite simple. Here is the beginning, where basically I declare variables, allocate memory and create the plans for the FFTW routines.

```
# include <stdlib.h>
# include <stdio.h>
# include <time.h>
# include <math.h>
# include <fftw3.h>
# define pi M_PI
int main(){
// define lattice size and spacing
int Nx = 150; // n of points on x
int Ny = 150; // n of points on y
double dx = 0.5; // bin size on x and y
// define simulation time and time step
long int Nt = 1000; // n of time steps
double dt = 0.5; // time step size
// number of frames to plot (at denominator)
long int nframes = Nt/100;
// define the noise
double rn, drift = 0.05; // punctual drift of h(x)
srand(666); // seed the RNG
// other variables
int i, j, nt; // variables for space and time loops
// declare FFTW3 routine
fftw_plan FT_h_hft; // routine to perform fourier transform
fftw_plan FT_Nonl_Nonlft;
fftw_plan IFT_hft_h; // routine to perform inverse fourier transform
// declare and allocate memory for real variables
double *Linft = fftw_alloc_real(Nx*Ny);
double *Q2 = fftw_alloc_real(Nx*Ny);
double *qx = fftw_alloc_real(Nx);
double *qy = fftw_alloc_real(Ny);
// declare and allocate memory for complex variables
fftw_complex *dh = fftw_alloc_complex(Nx*Ny);
fftw_complex *dhft = fftw_alloc_complex(Nx*Ny);
fftw_complex *Nonl = fftw_alloc_complex(Nx*Ny);
fftw_complex *Nonlft = fftw_alloc_complex(Nx*Ny);
// create the FFTW plans
FT_h_hft = fftw_plan_dft_2d ( Nx, Ny, dh, dhft, FFTW_FORWARD, FFTW_ESTIMATE );
FT_Nonl_Nonlft = fftw_plan_dft_2d ( Nx, Ny, Nonl, Nonlft, FFTW_FORWARD, FFTW_ESTIMATE );
IFT_hft_h = fftw_plan_dft_2d ( Nx, Ny, dhft, dh, FFTW_BACKWARD, FFTW_ESTIMATE );
// open file to store the data
char acstr[160];
FILE *fp;
sprintf(acstr, "CH2d_IE_dt%.2f_dx%.3f_Nt%ld_Nx%d_Ny%d_#f%.ld.dat",dt,dx,Nt,Nx,Ny,Nt/nframes);
```

After this preamble, I initialise my function h(x,y) with a uniform random noise, and I also take the FT of it. I set the imaginary part of h(x,y), which is `dh[i*Ny+j][1]`

in the code, to 0, since it is a real function. Then I calculate the wavevectors `qx`

and `qy`

, and with them, I compute the linear operator of my equation in Fourier space, which is `Linft`

in the code. I consider only the - fourth derivative of h as the linear term, so that the FT of the linear term is simply -q^4... but again, I don't want to go into the details of my integration method. The question is not about it.

```
// generate h(x,y) at initial time
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
rn = (double) rand()/RAND_MAX; // extract a random number between 0 and 1
dh[i*Ny+j][0] = drift-2.0*drift*rn; // shift of +-drift
dh[i*Ny+j][1] = 0.0;
}
}
// execute plan for the first time
fftw_execute (FT_h_hft);
// calculate wavenumbers
for (i = 0; i < Nx; i++) { qx[i] = 2.0*i*pi/(Nx*dx); }
for (i = 0; i < Ny; i++) { qy[i] = 2.0*i*pi/(Ny*dx); }
for (i = 1; i < Nx/2; i++) { qx[Nx-i] = -qx[i]; }
for (i = 1; i < Ny/2; i++) { qy[Ny-i] = -qy[i]; }
// calculate the FT of the linear operator
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
Q2[i*Ny+j] = qx[i]*qx[i] + qy[j]*qy[j];
Linft[i*Ny+j] = -Q2[i*Ny+j]*Q2[i*Ny+j];
}
}
```

Then, finally, it comes the time loop. Essentially, what I do is the following:

Every once in a while, I save the data to a file and print some information on the terminal. In particular, I print the highest value of the FT of the Nonlinear term. I also check if h(x,y) is diverging to infinity (it shouldn't happen!),

Calculate h^3 in direct space (that is simply

`dh[i*Ny+j][0]*dh[i*Ny+j][0]*dh[i*Ny+j][0]`

). Again, the imaginary part is set to 0,Take the FT of h^3,

Obtain the complete Nonlinear term in reciprocal space (that is N[h_q] in the IE algorithm written above) by computing -q^2*(FT[h^3] - FT[h]). In the code, I am referring to the lines

`Nonlft[i*Ny+j][0] = -Q2[i*Ny+j]*(Nonlft[i*Ny+j][0] -dhft[i*Ny+j][0])`

and the one below, for the imaginary part. I do this because:

- Advance in time using the IE method, transform back in direct space, and then normalise.

Here is the code:

```
for(nt = 0; nt < Nt; nt++) {
if((nt % nframes)== 0) {
printf("%.0f %%\n",((double)nt/(double)Nt)*100);
printf("Nonlft %.15f \n",Nonlft[(Nx/2)*(Ny/2)][0]);
// write data to file
fp = fopen(acstr,"a");
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
fprintf(fp, "%4d %4d %.6f\n", i, j, dh[i*Ny+j][0]);
}
}
fclose(fp);
}
// check if h is going to infinity
if (isnan(dh[1][0])!=0) {
printf("crashed!\n");
return 0;
}
// calculate nonlinear term h^3 in direct space
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
Nonl[i*Ny+j][0] = dh[i*Ny+j][0]*dh[i*Ny+j][0]*dh[i*Ny+j][0];
Nonl[i*Ny+j][1] = 0.0;
}
}
// Fourier transform of nonlinear term
fftw_execute (FT_Nonl_Nonlft);
// second derivative in Fourier space is just multiplication by -q^2
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
Nonlft[i*Ny+j][0] = -Q2[i*Ny+j]*(Nonlft[i*Ny+j][0] -dhft[i*Ny+j][0]);
Nonlft[i*Ny+j][1] = -Q2[i*Ny+j]*(Nonlft[i*Ny+j][1] -dhft[i*Ny+j][1]);
}
}
// Implicit Euler scheme in Fourier space
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
dhft[i*Ny+j][0] = (dhft[i*Ny+j][0] + dt*Nonlft[i*Ny+j][0])/(1.0 - dt*Linft[i*Ny+j]);
dhft[i*Ny+j][1] = (dhft[i*Ny+j][1] + dt*Nonlft[i*Ny+j][1])/(1.0 - dt*Linft[i*Ny+j]);
}
}
// transform h back in direct space
fftw_execute (IFT_hft_h);
// normalize
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
dh[i*Ny+j][0] = dh[i*Ny+j][0] / (double) (Nx*Ny);
dh[i*Ny+j][1] = dh[i*Ny+j][1] / (double) (Nx*Ny);
}
}
}
```

Last part of the code: empty the memory and destroy FFTW plans.

```
// terminate the FFTW3 plan and free memory
fftw_destroy_plan (FT_h_hft);
fftw_destroy_plan (FT_Nonl_Nonlft);
fftw_destroy_plan (IFT_hft_h);
fftw_cleanup();
fftw_free(dh);
fftw_free(Nonl);
fftw_free(qx);
fftw_free(qy);
fftw_free(Q2);
fftw_free(Linft);
fftw_free(dhft);
fftw_free(Nonlft);
return 0;
}
```

If I run this code, I obtain the following output:

```
0 %
Nonlft 0.0000000000000000000
1 %
Nonlft -0.0000000000001353512
2 %
Nonlft -0.0000000000000115539
3 %
Nonlft 0.0000000001376379599
...
69 %
Nonlft -12.1987455309071730625
70 %
Nonlft -70.1631962517720353389
71 %
Nonlft -252.4941743351609204637
72 %
Nonlft 347.5067875825179726235
73 %
Nonlft 109.3351142318568633982
74 %
Nonlft 39933.1054502610786585137
crashed!
```

The code crashes before reaching the end and we can see that the Nonlinear term is diverging.

Now, the thing that doesn't make sense to me is that if I change the lines in which I calculate the FT of the Nonlinear term in the following way:

```
// calculate nonlinear term h^3 -h in direct space
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
Nonl[i*Ny+j][0] = dh[i*Ny+j][0]*dh[i*Ny+j][0]*dh[i*Ny+j][0] -dh[i*Ny+j][0];
Nonl[i*Ny+j][1] = 0.0;
}
}
// Fourier transform of nonlinear term
fftw_execute (FT_Nonl_Nonlft);
// second derivative in Fourier space is just multiplication by -q^2
for ( i = 0; i < Nx; i++ ) {
for ( j = 0; j < Ny; j++ ) {
Nonlft[i*Ny+j][0] = -Q2[i*Ny+j]* Nonlft[i*Ny+j][0];
Nonlft[i*Ny+j][1] = -Q2[i*Ny+j]* Nonlft[i*Ny+j][1];
}
}
```

Which means that I am using this definition:

instead of this one:

Then the code is perfectly stable and no divergence happens! Even for billions of time steps! **Why does this happen, since the two ways of calculating Nonlft should be equivalent?**

Thank you very much to anyone who will take the time to read all of this and give me some help!

EDIT: To make things even more weird, I should point out that this bug does NOT happen for the same system in 1D. In 1D both methods of calculating `Nonlft`

are stable.

EDIT: I add a short animation of what happens to the function h(x,y) just before crashing. Also: I quickly re-wrote the code in MATLAB, which uses Fast Fourier Transform functions based on the FFTW library, and the bug is NOT happening... the mystery deepens.