I got the same problem, working in python, and I think that the limited precision of floating point arithmetic on a computer, esp. with powers of large numbers, is also not helping. I'll cut and paste my Python code and the results I get. This code tries to compute the first 20 moments of a standard normal. In short, I think it's not easy to compute high order moments of a distribution numerically, "high order" meaning here greater than 10 or so. In a separate experiment, I tried to reduce the variance I get on the 18th moment by drawing more and more samples, but that wasn't practical either given my "ordinary" computer.

```
N = 1000000
w = np.random.normal(size=N).astype("float128")
for i in range(20):
print i, mean(w**i) # simply computing the mean of the data to the power of i
```

Gives you:

```
0 1.0
1 0.000342014729693
2 1.00124397377
3 0.000140133725668
4 3.00334304532
5 0.00506625342217
6 15.0227401941
7 0.0238395446636
8 105.310071549
9 -0.803915389936
10 948.126995798
11 -34.8374820713
12 10370.6527554
13 -1013.23231638
14 132288.117911
15 -26403.9090218
16 1905267.02257
17 -658590.680295
18 30190439.4783
19 -16101299.7354
```

But the correct moments are: 1, 0, 1, 0, 3, 0, 15, 0, 105, 0, 945, 0, 10395, 0, 135135, 0, 2027025, 0, 34459425, 0, 654729075.