NumPy arrays are specifically designed for working with multidimensional numeric data, with additional support for arrays of arbitrary objects. They provide fast vectorized operations with convenient syntax.

```
>>> x = numpy.arange(4).reshape((2, 2))
>>> x
array([[0, 1],
[2, 3]])
>>> x.T # Transpose.
array([[0, 2],
[1, 3]])
>>> x.max()
3
>>> x * 4
array([[ 0, 4],
[ 8, 12]])
>>> x[:, 1] # Slice to select the second column.
array([1, 3])
>>> x[:, 1] *= 2
>>> x
array([[0, 2],
[2, 6]])
>>> timeit.timeit('x * 5',
... setup='import numpy; x = numpy.arange(1000)',
... number=100000)
0.4018515302670096
>>> timeit.timeit('[item*5 for item in x]',
... setup='x = range(1000)',
... number=100000)
8.542360042395984
```

In comparison, lists are fundamentally geared towards 1-dimensional data. You can have a list of lists, but that's not a 2D list. You can't conveniently take the max of a 2D data set represented as a list of lists; calling `max`

on it will compare the lists lexicographically and return a list. Lists are good for homogeneous sequences of objects, but if you're doing math, you want numpy, and you want ndarrays.