You could avoid computing pairwise distances by observing that the two points which are furthest apart will occur as vertices in the convex hull. You can then compute pairwise distances between fewer points.
For example, with 100,000 points distributed uniformly in a unit square, there are only 22 points in the convex hull in my instance.
import numpy as np
from scipy import spatial
# test points
pts = np.random.rand(100_000, 2)
# two points which are fruthest apart will occur as vertices of the convex hull
candidates = pts[spatial.ConvexHull(pts).vertices]
# get distances between each pair of candidate points
dist_mat = spatial.distance_matrix(candidates, candidates)
# get indices of candidates that are furthest apart
i, j = np.unravel_index(dist_mat.argmax(), dist_mat.shape)
# e.g. [ 1.11251218e-03 5.49583204e-05] [ 0.99989971 0.99924638]
If the data is 2-dimensional, you can compute the convex hull in
O(n*log(n)) time where
n is the number of points. Unfortunately, the performance gains disappear as the number of dimensions grows.