Umm.. 1,000 records?? You are still well within the polynomial cooefficient dominance here.. If I have
selection-sort: 15 * n ^ 2 (reads) + 5 * n^2 (swaps)
insertion-sort: 5 * n ^2 (reads) + 15 * n^2 (swaps)
merge-sort: 200 * n * log(n) (reads) 1000 * n * log(n) (merges)
You're going to be in a close race for a lonng while.. By the way, 2x faster in sorting is NOTHING. Try 100x slower. That's where the real differences are felt. Try "won't finish in my life-time" algorithms (there are known regular expressions that take this long to match simple strings).
So try 1M or 1G records and let us know if you still thing merge-sort isn't doing too well.
That being said..
There are lots of things causing this merge-sort to be expensive. First of all, nobody ever runs quick or merge sort on small scale data-structures.. Where you have if (len <= 1), people generally put:
if (len <= 16) : (use inline insertion-sort)
At EACH propagation level.
Since insertion-sort is has smaller coefficent cost at smaller sizes of n. Note that 50% of your work is done in this last mile.
Next, you are needlessly running array1.pop(0) instead of maintaining index-counters. If you're lucky, python is efficiently managing start-of-array offsets, but all else being equal, you're mutating input parameters
Also, you know the size of the target array during merge, why copy-and-double the merged_array repeatedly.. Pre-allocate the size of the target array at the start of the function.. That'll save at least a dozen 'clones' per merge-level.
In general, merge-sort uses 2x the size of RAM.. Your algorithm is probably using 20x because of all the temporary merge buffers (hopefully python can free structures before recursion). It breaks elegance, but generally the best merge-sort algorithms make an immediate allocation of a merge buffer equal to the size of the source array, and you perform complex address arithmetic (or array-index + span-length) to just keep merging data-structures back and forth. It won't be as elegent as a simple recursive problem like this, but it's somewhat close.
In C-sorting, cache-coherence is your biggest enemy. You want hot data-structures so you maximize your cache. By allocating transient temp buffers (even if the memory manager is returning pointers to hot memory) you run the risk of making slow DRAM calls (pre-filling cache-lines for data you're about to over-write). This is one advantage insertion-sort,selection-sort and quick-sort have over merge-sort (when implemented as above)