Since there are 10 markers, it seems natural to aim for 10-way parallelization. Splitting on the first digit might achieve this in a way that's easy for a human to perform, although it depends on the distribution of the registration numbers whether you get an even division or not.
It's also the first step of an MSD radix sort. Exam papers are like linked lists in that concatenating sequences is cheap (put one pile on top of another pile). So an MSD radix sort is embarrassingly parallel, easy for a human to perform, and therefore I propose a modified MSD radix sort:
- Divide the papers into 10 piles on their most significant digit[*]. Assign one pile to each of the 10 people.
- Each person takes their pile and continues performing an MSD radix sort. I expect that below a certain size, insertion sort becomes faster than radix sort, and it's particularly easy for a human handling physical objects. That size could be determined in advance if you have testing time, or just leave it for the individuals to guess. For the given size of 400 papers, a second radix step gives an average size of 4 papers, which surely is below the threshold.
- The initial 10 piles might not all be the same size, and the people might not all work at the same speed. Therefore, some of the 10 people will finish their pile before others. Fortunately, it's very easy for them to help others: just find an unsorted pile and sort it.
- Finally, stack all the piles together (this is where top-down approaches like MSD radix or quicksort have a big advantage over bottom-up approaches like LSD radix or mergesort).
I don't think that bubble sort or merge sort are useful, they're actually quite fiddly to do by hand. Selection sort might be worth testing against insertion sort for very small piles. In practice, a human can sort 4 objects just by looking at the numbers, mentally sorting those numbers, then putting the objects into order. You could call that selection sort.
[*] Ideally that's the MSD of all of them put together, and you pad numbers with leading zeroes as necessary. But if you don't know in advance how many digits a registration number can have, that's actually quite awkward, it might require an initial pass of all 400 papers to find the maximum number. An alternative is to split the papers based on the number of digits in the registration number, and continue from there. It still works as a top-down partition, just doesn't have the convenient division into 10 at the first step.