Since the data is sorted, you can locate content very quickly and efficiently by just keeping a small, sparse subset of the data in memory. For example, let's say we decide to store every Nth element in memory. For efficient initialization of your API, you'd want to compile this sparse list in a separate file on disk, so you don't have to stream through 100GB of data to get it.
For each of these terms, you need to save the disk offset relative to the head of the file for where the term starts. Then, all you've got to do is load the sparse list / offset pairs into memory, and the implementations of your two requests become straightforward:
Get floor(n/N)-th string/offset pair from list
Seek offset position in index
Read/Skip n mod N strings, then return the next one
Binary search over sparse list in memory
Locate lower and upper bound string/offset pairs
If a string/offset pair is in the i-th position in our sparse list,
then the string itself is the (N x i)-th string in our index.
We can use this information to compute the return value
If the string we want isn't in memory:
Seek lower-bound offset in index
Read strings until we:
a) Find a match
b) Reach the high-bound offset
c) Reach a string which is lexicographically greater than the one we are looking for
Just return the index for the matching string in our sparse list
If the strings in your index are fixed-width, you can make even greater optimizations.
You will want to be careful about your choice of 'N' for this algorithm, if you implement it. Remember, the cost of reading 10 bytes from a position on disk isn't much lower than the cost of reading 10,000 bytes from that same position: It's the overhead of the disk seek, and getting in and out of the I/O call that hurts most.