I haven't done functional-relational mapping, per se, but I have used functional programming techniques to speed up access to an RDBMS.
It's quite common to start with a dataset, do some complex computation on it, and store the results, where the results are a subset of the original with additional values, for example. The imperative approach dictates that you store your initial dataset with extra NULL columns, do your computation, then update the records with the computed values.
Seems reasonable. But the problem with that is it can get very slow. If your computation requires another SQL statement besides the update query itself, or even needs to be done in application code, you literally have to (re-)search for the records that you are changing after the computation to store your results in the right rows.
You can get around this by simply creating a new table for results. This way, you can just always insert instead of update. You end up having another table, duplicating the keys, but you no longer need to waste space on columns storing NULL – you only store what you have. You then join your results in your final select.
I (ab)used an RDBMS this way and ended up writing SQL statements that looked mostly like this...
create table temp_foo_1 as select ...;
create table temp_foo_2 as select ...;
create table foo_results as
select * from temp_foo_n inner join temp_foo_1 ... inner join temp_foo_2 ...;
What this is essentially doing is creating a bunch of immutable bindings. The nice thing, though, is you can work on entire sets at once. Kind of reminds you of languages that let you work with matrices, like Matlab.
I imagine this would also allow for parallelism much easier.
An extra perk is that types of columns for tables created this way don't have to be specified because they are inferred from the columns they're selected from.