Fine-grained quantum advantage beyond double-logarithmic space

Abstract

Polynomial-time quantum Turing machines are provably superior to their classical counterparts within a common space bound in o( n). For ( n) space, the only known quantum advantage result has been the fact BPTISP(2O(n),o( n))⊂neq BQTISP(2O(n),o( n)), proven by exhibiting an exponential-time quantum finite automaton (2QCFA) that recognizes Lpal, the language of palindromes, which is an impossible task for sublogarithmic-space probabilistic Turing machines. No subexponential-time quantum algorithm can recognize Lpal in sublogarithmic space. We initiate the study of quantum advantage under simultaneous subexponential time and ( n) o( n) space bounds. We exhibit an infinite family F of functions in ( n)ω(1) no(1) such that for every fi∈F, there exists another function fi+1∈F such that fi+1(n) ∈ o(fi(n)), and each such fi corresponds to a different quantum advantage statement, i.e. a proper inclusion of the form BPTISP(2O(fi(n)),o( fi(n)))⊂neq BQTISP(2O(fi(n)),o( fi(n))) for a different pair of subexponential time and sublogarithmic space bounds. Our results depend on a technique enabling polynomial-time quantum finite automata to control padding functions with very fine asymptotic granularity.