Following a recent proposal by Dhar et al (2006 Phys.Rev.Lett.96 100405),we demonstrate experimentally the preservation of quantum states in a two-qubit system based on a super-Zeno effect using liquid-state nuclear magnetic resonance techniques.Using inverting radiofrequency pulses and delicately selecting time intervals between two pulses,we suppress the effect of decoherence of quantum states.We observe that preservation of the quantum state |11 with the super-Zeno effect is three times more efficient than the ordinary one with the standard Zeno effect.
DNA computation (DNAC) has been proposed to solve the satisfiability (SAT) problem due to operations in parallel on extremely large numbers of strands.This paper attempts to treat the DNA-based bio-molecular solution for the SAT problem from the quantum mechanical perspective with a purpose to explore the relationship between DNAC and quantum computation (QC).To achieve this goal,it first builds up the correspondence of operations between QC and DNAC.Then it gives an example for the case of two variables and three clauses for details of this theory.It also demonstrates a three-qubit experiment for solving the simplest SAT problem with a single variable on a liquid-state nuclear magnetic resonance ensemble to verify this theory.Some discussions are made for the potential application and for further exploration of the present work.