We have examined the sensitivity of single and sequential two-photon laser-induced fluorescence (LIF) techniques for the detection of elemental mercury, Hg(0), in the gas phase. Single photon LIF involves excitation of the 6 3 P 1 -6 1 S 0 transition at 253.7nm, followed by observation of resonance fluorescence. Sequential two-photon techniques follow the initial 6 3 P 1 -6 1 S 0 excitation with a second excitation step to either the 7 1 S 0 or 7 3 S 1 levels followed by observation of blue or red shifted fluorescence. We have examined four variants of these approaches which all exceed the sensitivity of single photon LIF. The most sensitive detection approach involves the initial 253.7nm excitation followed by excitation of the 7 1 S 0 -6 3 P 1 transition at 407.8nm. Fluorescence is observed on the 6 1 P 1 -6 1 S 0 transition at 184.9nm. Using this approach, our limits of detection are 0.1ngm - 3 with a 10s integration time in air. We have also examined the effects of saturation, quenching and line-width on detection sensitivity. We have used the pulsed laser photolysis-pulsed laser-induced fluorescence (PLP-PLIF) technique to study the kinetics of the reaction of elemental mercury with the hydroxyl radical under atmospheric conditions at 298K. We see no evidence for reaction and obtain an upper limit of 1.2x10 - 1 3 cm 3 molecule - 1 s - 1 for the rate coefficient.