The OH radical is known to play an important role in the atmosphere. It is formed by reactions of O atoms with H-containing molecules. The O(1D) + H2 reaction, the simplest yet one of the most fundamental reactions, has been extensively studied by many research groups using various techniques. Typically the sensitive laser-induced fluorescence (LIF) technique is employed for detection of OH. However, because of predissociation of OH at higher rotational and vibrational levels, detection of OH in these states are difficult. Although Rydberg tagging technique1 provides detailed information on the vibrational-rotational distribution of OH product, F1/ F2 and e/f components but except for v= 4 of OH were unresolved. We employed a step-scan Fourier-transform IR spectrometer to observe emission spectrum of OH emission (v = 1-4) produced from the reaction O(1D) + p-H2 in the spectra region 2300-3900 cm-1. O(1D) was produced by photolysis of O3 with light from a KrF excimer laser at 248 nm. Upon irradiation of a flowing mixture of O3 (38 mTorr) and p-H2 (76 mTorr) at 248 nm, emission of OH from highly internally excited states appeared within 2 μs, followed by rapid relaxation. The preliminary data at resolution of 0.6 cm-1, we were able to resolve most spectral line and derive population for each of the e/f and F1/F2 component. A small preference of the e/f propensity indicates that the reaction intermediate is short-lived.