From the study of gas hydrate related thermal phenomena; it is possible to estimate the base of gas hydrate stability zone (BGHS) based on the intersection of the temperature gradient and the gas hydrate stability boundary curve and detect the gas hydrate within the sediment via negative temperature anomaly induced from the dissociation of gas hydrate during temperature raising and depressurizing. The Lister-type marine heat probe has been extensively utilized to measure in situ temperature, temperature gradient and thermal conductivity. However, the difficulty is we can only assume the thermal capacity of the probe when the data are regressed to calculate the temperature, temperature gradient and thermal conductivity of the seabed sediments, as there are currently no methods to precisely determine the probe’s heat capacity. We can only make very rough estimates of the heat capacity based on the building materials of the probes. In general, the estimated range could vary up to ±20 %. Yet we have come to understand that the heat capacity affects the calculated results greatly, especially the temperature gradient, which would further influence the estimated depth of BGHS. Here we have developed two alternative methods. One is to wrap the probe with enameled wire and observe its resistance corresponding to the temperature change. The other is to use infrared camera to scan the temperature change on the probe. After experimenting with both methods, we have found the infrared scanning method to be far better than the enameled wire method in both accuracy and convenience. Furthermore, the standard deviation of heat capacity measured by the infrared scanning method is within ±2 % which is about one order better than conventional estimate. Due to temperature raising and depressurizing as we transport the gas hydrate from the seabed toward the sea surface, it will dissociate and rapidly absorb the surrounding heat, which would produce anomalies in thermal conductivity and negative temperature. According to our experiments, even when the sediment is bearing very little granulated gas hydrate, we can still detect the negative temperature anomaly of about 1 °C after two hours which is normally the time it takes to carry the sediment from seabed to the coring vessel. In the planed drilling sites for gas hydrate investigation, four of the sites have show anomalies in thermal conductivity. Amongst them, three of the sites have also shown negative temperature anomalies in infrared thermal images. The locations of these two related anomalies were in very close proximity. Particularly at site KP-7-1, we have detected every thermal anomaly indicating the presence of gas hydrate within the sediment.