We divided the sample into four groups by temperature regimes and comparing the Lethal effect after exposure to high room temperatures for 50~58 days. After inoculating Cnidium officinale Makino with Tribolium castaneum Herbst, the storage insects of medicinal herbs, was 20 respectively. The results of treating cut Cninium officinale Makino are listed below. Survival rate of group A by exposure of 5 times at 35~36.5℃ is less than 7.5%. Survival rate of group C by exposure of 5 times at 35.5~39.5℃ and group D by exposure of 23day at 37~44℃ is less than 2.5%. Especially in the case of group D, we found that complete eradication of the insect is difficult despite exposure high temperature for a long time. Also most of the grinded Cninium officinale Makino has the same patten but group B by relatively treated low temperature has a significant difference in mortality. Insect mortality in cut Cninium officinale Makino by exposure at 35℃ and 39.5℃ is 7.5% and the insect mortality in grinded Cninium officinale Makino by exposure at 39. 5℃ is only 75%. The reason is estimated that heat conduction of grinded Cninium officinale Makino is slow and it was less shocked by heat because The final core temperature of medicinal herbs is relatively low about 0.5~2℃. This means that storage insect(Tribolium castaneum Herbst) can be suppressed at mid-high temperature if it is to be treated more than 50 days without problem of quality deterioration of medicinal herbs that can be caused by high temperature.

The thermal death kinetics of the Black timber bark beetle, Xylosandrus germanus, was investigated to develop a heat treatment for control of infested wood packing materials used to export goods. To determine the feasibility of microwave irradiation as an alternative control method, laboratory experiments irradiating wooden blocks of Douglas fir (200×200×250mm), which were artificially infested with adults, with 2.45 GHz of microwave energy. All (100%) Ambrosia beetle adults were killed by both hot water treatments and microwave irradiation at 52˚C and 58˚C, respectively. Probit analyses estimated the internal wood temperature required to produce Probit (0.99) efficacy to be 64.7˚C (95% CI 62.4-69.9˚C) at one minute after microwave treatment.

Thermal death kinetics of the Japanese pine sawyer, Monochamus alternatus, was investigated to develop a heat treatment method that controls the pest in wood packing materials used in the export of goods. To determine the feasibility of microwave irradiation as an alternative treatment, laboratory experiments were performed on blocks (200x200x250 mm) of Douglas fir artificially infested with live larvae and pupae irradiating the blocks with 2.45 GHz of microwave energy. One hundred percent mortality of larvae and pupae of Japanese pine sawyer was observed by hot water treatment at 64°C and 68°C, respectively. One hundred percent mortality of treated Japanese pine sawyer was achieved above 67°C for larvae and 70°C for pupae based on the measured wood temperature, regardless of the irradiation time.

Thermal death kinetics was examined to develop a heat treatment method to control the Pine wood nematode, Bursaphelenchus xylophilus, in wood packing materials for export goods. To determine the feasibility of microwave irradiation as an alternative treatment, we performed laboratory experiments on the blocks (200x200x250mm) of Douglas-fir artificially infested with live adults with subsequent 2.45GHz microwave energy irradiation. The 100% mortality of treated Pine wood nematode was achieved above 64℃ of the measured wood temperature, regardless of irradiated time. All measurement points in the blocks reached 64℃ within 84-312 seconds with microwave irradiation by wood weight. Likewise, the 100% mortality of nematodes were observed by hot water treatment on 62℃. We need further experimental verification, but commercial microwave (2.45GHz) treatment is a feasible alternative to conventional heat treatment to control Pine wood nematode on the wood packing materials for export goods.

Thermal death kinetics was examined to develop a heat treatment method to control the Alnus ambrosia beetle, Xylosandrus germanus, in wood packing materials for export goods. To determine the feasibility of microwave irradiation as an alternative treatment, we performed laboratory experiments on the blocks (200x200x250mm) of Douglas-fir artificially infested with live adults with subsequent 2.45GHz microwave energy irradiation. The 100% mortality of treated Alnus Ambrosia Beetle was achieved above 58℃ of the measured wood temperature, regardless of irradiated time. All measurement points in the blocks reached 58℃ within 84-312 seconds with microwave irradiation by wood weight. Likewise, the 100% mortality of breetles were observed by hot water treatment on 52℃. We need further experimental verification, but commercial microwave (2.45GHz) treatment is a feasible alternative to conventional heat treatment to control Alnus ambrosia beetle on the wood packing materials for export goods.