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Article

Estimation of the Damage Risk Range and Activity Period of Termites (Reticulitermes speratus) in Korean Wooden Architectural Heritage Building Sites

by
Sihyun Kim
1 and
Jisoo Kim
2,*
1
Restoration Technology Division, National Research Institute of Cultural Heritage, Daejeon 34122, Republic of Korea
2
Safety and Disaster Prevention Division, National Research Institute of Cultural Heritage, Daejeon 34122, Republic of Korea
*
Author to whom correspondence should be addressed.
Forests 2024, 15(4), 602; https://doi.org/10.3390/f15040602
Submission received: 19 January 2024 / Revised: 20 March 2024 / Accepted: 25 March 2024 / Published: 26 March 2024
(This article belongs to the Special Issue Managing Indoor Wood Biodeterioration)
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Abstract

:
Korean wooden architectural heritage buildings are often damaged by termites, and climate change is expected to exacerbate the problem. To prevent termite damage, it is necessary to identify the habitat range and activity period of termites. In this study, we comprehensively analyzed the ecological characteristics of Reticulitermes speratus, the dominant termite species in South Korea, past termite damage records of wooden architectural heritage buildings, and climate data (2000–2019). We determined that termite infestations could potentially occur in 98.5% of the total studied area, except for a few mountainous regions in South Korea. In addition, termites were active for an average of 209 days per year. The habitat range of termites appears to be gradually expanding, possibly as a result of a combination of anthropogenic interventions, rising temperatures caused by climate change, and the ecological characteristics of termites. In the future, it is imperative to implement enhanced preventive and active termite control measures to preserve the original wooden architectural heritage buildings of South Korea.

1. Introduction

Termites are the leading cause of damage to wooden buildings and result in considerable economic losses. Although they are important decomposers in the ecosystem by effectively disintegrating plant material [1], the economic loss caused by termites is estimated to reach up to $40 billion annually [2]. Termites also pose a considerable threat to wooden architectural heritage buildings worldwide. Termite damage to wooden architectural buildings has been reported in China [3], Taiwan [4], Japan [5], and Southeast Asia [6]. In South Korea, termite damage to wooden architectural heritage buildings has been continuously confirmed since the 1980s [7,8,9,10]. A comprehensive analysis of biological damage surveys revealed that 51% of national wooden architectural heritage buildings presented evidence of termite damage [11]. Furthermore, climate change and the introduction of invasive species are anticipated to increase termite-induced damage to wooden architectural heritage buildings [12].
To date, a total of two families (Rhinotermitidae, Kalotermitidae), three genera (Reticulitermes, Glyptotermes, Incisitermes), and four species (Reticulitermes speratus, Reticulitermes kanmonensis, Glyptotermes nakajimai, Incisitermes minor) of termites have been confirmed in South Korea (Table 1). Of these, the latter three species have only been recently discovered (since the 2010s) and are found in a small number of locations. Conversely, the presence of R. speratus in Korea has been confirmed as early as the 1920s, and being a dominant species found throughout the country, it is widely considered to be the primary cause of the deterioration of wooden architectural heritage buildings [13].
Reticulitermes speratus is a kind of subterranean termite. They make many nests that are connected by galleries within wood or underground. Their workers explore their surroundings to find food sources, a process called foraging. During this process, they enter the surrounding wood structures and cause damage. R. speratus is widely distributed in Far East Asia, including Japan and northern China, as well as South Korea, where it causes damage to wooden structures [14]. Therefore, various studies have been conducted on the distribution range of this species in order to characterize its ecology and effectively control it. Consequently, the distribution range of this species was estimated to include areas where the mean temperature during January, the coldest month of the year, was at least −4 °C [20,21,22]. Based on this, the latitudinal limit of termite distribution in South Korea was estimated to be around the city of Chuncheon (37.88° N, 127.73° E) [23]. However, since the 2000s, colonies of R. speratus and damaged wooden buildings have been identified in places with mean temperature in the coldest month below −4 °C, such as Asashigawa in Hokkaido [24] and Sugadaira highland in Honshu [25]. Accordingly, Ohmura [26] investigated termite damage and infestations in Japan and found that the distribution of R. speratus was wider than previously estimated.
Similar cases have been identified in China. Termite damage in China has predominantly been observed in the southeast, whereas termite infestations have not been confirmed in the northeast due to the prevailing cold and dry winter; however, the termite distribution range has expanded to the northeast since the 2000s [27]. Termite infestations and damage have been confirmed in the Forbidden City in Beijing [28], and in 2012, termites were found in Gongzhuling, Jilin Sheng (43.2–44.2° N, 124.0–125.3° E) in Jilin Province. Of note, the mean January temperature in this area is cold, reaching approximately −10 °C, and is considered the northern limit of termite distribution in China [27].
Temperature exerts influence over the habitat range and activity period of termites [29,30]; consequently, climate change is expected to expand the habitat range of termites and prolong their activity period [31]. In a recent study, a 10 °C increase in the average annual temperature led to an approximately 6.8-fold increase in wood decomposition by termites [32]. In South Korea, the annual mean temperature has increased by 1.5 ℃ over the past 100 years, with the average temperature in January, the coldest month, being increased by 2.1 °C, which is estimated to have increased the activity period of termites by approximately 16 days [33]. In addition, the change in the activity period of termites over the past 40 years (1980−2019) in 106 national state-designated wooden architectural heritage buildings located in 84 cities and counties nationwide was estimated to have increased by approximately 9.2 days, from 243.3 to 252.5 days [34].
Termite damage is occurring in most wooden architectural heritage buildings in South Korea, with termites expanding their distribution range and prolonging their activity period. To reduce termite damage and preserve architectural heritage buildings, it is crucial to determine the range of termites in South Korea; however, no comprehensive study has been conducted on the distribution range of termites in South Korea. Therefore, in this study, we investigated the termite-induced damage status of important wooden architectural heritage buildings in South Korea and the temperature of each building throughout the year and estimated the habitat range and activity period of termites.

2. Research Site and Methods

2.1. Research Site

2.1.1. Study Area

South Korea is located in the mid-latitude region on the eastern edge of the Eurasian continent. Consequently, its climate is characterized by cold, dry winters and hot, rainy summers due to continental and oceanic influences. Due to its geographic location as a peninsula, the coastal regions surrounding the Korean Peninsula experience diverse maritime influences throughout the year, whereas the inland areas exhibit a distinct contrast, which can be attributed to a combination of seasonal wind changes and undulating topography [35]. Complex mountainous terrain covers approximately 70% of the Korean territory; despite the average elevation of the Korean Peninsula (448 m) not exceeding the overall average for East Asia (910 m), its relatively steep slopes and complex structural features contribute to its high diversity [36].

2.1.2. Wooden Architectural Heritage Buildings in South Korea

A total of 449 state-designated wooden architectural heritage buildings are found in South Korea (25 National Treasures, 230 Treasures, and 194 National Folk Cultural Properties) [37]. In this study, 104 sites (16 National treasures, 53 Treasures, 34 National Folk Cultural Properties, and one Historic Site) were selected from nine provinces and 94 counties, taking into account the geographical distribution (Figure 1). A detailed list is provided in Appendix A (Table A1).

2.2. Methods

2.2.1. Determining the Status of Termite Damage in Wooden Architectural Heritage Buildings

The current status of termite damage to wooden architectural heritage buildings was confirmed through the “Report on the Investigation of Species Causing Damage to Wooden Cultural Heritage” (NRICH, 2017−2022), which was conducted by the National Research Institute of Cultural Heritage. This study identified termite damage to wooden structures adjacent to individual heritage buildings and termite infestations in the surrounding forests. If termite damage or colonies were confirmed at least once in the case of a heritage building site that was inspected more than twice, the building was considered as a place of possible termite infestation.

2.2.2. Estimation of Outdoor Temperature at the Sites of Wooden Architectural Heritage Buildings Studied

The daily mean temperature for each architectural heritage building site was derived by collecting and processing MK−PRISM climate data provided by the Korea Meteorological Administration Climate Information Portal [38]. MK−PRISM data refer to a modified version of the Parameter-elevation Regression on Independent Slopes Model (PRISM) specifically tailored for South Korea; it takes into account factors such as the effects of altitude, distance, orientation, and oceanicity on local climate and has been modified to fit the 1 km grid of South Korea [38]. Currently, climate data available for the last 20 years from 2000 to 2019 are provided from MK-PRISM at 1 km × 1 km spatial resolution. From this data, we obtained daily mean temperature data for 104 wooden architectural heritage building sites.

2.2.3. Analysis of Thermal Limit of Termite Distribution

The thermal limit of termite distribution is determined by temperature during the coldest period. Using the termite damage records of heritage building sites and the Monthly Mean Temperature (MMT) value in January (the coldest month for all 104 heritage building sites), the lowest temperature at which termites can be active was determined.

2.2.4. Mapping the Termite Distribution Range

For each architectural heritage building identified above, the distribution range of termites in South Korea was mapped based on the results of the termite damage investigation and the MMT in January for the last 20 years. The map was created using ArcGIS Pro 3.2.2, the latest software in the ESRI GIS family (ESRI, Redlands, CA, USA) (Figure 2).

2.2.5. Calculating the Number of Days Available for Termite Activity at Each Wooden Architectural Heritage Building Site

The activity period of termites at each heritage was estimated to be consistent with the findings reported in previous studies [33,34]. Previous studies on termite survival rate and wood consumption by temperature [23,39] showed a high survival rate at 10–30 °C, with temperature values and wood consumption exhibiting a proportional correlation. Therefore, in this study, the period with a mean daily temperature of 10–30 °C was defined as the “number of days available for termite activity (NDATA)”. The NDATA was calculated using climate data for each architectural heritage building site.

3. Results

3.1. Outdoor Temperature at All Sites of the 104 Heritage Wood Buildings Studied

The monthly and annual mean temperatures of a total of 104 wooden architectural heritage buildings are presented in Appendix A (Table A2). The lowest MMT across all destinations was in January. From April to October, the monthly MMT at heritage building sites nationwide was over 11 °C, confirming that R. speratus was active on the ground nationwide. In March and November, the MMT nationwide was 5–7 °C, with deviations in temperature by region, indicating that the termite activity period was likely to differ across regions.
In order to examine the regional characteristics within South Korea, representative wooden architectural heritage buildings were selected from nine regions and their temperature distributions were examined. The monthly and annual mean temperatures at nine major heritage building sites are shown in Table 2. Gangwon-do had the lowest monthly and annual mean temperatures. This could be attributed to the fact that many architectural heritage buildings in the region are located at high latitudes and elevations. In contrast, Jeollanam-do had the highest temperature distribution showing the highest monthly and annual mean temperatures on the Korean Peninsula owing to the large number of architectural heritage buildings located at lower latitudes and elevations. Jeju Island is a volcanic island located approximately 80 km south of the Korean Peninsula, and its architectural heritage buildings are located along the coast, resulting in the highest mean monthly and annual temperatures of wooden heritage building sites in the country owing to their distribution in low latitudes and elevations.

3.2. Termite Damage and Distribution Range

Of the 104 sites studied, 83 (79.8%) showed termite damage to the architectural heritage buildings or neighboring wooden buildings. There are 17 heritage building sites located in areas where the MMT is below −4 °C, 12 (70.5%) of which termite damage was detected despite such a cold environment (Table 3). In particular, termite damage was confirmed in the architectural heritage buildings or neighboring buildings at the House with an Oak Bark Roof in Daei−ri, Samcheok, with an MMT in January of −8.5 °C, and Hoejeonmun Gate of Cheongpyeongsa Temple, Chuncheon, with an MMT in January of −7.5 °C. This finding suggested that termites may have a wider distribution range than expected. Based on these results, the distribution range of termites in South Korea was estimated to be 95,941 km2, accounting for 98.5% of the total land area of South Korea, 97,377 km2 (Figure 3). Of the 449 state-designated wooden architectural heritage buildings in South Korea, only one, Jeokmyeolbogung Hall of Jungdae Terrace in Odaesan Mountain, Pyeongchang (Treasure), shows an MMT lower than −8.5 °C in January, whereas the remaining 448 are all within the temperature range for termite damage.

3.3. Number of Days Available for Termite Activity at Each Wooden Architectural Heritage Building Site

The number of days available for termite activity at each architectural heritage building site ranged from 138 to 249 days, with an average of 209 days (Table 4 and Table 5). Among the tested sites, Jeokmyeolbogung Hall of Jungdae Terrace in Odaesan Mountain, Pyeongchang, had the shortest termite activity period of 138 days. This site is located at an elevation of 1180 m and had an MMT of −10.4 °C in January, which was the lowest among all tested sites. Excluding this location, the remaining 103 termite activity periods ranged from 165 to 249 days. Therefore, termites might be active in the ground for approximately five to eight months, although this period varies by region.

4. Discussion and Conclusions

In this study, 104 wooden architectural heritage buildings in 94 counties in South Korea were selected to determine the damage caused by R. speratus. The distribution range and activity period of termites were estimated by examining the extent of damage caused, as well as the MMT at each site throughout a period of 20 years. Consequently, approximately 80% of sites were found to have termite damage to the heritage or neighboring buildings, confirming the occurrence of termite damage in wooden architectural heritage buildings across almost all regions of South Korea.
In addition, termite damage was confirmed in the architectural heritage buildings or surrounding buildings in 12 of the 17 sites with MMT lower than −4 °C, which was previously considered the thermal limit for R. speratus distribution. In particular, R. speratus damage was confirmed in places with MMTs of −7.5 and −8.5 °C in January, suggesting that the species is widely distributed throughout South Korea, with few exceptions in certain mountainous areas. Of the 449 state-designated wooden architectural heritage buildings, except for the Jeokmyeolbogung Hall of Jungdae Terrace in Odaesan Mountain, Pyeongchang, all the others were within the temperature range conducive to potential termite damage. This termite damage risk is wider than that reported in the study by Lee and Jeong [23], who estimated the northern limit of termite distribution in South Korea to be near Chuncheon (MMT of −4.4 °C in January).
This study and other recent studies in Japan, China, and elsewhere have confirmed the gradually expanding distribution range of R. speratus. This could be attributed to a combination of environmental changes, termite ecology, and other factors. Urbanization and anthropogenic interventions, such as alterations in land cover and improvements in home insulation, have led to a reduction in the extent of freezing and increased temperatures, which may have facilitated the infestations of urban centers in colder regions by termites, which were previously absent from these areas [40].
Termites possess the ability to survive the cold of winter through a variety of strategies at the individual and colony levels. At the individual level, termites have the ability to alter the composition of their carbohydrate metabolites as well as balance their body water content and total lipids as a physiological strategy to adapt to the cold [41]. In addition, an evaluation of termite survival in response to temperature changes revealed a substantial decrease in their survival during short-term cold exposure when temperatures were lower than −8 °C for kings and queens and lower than −4 °C for soldiers and worker ants [42]. Even when subject to low temperatures, termites require a specific duration to die. Due to their social nature, termites are not readily exposed to low temperatures that might lead to freezing.
At the colony level, R. speratus forms multiple-site nesting connecting several wood resources by underground tunnels [43]. This elaborate nest structure plays a crucial role in regulating fluctuations in the outside temperature and creating a favorable microenvironment for the survival of termites. Subterranean termites also move their habitat in response to temperature changes. During winter, the ground temperature consistently remains higher than the air temperature, leading to less variation. As a result, it is expected that subterranean termites will descend into the deep underground where temperatures are relatively high in order to overwinter [44]. Eastern subterranean termites (R. flavipes) have been found to descend to 1 m underground [45], whereas Formosan subterranean termites (C. formosanus) and Eastern subterranean worker ants move progressively deeper into the ground as air temperatures decrease [46].
A recent study of R. speratus showed similar results. The king and queen stayed in their terrestrial habitat during the summer months. However, during the winter months, they moved to the underground royal chamber, where the temperature remained consistently high compared to the outside environment. The royal chamber, where the king and queen wintered, was located 15 to 37 cm below ground, and the inside temperature remained stable at 5 to 10 °C during January and February [42]. Due to their social nature, termites are not readily exposed to low temperatures that might lead to freezing.
As termites are well-adapted to cold climates, their distribution range is likely to expand with climate change. The longer termites are exposed to suitable temperature conditions, the more active they become, and as a result, they can forage more effectively [47]. The increase in winter minimum temperatures due to global warming is expected to increase the active period of forest insects including termites and expand their distribution range [48]. The daily mean temperature in South Korea in winter is exhibiting a sustained long-term trend characterized by increasing temperatures and a decrease in the number of cold days [49,50]. In particular, recent studies have confirmed a trend of a 2.1 °C increase in winter mean temperatures since the mid-1980s [51]. This increase in winter temperatures in South Korea appears to lead to an expansion in the activity range and period of termites.
This study confirmed that termites can inhabit almost all areas of South Korea currently and that most wooden architectural heritage buildings pose to potential threat to termite infestation. Termite damage is expected to increase further due to climate change and the introduction of invasive species. Therefore, proactive and preventive measures for termite control are needed to preserve the original wooden architectural heritage buildings.

Author Contributions

Conceptualization, S.K. and J.K.; methodology, S.K. and J.K.; software, S.K. and J.K.; validation, S.K. and J.K.; formal analysis, S.K. and J.K.; investigation, S.K. and J.K.; resources, S.K.; data curation, S.K. and J.K.; writing—original draft preparation, S.K.; writing—review and editing, S.K. and J.K.; visualization, S.K. and J.K.; supervision, J.K.; project administration, S.K.; funding acquisition, S.K. All authors have read and agreed to the published version of the manuscript.

Funding

This study was supported by the National Research Institute of Cultural Heritage (NRICH-2405-A62F-1).

Data Availability Statement

Data are available on request from the first author.

Acknowledgments

The authors are thankful for administrative support from the National Research Institute of Cultural Heritage.

Conflicts of Interest

The authors declare no conflicts of interest.

Appendix A

Table A1. Monthly mean temperature of wooden architectural heritage building sites in Korea in the last 20 years (2000–2019).
Table A1. Monthly mean temperature of wooden architectural heritage building sites in Korea in the last 20 years (2000–2019).
No.Name of Wooden Architectural Heritage Building SitesLatitudeLongitudeElevation (m)Monthly Mean Temperature (°C)Yearly Mean Temperature (°C)
JanFebMarAprMayJunJul.Aug.Sep.Oct.Nov.Dec.
1Geunjeongjeon Hall of Gyeongbokgung Palace37.5785 126.9770 26−3.1−0.25.211.717.722.024.525.320.914.66.8−0.912.0
2Guksadang Shrine of Inwangsan Mountain37.5927 126.9666 123−2.60.25.712.218.122.525.125.921.414.97.2−0.412.5
3Daeungjeon Hall of Jeondeungsa Temple, Ganghwa37.6320 126.4849 130−3.0−0.44.810.916.521.024.225.421.014.77.1−0.511.8
4Josadang Shrine of Silleuksa Temple, Yeoju37.2978 127.6614 40−4.1−0.95.011.717.922.425.225.620.213.15.5−2.011.6
5Paldalmun Gate, Suwon37.2777 127.0169 47−2.30.45.812.218.122.625.426.221.615.07.40.012.7
6Yeongsanjeon Hall of Seongnamsa Temple, Anseong36.9398 127.3069 224−4.5−1.44.310.716.420.723.523.818.611.84.7−2.410.5
7Ritual House at Geonwolleung Royal Tomb, Guri37.6242 127.1311 40−2.80.25.812.318.322.725.326.021.114.56.9−0.612.5
8Daeungbojeon Hall of Yongjusa Temple, Hwaseong37.2124 127.0050 51−2.50.25.612.017.922.325.326.121.414.77.2−0.212.5
9Eo Jae−yeon’s House, Icheon37.0454 127.5603 136−3.6−0.65.111.717.722.124.925.220.013.15.8−1.511.6
10Historic House of Maegok−ri, Yangju37.8945 126.9570 136−5.0−1.74.210.916.921.424.224.719.612.65.0−2.710.8
11Donggwandaek House, Namyangju37.6870 127.1582 57−4.2−1.14.611.117.121.624.324.920.013.25.6−2.011.3
12Main Gate of Imyeonggwan Guesthouse, Gangneung37.7793 128.8776 160.22.16.812.417.220.524.124.520.315.08.72.312.8
13Hoejeonmun Gate of Cheongpyeongsa Temple, Chuncheon37.9862 127.8091 306−7.5−4.51.28.013.818.021.221.215.79.22.3−5.07.8
14Jukseoru Pavilion, Samcheok37.4411 129.1606 100.62.46.712.116.920.123.724.419.815.09.02.912.8
15Shingled House and Folk Artifacts of Sin−ri, Samcheok37.3239 129.0140 361−8.5−5.6−0.16.713.016.720.319.714.78.21.1−5.96.7
16Geungnakbojeon Hall of Sinheungsa Temple, Sokcho38.1760 128.4843 231−5.0−2.72.38.814.517.821.121.316.411.24.3−2.78.9
17Jeongmyeolbogung Hall in Jungdae Peak of Odaesan Mountain, Pyeongchang37.7898 128.5562 1180−10.4−7.8−2.74.010.614.017.317.412.36.7−0.8−8.14.4
18Wanggok Village, Goseong38.3412 128.4987 20−1.30.75.411.216.219.723.223.819.114.07.61.111.7
19Palsangjeon Wooden Pagoda of Beopjusa Temple, Boeun36.5419 127.8330 352−5.8−3.22.39.014.819.422.623.117.910.83.6−3.59.2
20Hanbyeongnu Pavilion in Cheongpung, Jecheon37.0049 128.1717 196−3.2−0.55.011.817.622.024.825.220.013.46.3−0.911.8
21Daeungjeon Hall of Ansimsa Temple, Cheongju36.5526 127.4133 145−2.40.35.712.218.122.325.325.620.613.96.8−0.212.3
22Soseok House, Yeongdong36.2179 127.7127 103−2.50.25.612.017.722.125.225.420.213.36.3−0.412.1
23Yun Yang−gye’s House, Chungju37.0838 127.9204 75−4.1−1.04.811.617.822.525.425.720.112.85.3−1.911.6
24Kim Hang−muk’s House, Goesan36.7818 127.8594 130−3.7−0.84.811.417.221.624.624.919.612.55.4−1.711.3
25Jaenmal House, Eumseong37.0808 127.6576 137−3.9−0.94.811.517.521.924.825.119.812.75.4−1.811.4
26Jo Deok−su’s House, Danyang37.0033 128.3839 164−3.7−0.75.011.617.521.724.524.719.412.95.7−1.511.4
27Daeungjeon Hall of Sudeoksa Temple, Yesan36.6632 126.6227 151−2.8−0.64.510.816.721.024.224.920.113.76.6−0.411.5
28Daeungjeon Hall of Gaesimsa Temple, Seosan36.7469 126.5903 187−2.5−0.34.610.916.821.224.525.220.413.96.80.011.8
29Dongchundang Hall in Hoedeok, Daejeon36.3650 127.4415 85−2.00.65.912.318.122.325.225.620.714.17.00.112.5
30Geungnakjeon Hall of Muryangsa Temple, Buyeo36.3171 126.6932 156−5.8−3.42.08.915.019.322.922.516.910.13.3−3.59.0
31Saun House, Hongseong36.4981 126.7431 46−2.9−0.54.610.916.821.224.625.120.013.26.2−0.611.6
32Eungdodang Lecture Hall of Donamseowon Confucian Academy, Nonsan36.2089 127.1809 34−1.80.75.912.218.222.625.726.221.214.37.20.412.7
33Daegwangbojeon Hall of Magoksa Temple, Gongju36.5591 127.0122 113−3.8−1.23.910.516.421.124.524.919.612.55.4−1.611.0
34Jungakdan Shrine in Gyeryongsan Mountain, Gongju36.3354 127.1848 114−2.60.05.211.617.521.824.925.320.313.66.5−0.412.0
35Hong Sun−hyeong’s House, Sejong36.5340 127.3653 38−2.40.35.812.218.122.325.325.720.713.96.8−0.212.4
36Champandaek House in Oeam Village, Asan36.7303 127.0186 65−2.7−0.15.311.817.822.225.325.720.713.96.7−0.312.2
37Yi Ha−bok’s House, Seocheon36.0809 126.7594 17−1.01.15.511.317.221.725.226.021.314.98.21.512.7
38Upper Daeungjeon Hall of Janggoksa Temple, Cheongyang36.4175 126.8602 148−3.7−1.23.910.316.220.624.224.519.212.35.4−1.410.9
39Mireukjeon Hall of Geumsansa Temple, Gimje35.7231 127.0538 140−2.30.04.811.116.921.324.925.220.213.56.70.111.9
40Geungnakjeon Hall of Hwaamsa Temple, Wanju36.0661 127.2870 250−2.10.45.611.917.822.125.425.720.713.96.90.112.4
41Daeseongjeon Shrine of Jangsuhyanggyo Local Confucian School35.6485 127.5233 419−3.5−1.04.110.416.020.023.223.218.211.75.2−1.110.5
42Pihyangjeong Pavilion, Jeongeup35.6514 126.9431 16−1.11.25.811.918.022.526.026.321.414.78.01.313.0
43Gwanghallu Pavilion, Namwon35.4039 127.3798 84−1.41.16.012.117.922.325.425.620.914.17.20.712.7
44Daeungjeon Hall of Seonunsa Temple, Gochang35.4972 126.5782 20−1.20.65.211.016.520.824.525.020.214.07.61.212.1
45Daeungbojeon Hall of Naesosa Temple, Buan35.6176 126.5870 53−1.20.75.311.216.921.124.825.120.414.27.61.212.3
46Pungpaejigwan Guesthouse, Jeonju35.8180 127.1454 440.02.27.013.218.923.126.426.922.315.89.02.313.9
47Bogwangjeon Hall of Sungnimsa Temple, Iksan36.0816 126.9157 66−1.60.75.511.617.421.925.125.720.914.37.40.712.5
48Suseonru Pavilion, Jinan35.7460 127.3444 284−3.4−0.84.210.516.220.523.823.919.012.35.6−1.010.9
49Geungnakbojeon Hall of Muwisa Temple, Gangjin34.7387 126.6868 145−1.70.24.510.215.419.423.224.019.513.26.60.611.3
50Haetalmun Gate of Dogapsa Temple, Yeongam34.7527 126.6621 91−0.61.35.711.416.921.024.825.420.914.58.01.812.6
51Guksajeon Shrine of Songgwangsa Temple, Suncheon35.0019 127.2764 223−0.91.35.911.817.121.224.625.120.514.17.51.212.4
52Gakhwangjeon Hall of Hwaeomsa Temple, Gurye35.2571 127.4974 253−2.10.14.811.016.119.722.923.218.812.96.50.111.2
53Jinnamgwan Hall, Yeosu34.7418 127.7367 272.54.28.213.117.820.924.325.822.417.611.34.914.4
54Daeseongjeon Shrine of Najuhyanggyo Local Confucian School35.0333 126.7114 190.02.16.512.518.122.325.826.321.715.38.62.213.4
55Daeungjeon Hall of Bulgapsa Temple, Yeonggwang35.2007 126.5499 70−0.61.35.711.617.321.625.225.821.114.78.11.712.8
56Daeungjeon Hall of Mihwangsa Temple, Haenam34.3830 126.5779 2111.42.86.711.916.920.724.525.621.716.29.93.813.5
57Daeungjeon Hall of Neunggasa Temple, Goheung34.6391 127.4140 452.13.87.812.917.621.124.726.122.417.110.54.314.2
58Yang Jae−hyeong’s House, Hwasun34.9845 126.9116 39−0.12.06.512.418.022.225.826.321.615.18.42.113.4
59Jehojeong House, Gokseong35.3221 127.2213 67−0.91.56.412.418.022.425.625.921.114.47.61.213.0
60Historic House of Yureo−ri, Boseong34.8665 127.1670 133−0.61.55.911.817.021.224.925.520.914.37.51.412.6
61Jonjae House, Jangheung34.5495 126.9501 661.83.57.512.817.821.525.126.322.216.510.04.014.1
62Historic House of Yugyo−ri, Muan34.8472 126.4381 201.12.66.612.217.621.825.426.422.116.29.83.513.8
63Kim Whanki’s House, Sinan34.7528 126.1217 151.82.96.611.917.221.325.226.422.417.010.74.514.0
64Eungjinjeon Hall of Buryeongsa Temple, Uljin36.9410 129.2731 178−1.30.85.511.517.120.423.923.918.813.67.30.911.9
65Manhoe House, Bonghwa36.8972 128.7154 188−3.5−0.74.711.116.920.923.924.018.912.45.3−1.511.0
66Geungnakjeon Hall of Bongamsa Temple, Mungyeong36.7002 128.0064 269−6.2−3.71.88.214.018.121.321.616.610.13.2−3.88.4
67Muryangsujeon Hall of Buseoksa Temple, Yeongju36.9988 128.6875 486−4.8−2.22.89.214.918.621.821.816.710.84.2−2.69.3
68Museom Village, Yeongju36.7314 128.6214 118−3.3−0.45.111.517.221.324.424.519.312.75.4−1.311.4
69Seoseokji Garden, Yeongyang36.6118 129.0696 207−3.3−0.64.410.515.919.723.323.418.412.25.3−1.210.7
70Chunghyodang Head House, Yeongdeok36.5536 129.3654 360.02.16.512.017.020.424.024.519.814.68.42.112.6
71Jeongyodang Lecture Hall of Dosanseowon Confucian Academy, Andong36.7273 128.8435 177−3.5−0.74.710.916.720.824.024.219.012.45.2−1.511.0
72Yangjindang House in Hahoe, Andong36.5389 128.5169 77−2.50.35.912.318.222.425.325.520.213.46.0−0.712.2
73Daejangjeon Hall and Rotating Sutra Case of Yongmunsa Temple, Yecheon36.7315 128.3697 399−4.7−2.52.89.315.018.922.122.417.210.94.3−2.79.4
74Yangjindang House, Sangju36.3641 128.2291 61−1.80.76.212.518.222.225.025.220.113.56.60.012.4
75Manchwidang House, Uiseong36.4242 128.7622 160−3.1−0.35.211.517.221.324.624.819.512.85.5−1.211.5
76Bogwangjeon Hall of Daejeonsa Temple, Cheongsong36.3966 129.1459 237−4.3−1.63.59.915.419.022.723.117.811.44.5−2.29.9
77Daeungjeon Hall of Jikjisa Temple, Gimcheon36.1170 128.0045 202−3.1−0.74.610.816.119.822.723.018.212.45.7−1.110.7
78Yeongsanjeon Hall of Geojoam Hermitage of Eunhaesa Temple, Yeongcheon36.0201 128.7650 293−2.40.05.111.216.720.423.724.019.113.26.5−0.411.4
79Mucheomdang House in Yangdong, Gyeongju36.0019 129.2526 261.03.27.813.318.221.625.225.621.015.59.02.913.7
80Daeungjeon Hall of Bulguksa Temple, Gyeongju35.7901 129.3321 238−0.41.86.412.017.120.524.324.719.914.48.01.712.5
81Jeokgwangjeon Hall of Bogyeongsa Temple, Pohang36.2522 129.3178 94−2.10.04.610.615.919.423.123.318.212.76.30.011.0
82Daeungjeon Hall of Daedunsa Temple, Gumi36.3360 128.2421 211−1.70.96.412.718.422.525.325.520.213.76.70.112.6
83Ssangam House, Gumi36.1900 128.3844 33−1.80.96.412.718.422.525.425.620.413.76.60.012.6
84Daeungjeon Hall of Hwanseongsa Temple, Gyeongsan35.9363 128.7661 366−1.80.65.811.917.321.024.224.519.613.77.00.212.0
85Daeungjeon Hall of Daebisa Temple, Cheongdo35.6564 128.9362 182−1.41.16.112.017.221.024.624.819.913.76.90.512.2
86Hangae Village, Seongju35.9303 128.3278 63−1.01.77.113.218.722.725.726.021.014.67.50.913.2
87Taegojeong House, Dalseong35.9113 128.4166 56−0.42.27.613.619.223.126.126.321.415.08.01.513.6
88Daeungjeon Hall of Donghwasa Temple, Daegu35.9932 128.7043 496−3.5−1.14.010.215.619.022.222.517.812.35.8−1.210.3
89Janggyeongpanjeon Depositories of Haeinsa Temple, Hapcheon35.8016 128.0988 653−4.5−2.62.18.413.016.219.419.815.29.73.8−2.18.2
90Mugwa House, Hapcheon35.6792 128.1309 206−2.10.25.211.316.520.223.323.618.812.76.20.011.3
91Daeungjeon Hall and Ordination Platform of Tongdosa Temple, Yangsan35.4879 129.0638 163−1.70.65.511.316.520.224.024.019.013.16.60.311.6
92Yeongnamnu Pavilion, Miryang35.4916 128.7551 370.32.97.713.318.522.525.826.321.715.48.42.113.7
93Yaksajeon Hall of Gwallyongsa Temple, Changnyeong35.5317 128.5533 368−4.0−1.24.811.316.720.623.723.618.111.44.6−2.010.6
94Daeungjeon Hall of Yulgoksa Temple, Sancheong35.4164 127.9667 379−0.91.36.011.917.220.723.824.119.513.77.31.112.2
95Daeungjeon Hall of Ssanggyesa Temple, Hadong35.2326 127.6508 161−0.51.76.512.417.321.124.324.820.314.27.81.612.6
96Jinjuseong Fortress35.1903 128.0801 200.02.57.212.818.121.925.425.921.415.18.12.013.4
97Historic House of the Jinyang Ha Clan, Changnyeong35.5404 128.4961 67−0.81.97.213.118.722.926.126.421.414.97.61.013.4
98Ildu House, Hamyang35.5663 127.7686 173−1.01.26.112.217.621.624.825.020.013.67.11.012.4
99Donggye Head House, Geochang35.7551 127.8289 281−2.00.35.411.517.021.024.124.319.412.96.30.111.7
100Heo Sam−dul’s House, Hamyang35.6303 127.8109 198−1.40.95.912.017.421.424.524.719.813.46.90.712.2
101Mugiyeondang Garden, Haman35.2987 128.5390 530.12.77.613.218.422.225.726.321.615.48.31.913.6
102Daeungjeon Hall of Beomeosa Temple, Busan35.2840 129.0682 327−1.01.05.110.515.518.622.323.118.814.17.81.311.4
103Daeungjeon Hall of Jangansa Temple, Gijang35.3746 127.2330 100−1.21.26.012.117.822.125.325.620.914.27.41.012.7
104Merchant’s House in Seongeup Village, Jeju33.3869 126.8018 1214.45.58.813.417.720.825.026.122.517.612.06.615.0
Table A2. Days of termite activity in wooden architectural heritage building sites in Korea.
Table A2. Days of termite activity in wooden architectural heritage building sites in Korea.
No.Name of Wooden Architectural Heritage Building SitesMonthly Temperature in January (°C)Days of Termite Activity
(Days/Year)		Termite Damage on Wooden Heritage Buildings or Termite Colonies around BuildingsReference
1Geunjeongjeon Hall of Gyeongbokgung Palace−3.12121 *[52]
2Guksadang Shrine of Inwangsan Mountain−2.62161[52]
3Daeungjeon Hall of Jeondeungsa Temple, Ganghwa−3.02121[52]
4Josadang Shrine of Silleuksa Temple, Yeoju−4.12031[52]
5Paldalmun Gate, Suwon−2.32170[52]
6Yeongsanjeon Hall of Seongnamsa Temple, Anseong−4.51990[52]
7Ritual House at Geonwolleung Royal Tomb, Guri−2.82151[53]
8Daeungbojeon Hall of Yongjusa Temple, Hwaseong−2.52151[52]
9Eo Jae−yeon’s House, Icheon−3.62040[52]
10Historic House of Maegok−ri, Yangju−5.02000[52]
11Donggwandaek House, Namyangju−4.22021[52]
12Main Gate of Imyeonggwan Guesthouse, Gangneung0.22231[54]
13Hoejeonmun Gate of Cheongpyeongsa Temple, Chuncheon−7.51671[55]
14Jukseoru Pavilion, Samcheok0.62220[55]
15Shingled House and Folk Artifacts of Sin−ri, Samcheok−8.51651[54]
16Geungnakbojeon Hall of Sinheungsa Temple, Sokcho−5.01850[53]
17Jeongmyeolbogung Hall in Jungdae Peak of Odaesan Mountain, Pyeongchang−10.41380[53]
18Wanggok Village, Goseong−1.32151[55]
19Palsangjeon Wooden Pagoda of Beopjusa Temple, Boeun−5.81831[53]
20Hanbyeongnu Pavilion in Cheongpung, Jecheon−3.22060[53]
21Daeungjeon Hall of Ansimsa Temple, Cheongju−2.42140[53]
22Soseok House, Yeongdong−2.52071[53]
23Yun Yang−gye’s House, Chungju−4.12021[53]
24Kim Hang−muk’s House, Goesan−3.72021[53]
25Jaenmal House, Eumseong−3.92020[53]
26Jo Deok−su’s House, Danyang−3.72031[53]
27Daeungjeon Hall of Sudeoksa Temple, Yesan−2.82090[53]
28Daeungjeon Hall of Gaesimsa Temple, Seosan−2.52091[53]
29Dongchundang Hall in Hoedeok, Daejeon−2.02161[56]
30Geungnakjeon Hall of Muryangsa Temple, Buyeo−5.81751[53]
31Saun House, Hongseong−2.92051[53]
32Eungdodang Lecture Hall of Donamseowon Confucian Academy, Nonsan−1.82151[53]
33Daegwangbojeon Hall of Magoksa Temple, Gongju−3.81981[53]
34Jungakdan Shrine in Gyeryongsan Mountain, Gongju−2.62070[53]
35Hong Sun−hyeong’s House, Sejong−2.42141[53]
36Champandaek House in Oeam Village, Asan−2.72111[53]
37Yi Ha−bok’s House, Seocheon−1.02171[53]
38Upper Daeungjeon Hall of Janggoksa Temple, Cheongyang−3.71971[53]
39Mireukjeon Hall of Geumsansa Temple, Gimje−2.32081[57]
40Geungnakjeon Hall of Hwaamsa Temple, Wanju−2.12131[56]
41Daeseongjeon Shrine of Jangsuhyanggyo Local Confucian School−3.51941[56]
42Pihyangjeong Pavilion, Jeongeup−1.12171[56]
43Gwanghallu Pavilion, Namwon−1.42161[54]
44Daeungjeon Hall of Seonunsa Temple, Gochang−1.22121[58]
45Daeungbojeon Hall of Naesosa Temple, Buan−1.22121[56]
46Pungpaejigwan Guesthouse, Jeonju0.02271[56]
47Bogwangjeon Hall of Sungnimsa Temple, Iksan−1.62141[56]
48Suseonru Pavilion, Jinan−3.41981[54]
49Geungnakbojeon Hall of Muwisa Temple, Gangjin−1.71991[58]
50Haetalmun Gate of Dogapsa Temple, Yeongam−0.62161[56]
51Guksajeon Shrine of Songgwangsa Temple, Suncheon−0.92141[56]
52Gakhwangjeon Hall of Hwaeomsa Temple, Gurye−2.12071[58]
53Jinnamgwan Hall, Yeosu2.52361[52]
54Daeseongjeon Shrine of Najuhyanggyo Local Confucian School0.02261[58]
55Daeungjeon Hall of Bulgapsa Temple, Yeonggwang−0.62171[56]
56Daeungjeon Hall of Mihwangsa Temple, Haenam1.42221[56]
57Daeungjeon Hall of Neunggasa Temple, Goheung2.12301[56]
58Yang Jae−hyeong’s House, Hwasun−0.12250[56]
59Jehojeong House, Gokseong−0.92181[56]
60Historic House of Yureo-ri, Boseong−0.62141[56]
61Jonjae House, Jangheung1.82281[56]
62Historic House of Yugyo−ri, Muan1.12251[58]
63Kim Whanki’s House, Sinan1.82271[58]
64Eungjinjeon Hall of Buryeongsa Temple, Uljin−1.32120[52]
65Manhoe House, Bonghwa−3.52000[52]
66Geungnakjeon Hall of Bongamsa Temple, Mungyeong−6.21720[52]
67Muryangsujeon Hall of Buseoksa Temple, Yeongju−4.81881[52]
68Museom Village, Yeongju−3.32020[52]
69Seoseokji Garden, Yeongyang−3.31961[52]
70Chunghyodang Head House, Yeongdeok0.02190[52]
71Jeongyodang Lecture Hall of Dosanseowon Confucian Academy, Andong−3.52001[52]
72Yangjindang House in Hahoe, Andong−2.52081[52]
73Daejangjeon Hall and Rotating Sutra Case of Yongmunsa Temple, Yecheon−4.71911[52]
74Yangjindang House, Sangju−1.82131[52]
75Manchwidang House, Uiseong−3.12041[52]
76Bogwangjeon Hall of Daejeonsa Temple, Cheongsong−4.31931[52]
77Daeungjeon Hall of Jikjisa Temple, Gimcheon−3.11981[52]
78Yeongsanjeon Hall of Geojoam Hermitage of Eunhaesa Temple, Yeongcheon−2.42081[52]
79Mucheomdang House in Yangdong, Gyeongju1.02291[56]
80Daeungjeon Hall of Bulguksa Temple, Gyeongju−0.42191[54]
81Jeokgwangjeon Hall of Bogyeongsa Temple, Pohang−2.12000[52]
82Daeungjeon Hall of Daedunsa Temple, Gumi−1.72141[53]
83Ssangam House, Gumi−1.82140[52]
84Daeungjeon Hall of Hwanseongsa Temple, Gyeongsan−1.82141[52]
85Daeungjeon Hall of Daebisa Temple, Cheongdo−1.42121[58]
86Hangae Village, Seongju−1.02231[52]
87Taegojeong House, Dalseong−0.42271[53]
88Daeungjeon Hall of Donghwasa Temple, Daegu−3.51950[53]
89Janggyeongpanjeon Depositories of Haeinsa Temple, Hapcheon−4.51671[52]
90Mugwa House, Hapcheon−2.12041[52]
91Daeungjeon Hall and Ordination Platform of Tongdosa Temple, Yangsan−1.72061[58]
92Yeongnamnu Pavilion, Miryang0.32271[54]
93Yaksajeon Hall of Gwallyongsa Temple, Changnyeong−4.01991[52]
94Daeungjeon Hall of Yulgoksa Temple, Sancheong−0.92161[54]
95Daeungjeon Hall of Ssanggyesa Temple, Hadong−0.52201[52]
96Jinjuseong Fortress0.02251[58]
97Historic House of the Jinyang Ha Clan, Changnyeong−0.82230[52]
98Ildu House, Hamyang−1.02151[52]
99Donggye Head House, Geochang−2.02061[52]
100Heo Sam−dul’s House, Hamyang−1.42131[52]
101Mugiyeondang Garden, Haman0.12271[52]
102Daeungjeon Hall of Beomeosa Temple, Busan−1.02081[53]
103Daeungjeon Hall of Jangansa Temple, Gijang−1.22161[53]
104Merchant’s House in Seongeup Village, Jeju4.42491[56]
* 1 = termite damage, 0 = no damage.

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Figure 1. Location of research subjects (104 Wooden Architectural Heritage Buildings in South Korea).
Figure 1. Location of research subjects (104 Wooden Architectural Heritage Buildings in South Korea).
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Figure 2. Range of monthly mean temperature (MMT) in January over the last 20 years (2000–2019) and termite damage records of wooden architectural heritage buildings.
Figure 2. Range of monthly mean temperature (MMT) in January over the last 20 years (2000–2019) and termite damage records of wooden architectural heritage buildings.
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Figure 3. Location of state-designated wooden architectural heritage buildings in South Korea and potential range of termite damage.
Figure 3. Location of state-designated wooden architectural heritage buildings in South Korea and potential range of termite damage.
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Table 1. Distribution of termite (Blattodea: Isoptera) species in South Korea.
Table 1. Distribution of termite (Blattodea: Isoptera) species in South Korea.
FamilyGenusSpeciesReference
RhinotermitidaeReticulitermesR. speratus[14,15,16]
R. kanmonensis[17]
KalotermitidaeGlyptotermesG. nakajimai[18]
IncisitermesI. minor[19]
Table 2. Monthly mean temperature of major wooden architectural heritage buildings by region using MK-PRISM data (Unit: °C).
Table 2. Monthly mean temperature of major wooden architectural heritage buildings by region using MK-PRISM data (Unit: °C).
Site *LatitudeAltitude (m)T.
Jan.
(°C)		T.
Feb.
(°C)		T.
Mar.
(°C)		T.
Apr.
(°C)		T.
May
(°C)		T.
Jun.
(°C)		T.
Jul.
(°C)		T.
Aug.
(°C)		T.
Sep.
(°C)		T.
Oct.
(°C)		T.
Nov.
(°C)		T.
Dec.
(°C)		T.
Annual
Mean
(°C)
137.434792−3.4−0.45.311.817.622.024.825.320.813.66.0−1.411.8
237.7181231−4.5−2.22.99.214.718.221.621.717.111.24.4−2.49.3
337.1001249−3.7−0.75.011.617.421.824.824.820.012.55.3−1.711.4
436.435891−2.8−0.35.011.417.221.624.825.020.313.16.1−0.711.7
535.7899133−1.80.65.611.717.421.725.125.120.713.66.90.412.2
634.8473650.22.16.512.217.421.424.925.521.515.18.52.313.1
736.0016187−2.40.25.411.617.020.824.124.019.412.86.0−0.611.5
835.4382193−1.41.06.112.017.221.024.324.320.013.46.70.512.1
935.43821934.45.68.913.517.820.925.126.022.617.411.86.415.0
Nationwide36.1935160−2.20.35.511.617.121.124.424.620.113.36.5−0.111.8
* 1 (Seoul, Incheon, Gyeonggi-do), 2 (Gangwon-do), 3 (Chungcheongbuk-do), 4 (Daejeon, Sejong, Chungcheongnam-do), 5 (Jeollabuk-do), 6 (Jeollanam-do), 7 (Daegu, Gyeongsangbuk-do), 8 (Busan, Gyeongsangnam-do), and 9 (Jeju-do).
Table 3. Wooden architectural heritage buildings in Korea with a monthly mean temperature of −4 °C or less in January.
Table 3. Wooden architectural heritage buildings in Korea with a monthly mean temperature of −4 °C or less in January.
Name of Wooden Architectural Heritage BuildingsLatitudeAltitude (m)Average Monthly Temperature in January (°C)Termite Damage to the Heritage or Surrounding BuildingsSurvey Year
Jeokmyeolbogung Hall of Jungdae Terrace in Odaesan Mountain, Pyeongchang37.789817 1180−10.40 *2019
House with an Oak Bark Roof in Daei-ri, Samcheok37.323864 361−8.512021
Hoejeonmun Gate of Cheongpyeongsa Temple, Chuncheon37.986167 306−7.512016
Geungnakjeon Hall of Bongamsa Temple, Mungyeong36.700161 269−6.202017
Palsangjeon Wooden Pagoda of Beopjusa Temple, Boeun36.541872 352−5.812019
Geungnakjeon Hall of Muryangsa Temple, Buyeo36.317142 156−5.812018
Geungnakbojeon Hall of Sinheungsa Temple, Sokcho38.175994 231−5.002019
Historic House of Maegok−ri, Yangju37.894536 136−5.002018
Muryangsujeon Hall of Buseoksa Temple, Yeongju36.998797 486−4.812017
Daejangjeon Hall and Rotating Sutra Case of Yongmunsa Temple, Yecheon36.731458 399−4.712017
Janggyeongpanjeon Depositories of Haeinsa Temple, Hapcheon35.801608 653−4.512017
Yeongsanjeon Hall of Seongnamsa Temple, Anseong36.939839 224−4.502018
Bogwangjeon Hall of Daejeonsa Temple, Cheongsong36.396639 237−4.312017
Donggwandaek House, Namyangju37.687000 57−4.212018
Josadang Shrine of Silleuksa Temple, Yeoju37.297767 40−4.112018
Yun Yang−gye’s House, Chungju37.083758 75−4.112018
Yaksajeon Hall of Gwallyongsa Temple, Changnyeong35.531733 368−4.012017
* 1 = termite damage, 0 = no damage.
Table 4. Distribution of the number of days available for termite activity at major wooden architectural heritage buildings in South Korea.
Table 4. Distribution of the number of days available for termite activity at major wooden architectural heritage buildings in South Korea.
M ± SDMinimum25th PercentileMedian75th PercentileMaximum
Number of days available for termite activity (d)209 ± 15.9138202212217249
Table 5. Number of days available for termite activity at wooden architectural heritage building sites by region.
Table 5. Number of days available for termite activity at wooden architectural heritage building sites by region.
Loc. *123456789Nationwide
Number of days available for termite activity **209188202207210220206211249209
* 1 (Seoul, Incheon, Gyeonggi-do), 2 (Gangwon-do), 3 (Chungcheongbuk-do), 4 (Daejeon, Sejong, Chungcheongnam−do), 5 (Jeollabuk-do), 6 (Jeollanam-do), 7 (Daegu, Gyeongsangbuk-do), 8 (Busan, Gyeongsangnam-do), 9 (Jeju-do). ** The period that termite can damage to wooden buildings above ground.
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Kim, S.; Kim, J. Estimation of the Damage Risk Range and Activity Period of Termites (Reticulitermes speratus) in Korean Wooden Architectural Heritage Building Sites. Forests 2024, 15, 602. https://doi.org/10.3390/f15040602

AMA Style

Kim S, Kim J. Estimation of the Damage Risk Range and Activity Period of Termites (Reticulitermes speratus) in Korean Wooden Architectural Heritage Building Sites. Forests. 2024; 15(4):602. https://doi.org/10.3390/f15040602

Chicago/Turabian Style

Kim, Sihyun, and Jisoo Kim. 2024. "Estimation of the Damage Risk Range and Activity Period of Termites (Reticulitermes speratus) in Korean Wooden Architectural Heritage Building Sites" Forests 15, no. 4: 602. https://doi.org/10.3390/f15040602

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