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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 林裕彬 | zh_TW |
dc.contributor.advisor | Yu-Pin Lin | en |
dc.contributor.author | 周禹辰 | zh_TW |
dc.contributor.author | Yu-Chen Chou | en |
dc.date.accessioned | 2023-09-22T17:09:04Z | - |
dc.date.available | 2023-11-09 | - |
dc.date.copyright | 2023-09-22 | - |
dc.date.issued | 2023 | - |
dc.date.submitted | 2023-08-14 | - |
dc.identifier.citation | Andrews, K. M., & Gibbons, J. W. (2005). How do highways influence snake movement? Behavioral responses to roads and vehicles. Copeia, 2005(4), 772-782.
Aresco, M. J. (2005). Mitigation measures to reduce highway mortality of turtles and other herpetofauna at a north Florida lake. The Journal of Wildlife Management, 69(2), 549-560. Arnold, E. M. (2016). Spatial, Roadway, and Biotic Factors Associated with Barn Owl (Tyto alba) Mortality and Characteristics of Mortality Hotspots Along Interstates 84 and 86 in Idaho. Ashley, E. P., & Robinson, J. T. (1996). Road mortality of amphibians, reptiles and other wildlife on the Long Point Causeway, Lake Erie, Ontario. Canadian Field Naturalist, 110(3), 403-412. Bailey T. C. & Gatrell A. C. (1995). Interactive spatial data analysis. Longman Scientific & Technical : J. Wiley. Barrientos, R., & Bolonio, L. (2009). The presence of rabbits adjacent to roads increases polecat road mortality. Biodiversity and Conservation, 18, 405-418. Bartonicka, T., Andrasik, R., Dula, M., Sedonik, J., & Bil, M. (2018). Identification of local factors causing clustering of animal‐vehicle collisions. The Journal of Wildlife Management, 82(5), 940-947. Beebee, T. J. (2013). Effects of road mortality and mitigation measures on amphibian populations. Conservation Biology, 27(4), 657-668. Beckmann, C., & Shine, R. (2015). Do the numbers and locations of road‐killed anuran carcasses accurately reflect impacts of vehicular traffic?. The Journal of Wildlife Management, 79(1), 92-101. Bernardino Jr, F. S., & Dalrymple, G. H. (1992). Seasonal activity and road mortality of the snakes of the Pa-hay-okee wetlands of Everglades National Park, USA. Biological Conservation, 62(2), 71-75. Blaustein, A. R., Wake, D. B., & Sousa, W. P. (1994). Amphibian declines: judging stability, persistence, and susceptibility of populations to local and global extinctions. Conservation biology, 8(1), 60-71. Bohm, M., Collen, B., Baillie, J. E., Bowles, P., Chanson, J., Cox, N., ... & Mateo, J. A. (2013). The conservation status of the world’s reptiles. Biological conservation, 157, 372-385. Bivand, R. S., & Wong, D. W. (2018). Comparing implementations of global and local indicators of spatial association. Test, 27(3), 716-748 Bil, M., Andrasik, R., Bartonicka, T., Krivankova, Z., & Sedonik, J. (2018). An evaluation of odor repellent effectiveness in prevention of wildlife-vehicle collisions. Journal of environmental management, 205, 209-214. Bil, M., Andrasik, R., Dula, M., & Sedonik, J. (2019). On reliable identification of factors influencing wildlife-vehicle collisions along roads. Journal of environmental management, 237, 297-304. Bil, M., Andrasik, R., & Janoska, Z. (2013). Identification of hazardous road locations of traffic accidents by means of kernel density estimation and cluster significance evaluation. Accident Analysis & Prevention, 55, 265-273. Bil, M., Andrasik, R., Svoboda, T., & Sedonik, J. (2016). The KDE+ software: a tool for effective identification and ranking of animal-vehicle collision hotspots along networks. Landscape ecology, 31, 231-237. Cai, X., Wu, Z., & Cheng, J. (2013). Using kernel density estimation to assess the spatial pattern of road density and its impact on landscape fragmentation. International Journal of Geographical Information Science, 27(2), 222-230. Chainey, S. P. (2013). Examining the influence of cell size and bandwidth size on kernel density estimation crime hotspot maps for predicting spatial patterns of crime. Bulletin of the Geographical Society of Liege, 60, 7-19. Chainey, S., Tompson, L., & Uhlig, S. (2008). The utility of hotspot mapping for predicting spatial patterns of crime. Security journal, 21, 4-28. Clarke, G. P., White, P. C., & Harris, S. (1998). Effects of roads on badger Meles meles populations in south-west England. Biological conservation, 86(2), 117-124. Clevenger, A. P., Chruszcz, B., & Gunson, K. E. (2003). Spatial patterns and factors influencing small vertebrate fauna road-kill aggregations. Biological conservation, 109(1), 15-26. Coffin, A. W. (2007). From roadkill to road ecology: a review of the ecological effects of roads. Journal of transport Geography, 15(5), 396-406. Collinson, W. J., Parker, D. M., Bernard, R. T., Reilly, B. K., & Davies‐Mostert, H. T. (2014). Wildlife road traffic accidents: a standardized protocol for counting flattened fauna. Ecology and evolution, 4(15), 3060-3071. Cramer, P. C., & Bissonette, J. A. (2005). Wildlife crossings in North America: the state of the science and practice. Crosby, J. (2014). Amphibian occurrence on South Okanagan roadways: investigating movement patterns, crossing hotspots, and roadkill mitigation structure use at the landscape scale (Master's thesis, University of Waterloo). D'Amico, M., Roman, J., De los Reyes, L., & Revilla, E. (2015). Vertebrate road-kill patterns in Mediterranean habitats: who, when and where. Biological Conservation, 191, 234-242. Delgado, J. D., Arroyo, N. L., Arevalo, J. R., & Fernandez-Palacios, J. M. (2007). Edge effects of roads on temperature, light, canopy cover, and canopy height in laurel and pine forests (Tenerife, Canary Islands). Landscape and Urban planning, 81(4), 328-340. Eigenbrod, F., Hecnar, S. J., & Fahrig, L. (2009). Quantifying the road-effect zone: threshold effects of a motorway on anuran populations in Ontario, Canada. Ecology and Society, 14(1). Enge, K. M., & Wood, K. N. (2002). A pedestrian road survey of an upland snake community in Florida. Southeastern Naturalist, 1(4), 365-380. Erritzoe, J., Mazgajski, T. D., & Rejt, Ł. (2003). Bird casualties on European roads—a review. Acta Ornithologica, 38(2), 77-93. Fahrig, L. (2003). Effects of habitat fragmentation on biodiversity. Annual review of ecology, evolution, and systematics, 34(1), 487-515. Fahrig, L., Pedlar, J. H., Pope, S. E., Taylor, P. D., & Wegner, J. F. (1995). Effect of road traffic on amphibian density. Biological conservation, 73(3), 177-182. Favilli, F., Bil, M., Sedonik, J., Andrasik, R., Kasal, P., Agreiter, A., & Streifeneder, T. (2018). Application of KDE+ software to identify collective risk hotspots of ungulate-vehicle collisions in South Tyrol, Northern Italy. European Journal of Wildlife Research, 64, 1-12. Findlay, C. S., & Bourdages, J. (2000). Response time of wetland biodiversity to road construction on adjacent lands. Conservation Biology, 14(1), 86-94. Forman, R. T. (2003). Road ecology: science and solutions. Island press. Forman, R. T., & Alexander, L. E. (1998). Roads and their major ecological effects. Annual review of ecology and systematics, 29(1), 207-231. Gatrell, A. C., Bailey, T. C., Diggle, P. J., & Rowlingson, B. S. (1996). Spatial point pattern analysis and its application in geographical epidemiology. Transactions of the Institute of British geographers, 256-274. Garriga, N., Santos, X., Montori, A., Richter-Boix, A., Franch, M., & Llorente, G. A. (2012). Are protected areas truly protected? The impact of road traffic on vertebrate fauna. Biodiversity and Conservation, 21, 2761-2774. Gibbons, J. W., Scott, D. E., Ryan, T. J., Buhlmann, K. A., Tuberville, T. D., Metts, B. S., ... & Winne, C. T. (2000). The Global Decline of Reptiles, Deja Vu Amphibians: Reptile species are declining on a global scale. Six significant threats to reptile populations are habitat loss and degradation, introduced invasive species, environmental pollution, disease, unsustainable use, and global climate change. BioScience, 50(8), 653-666. Gibbs, J. P., & Shriver, W. G. (2005). Can road mortality limit populations of pool-breeding amphibians?. Wetlands Ecology and Management, 13, 281-289. Glista, D. J., DeVault, T. L., & DeWoody, J. A. (2008). Vertebrate road mortality predominantly impacts amphibians. Herpetological conservation and Biology, 3(1), 77-87. Glista, D. J., DeVault, T. L., & DeWoody, J. A. (2009). A review of mitigation measures for reducing wildlife mortality on roadways. Landscape and urban planning, 91(1), 1-7. Galantinho, A., Eufrazio, S., Silva, C., Carvalho, F., Alpizar-Jara, R., & Mira, A. (2017). Road effects on demographic traits of small mammal populations. European Journal of Wildlife Research, 63, 1-13. Gomes, L., Grilo, C., Silva, C., & Mira, A. (2009). Identification methods and deterministic factors of owl roadkill hotspot locations in Mediterranean landscapes. Ecological research, 24, 355-370. Grant, R. A., Chadwick, E. A., & Halliday, T. (2009). The lunar cycle: a cue for amphibian reproductive phenology?. Animal Behaviour, 78(2), 349-357. Grilo, C., Bissonette, J. A., & Santos-Reis, M. (2009). Spatial–temporal patterns in Mediterranean carnivore road casualties: consequences for mitigation. Biological conservation, 142(2), 301-313.. Harper, E. B., Rittenhouse, T. A., & Semlitsch, R. D. (2008). Demographic consequences of terrestrial habitat loss for pool‐breeding amphibians: predicting extinction risks associated with inadequate size of buffer zones. Conservation Biology, 22(5), 1205-1215. Hastings, W. K. (1970). Monte Carlo sampling methods using Markov chains and their applications. Hell, P., Plavy, R., Slamecka, J., & Gasparik, J. (2005). Losses of mammals (Mammalia) and birds (Aves) on roads in the Slovak part of the Danube Basin. European Journal of Wildlife Research, 51, 35-40. Hels, T., & Buchwald, E. (2001). The effect of road kills on amphibian populations. Biological conservation, 99(3), 331-340. Hernandez, M. A. U. R. O. (1988). Owl (Athene noctua) in Spain. Journal of Raptor Research, 22(3), 81-84. Hosmer Jr, D. W., Lemeshow, S., & Sturdivant, R. X. (2013). Applied logistic regression (Vol. 398). John Wiley & Sons. Iosif, R., Rozylowicz, L., & Popescu, V. D. (2013). Modeling road mortality hotspots of Eastern Hermann’s tortoise in Romania. Amphibia-Reptilia, 34(2), 163-172. Jackson, S. D., & Griffin, C. R. (1996, April). Underpass systems for amphibians. In Trends in Addressing Transportation Related Wildlife Mortality, proceedings of the transportation related wildlife mortality seminar (pp. 224-227). Tallahassee: Florida Department of Transportation. Jackson, S. D. (2003). Proposed design and considerations for use of amphibian and reptile tunnels in New England. University of Massachusetts Report. Jacobson, S. L., Bliss‐Ketchum, L. L., de Rivera, C. E., & Smith, W. P. (2016). A behavior‐based framework for assessing barrier effects to wildlife from vehicle traffic volume. Ecosphere, 7(4), e01345. Jaeger, J. A., & Fahrig, L. (2004). Effects of road fencing on population persistence. Conservation biology, 18(6), 1651-1657. Jochimsen, D. M., Peterson, C. R., Andrews, K. M., Gibbons, J. W., & Drawer, E. (2004). A literature review of the effects of roads on amphibians and reptiles and the measures used to minimize those effects. Idaho Fish and Game Department, USDA Forest Service. Kumara, H. N., Sharma, A. K., Kumar, A., & Singh, M. (2000). Roadkills of wild fauna in Indira Gandhi wildlife sanctuary, Western Ghats, India: implications for management. Biosphere conservation: for nature, wildlife, and humans, 3(1), 41-47 Krempin, D. W., & Sullivan, C. W. (1981). The seasonal abundance, vertical distribution, and relative microbial biomass of chroococcoid cyanobacteria at a station in southern California coastal waters. Canadian journal of microbiology, 27(12), 1341-1344. Krisp, J. M., & Durot, S. (2007). Segmentation of lines based on point densities—An optimisation of wildlife warning sign placement in southern Finland. Accident Analysis & Prevention, 39(1), 38-46. Langen, T. A., Ogden, K. M., & Schwarting, L. L. (2009). Predicting hot spots of herpetofauna road mortality along highway networks. The Journal of Wildlife Management, 73(1), 104-114. Laurance, W. F., & Balmford, A. (2013). A global map for road building. Nature, 495(7441), 308-309. Laurance, W. F., Goosem, M., & Laurance, S. G. (2009). Impacts of roads and linear clearings on tropical forests. Trends in ecology & evolution, 24(12), 659-669. Lesbarreres, D., Lode, T., & Merila, J. (2004). What type of amphibian tunnel could reduce road kills?. Oryx, 38(2), 220-223. Levine, N., & Kim, K. E. (1998). The location of motor vehicle crashes in Honolulu: a methodology for geocoding intersections. Computers, environment and urban systems, 22(6), 557-576. Lin, Y. P., Chu, H. J., Wu, C. F., Chang, T. K., & Chen, C. Y. (2011). Hotspot analysis of spatial environmental pollutants using kernel density estimation and geostatistical techniques. International journal of environmental research and public health, 8(1), 75-88. Lode, T. (2000). Effect of a motorway on mortality and isolation of wildlife populations. AMBIO: A Journal of the Human Environment, 29(3), 163-166. Longcore, T., & Rich, C. (2004). Ecological light pollution. Frontiers in Ecology and the Environment, 2(4), 191-198. Malo, J. E., Suarez, F., & Diez, A. (2004). Can we mitigate animal–vehicle accidents using predictive models?. Journal of applied ecology, 41(4), 701-710. Marsh, D. M., Page, R. B., Hanlon, T. J., Corritone, R., Little, E. C., Seifert, D. E., & Cabe, P. R. (2008). Effects of roads on patterns of genetic differentiation in red-backed salamanders, Plethodon cinereus. Conservation Genetics, 9, 603-613. Marsh, D. M., Milam, G. S., Gorham, N. P., & Beckman, N. G. (2005). Forest roads as partial barriers to terrestrial salamander movement. Conservation biology, 19(6), 2004-2008. Marsh, D. M., & Trenham, P. C. (2001). Metapopulation dynamics and amphibian conservation. Conservation biology, 15(1), 40-49. Maschio, G. F., Santos-Costa, M. C., & Prudente, A. L. (2016). Road-kills of snakes in a tropical rainforest in the Central Amazon Basin, Brazil. South American Journal of Herpetology, 11(1), 46-53. Mazerolle, M. J. (2004). Amphibian road mortality in response to nightly variations in traffic intensity. Herpetologica, 60(1), 45-53. McLafferty, S., Williamson, D., & McGuire, P. G. (2000). Identifying crime hot spots using kernel smoothing. V Goldsmith PO McGuire, JH Mollenkopf and TA Ross Crime Mapping and the Training needs of Law Enforcement, 127. Meekan, M. G., Duarte, C. M., Fernandez-Gracia, J., Thums, M., Sequeira, A. M., Harcourt, R., & Eguíluz, V. M. (2017). The ecology of human mobility. Trends in ecology & evolution, 32(3), 198-210. Metropolis, N., Rosenbluth, A. W., Rosenbluth, M. N., Teller, A. H., & Teller, E. (1953). Equation of state calculations by fast computing machines. The journal of chemical physics, 21(6), 1087-1092. Mimet, A., Clauzel, C., & Foltete, J. C. (2016). Locating wildlife crossings for multispecies connectivity across linear infrastructures. Landscape Ecology, 31, 1955-1973. Mougey, T. (1996). Des tunnels pour les batraciens. COURRIER DE LA NATURE-PARIS-, 22-28. Mountrakis, G., & Gunson, K. (2009). Multi‐scale spatiotemporal analyses of moose–vehicle collisions: a case study in northern Vermont. International Journal of Geographical Information Science, 23(11), 1389-1412. Nielsen, S. E., Herrero, S., Boyce, M. S., Mace, R. D., Benn, B., Gibeau, M. L., & Jevons, S. (2004). Modelling the spatial distribution of human-caused grizzly bear mortalities in the Central Rockies ecosystem of Canada. Biological Conservation, 120(1), 101-113. Olson, D. D., Bissonette, J. A., Cramer, P. C., Green, A. D., Davis, S. T., Jackson, P. J., & Coster, D. C. (2014). Monitoring wildlife-vehicle collisions in the information age: how smartphones can improve data collection. PloS one, 9(6), e98613. Pechmann, J. H., Scott, D. E., Whitfield Gibbons, J., & Semlitsch, R. D. (1989). Influence of wetland hydroperiod on diversity and abundance of metamorphosing juvenile amphibians. Wetlands ecology and Management, 1, 3-11. Periquet, S., Roxburgh, L., Le Roux, A., & Collinson, W. J. (2018). Testing the value of citizen science for roadkill studies: A case study from South Africa. Frontiers in Ecology and Evolution, 6, 15. Pinowski, J. (2005). Roadkills of vertebrates in Venezuela. Revista Brasileira de Zoologia, 22, 191-196. Puky, M. (2003). Amphibian mitigation measures in Central-Europe. Ramp, D., Caldwell, J., Edwards, K. A., Warton, D., & Croft, D. B. (2005). Modelling of wildlife fatality hotspots along the snowy mountain highway in New South Wales, Australia. Biological conservation, 126(4), 474-490. Ramp, D., Wilson, V. K., & Croft, D. B. (2006). Assessing the impacts of roads in peri-urban reserves: road-based fatalities and road usage by wildlife in the Royal National Park, New South Wales, Australia. Biological Conservation, 129(3), 348-359. Series, B. C. R. S. (2008). Recovery strategy for the Great Basin spadefoot (Spea intermontana) in British Columbia. Rich, C., & Longcore, T. (Eds.). (2013). Ecological consequences of artificial night lighting. Island Press. Rytwinski, T., Soanes, K., Jaeger, J. A., Fahrig, L., Findlay, C. S., Houlahan, J., ... & van der Grift, E. A. (2016). How effective is road mitigation at reducing road-kill? A meta-analysis. PLoS one, 11(11), e0166941. Santos, R. A. L., Santos, S. M., Santos-Reis, M., Picanço de Figueiredo, A., Bager, A., Aguiar, L. M., & Ascensao, F. (2016). Carcass persistence and detectability: reducing the uncertainty surrounding wildlife-vehicle collision surveys. PloS one, 11(11), e0165608. Secco, H., Ratton, P., Castro, E., Da Lucas, P. S., & Bager, A. (2014). Intentional snake road-kill: a case study using fake snakes on a Brazilian road. Tropical Conservation Science, 7(3), 561-571. Seo, C., Thorne, J. H., Choi, T., Kwon, H., & Park, C. H. (2015). Disentangling roadkill: the influence of landscape and season on cumulative vertebrate mortality in South Korea. Landscape and ecological engineering, 11, 87-99. Sjolund, M. (2016). Road and landscape features affecting the aggregation of ungulate vehicle collisions in southern Sweden. Spellerberg, I. A. N. (1998). Ecological effects of roads and traffic: a literature review. Global Ecology & Biogeography Letters, 7(5), 317-333. Teixeira, F. Z., Coelho, A. V. P., Esperandio, I. B., & Kindel, A. (2013). Vertebrate road mortality estimates: effects of sampling methods and carcass removal. Biological Conservation, 157, 317-323. Trombulak, S. C., & Frissell, C. A. (2000). Review of ecological effects of roads on terrestrial and aquatic communities. Conservation biology, 14(1), 18-30. van der Grift, E. A., & Pouwels, R. (2006). Restoring habitat connectivity across transport corridors: identifying high-priority locations for de-fragmentation with the use of an expert-based model. In The ecology of transportation: managing mobility for the environment (pp. 205-231). Dordrecht: Springer Netherlands Van Der Ree, R., Smith, D. J., & Grilo, C. (2015). The ecological effects of linear infrastructure and traffic: challenges and opportunities of rapid global growth. Handbook of road ecology, 1-9. van Langevelde, F., & Jaarsma, C. F. (2005). Using traffic flow theory to model traffic mortality in mammals. Landscape ecology, 19, 895-907. Woltz, H. W., Gibbs, J. P., & Ducey, P. K. (2008). Road crossing structures for amphibians and reptiles: informing design through behavioral analysis. Biological conservation, 141(11), 2745-2750. Wood, A. G., Naef‐Daenzer, B., Prince, P. A., & Croxall, J. P. (2000). Quantifying habitat use in satellite‐tracked pelagic seabirds: application of kernel estimation to albatross locations. Journal of avian biology, 31(3), 278-286. Worton, B. J. (1987). A review of models of home range for animal movement. Ecological modelling, 38(3-4), 277-298. Worton, B. J. (1989). Kernel methods for estimating the utilization distribution in home‐range studies. Ecology, 70(1), 164-168. 朱哲民 (1996)。臺灣北部溪流蛙類群聚之研究。 林世強 (2009)。金門動物車禍調查與分析。國家公園學報,31-46。 徐宗廷 (2019)。地景結構與路殺熱點之研究 - 以土城區大安里及三峽區有木里為例。 陳冠儒、鄭瑞富與許金寶 (2014)。淺談道路建設對環境及野生動物之影響。自然保育季刊,(86),28-37。 黃榮千 (2007)。太魯閣國家公園砂卡礑溪流域斯文豪氏赤蛙族群生態研究。 侯文祥與張源修 (2005)。季節變化對台灣七種蛙類利用水岸邊坡之活動力影響研究。農業工程學報,51(4),54-68。 張源修與吳秉諭 (2014)。臺灣十一種蛙類之行為能力比較之研究。農業工程學報,60(2),1-9。 | - |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/90036 | - |
dc.description.abstract | 隨著人類社會與經濟的發展、都市化進程加速,道路的建設和擴張與日俱增。然而,道路的建設會切割原有的自然地景,對野生動物的棲息地產生負面影響,包括棲息地的破碎化、外來物種沿著道路入侵、人類活動干擾和車輛碰撞等,這些現象對野生動物族群的存續和生物多樣性造成威脅。而在這些影響中,野生動物與車輛的碰撞是對生態系統影響最直接且顯著的,尤其兩棲爬蟲動物因其生活史特性、體型較小等原因,使其更容易受到路殺事件的影響。
許多研究指出,道路環境、交通流量和氣候條件等因素對兩棲爬蟲動物的路殺風險有顯著影響。路殺事件不僅會對生物個體造成威脅,還可能對整個生態系統產生負面效應,甚至導致物種滅絕。為了降低道路對野生動物的影響,研究人員和相關團體已開始尋求有效的保護措施。 本研究旨在探討影響淺山道路兩棲爬蟲動物路殺熱點分佈的主要因素。本研究選擇新北市土城區的承天路與龍泉路作為研究區域,這些地區擁有豐富的兩棲爬蟲動物資源。延續前人與新北市農業局合作的調查計劃,本研究進行了為期一年的現地調查和數據收集。通過統計和分析所收集的數據,本研究試圖找出影響路殺熱點分佈的主要因素,並提出相應的保護建議,減輕路殺對野生動物的負面影響。 研究結果顯示,新北市土城區承天路與龍泉路的路殺物種以兩棲類大宗,爬蟲類次之,其路殺高峰期為春夏兩季。本研究以核密度估計來判斷路殺熱點位置分佈,並使用羅吉斯回歸分析來找出哪些影響因子對於路殺熱點的產生有較高影響力與解釋力。本研究發現路殺熱點的形成與道路兩側之明渠排水溝分佈、道路受植物遮蔽邊界情形、植生邊坡分佈、漿砌卵石擋土牆分佈以及道路坡度有一定的關聯性。同時本研究將路殺熱點之分佈與歷史資料做比對,發現熱點位置與過往分佈區域有所出入,影響原因為新北市農業局有針對過往之路殺熱點區域進行路殺改善工程,其工程結果有效的降低了路殺事件的發生。 本研究之調查資料及分析結果可以提供未來擁有類似道路條件之路段進行參考,作為路殺調查之監測基礎以及路殺改善工程之參酌。但因本調查之時間尺度僅有一個年度,若需要更詳盡的調查資料,則需要更深入且為期更長的調查。 | zh_TW |
dc.description.abstract | With the development of human society and economy, along with the acceleration of urbanization, the construction and expansion of roads have been increasing rapidly. However, road construction often results in the fragmentation of natural landscapes, negatively impacting wildlife habitats. This includes habitat fragmentation, the invasion of alien species along roadsides, disturbance from human activities, and vehicle collisions. These phenomena pose threats to the survival of wildlife populations and the biodiversity of ecosystems. Among these impacts, wildlife-vehicle collisions have the most direct and significant influence on the ecosystem, particularly for amphibians and reptiles who are more susceptible to roadkill due to their life history characteristics and smaller body size.
Numerous studies have indicated that road conditions, traffic flow, and climate factors significantly influence the risk of roadkill for amphibians and reptiles. Roadkill incidents not only pose threats to individual organisms but can also have negative effects on the entire ecosystem, potentially leading to species extinction. In order to mitigate the impact of roads on wildlife, researchers and relevant organizations have begun to seek effective conservation measures. The aim of this study is to investigate the main factors influencing the distribution of roadkill hotspots for amphibians and reptiles on shallow mountain roads. We selected the areas of Chengtian Road and Longquan Road in Tucheng District, New Taipei City as our research area, as these locations possess abundant amphibian and reptile resources. Building upon previous research that collaborated with the New Taipei City Agriculture Bureau, we conducted a one-year field survey and data collection. Through statistical analysis of the collected data, our objective is to identify the primary factors influencing the distribution of roadkill hotspots and propose corresponding conservation recommendations to mitigate the negative impact of roadkill on wildlife. The results of the study reveal that the majority of roadkill species on Chengtian Road and Longquan Road in Tucheng District, New Taipei City are amphibians, followed by reptiles, with the peak period of roadkill occurring in spring and summer seasons. We utilized kernel density estimation to determine the distribution of roadkill hotspots and employed logistic regression analysis to identify influential factors with higher explanatory power in hotspot formation. Our findings indicate a correlation between the formation of roadkill hotspots and the distribution of open drainage ditches, crown coverage, retaining walls, vegetation slopes, and road gradients. Furthermore, comparing the distribution of roadkill hotspots with historical data, we observed differences in hotspot locations, which can be attributed to roadkill improvement projects implemented by the New Taipei City Agriculture Bureau in previously identified hotspot areas. The results of these engineering interventions have effectively reduced the occurrence of roadkill incidents. The survey data and analysis results of this study can serve as a reference for future road sections with similar conditions, providing a basis for roadkill monitoring and guidance for roadkill improvement projects. However, it should be noted that the timeframe of this investigation was limited to a single year. For more comprehensive data, a more in-depth and longer-term survey would be necessary. | en |
dc.description.provenance | Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-09-22T17:09:04Z No. of bitstreams: 0 | en |
dc.description.provenance | Made available in DSpace on 2023-09-22T17:09:04Z (GMT). No. of bitstreams: 0 | en |
dc.description.tableofcontents | 第一章 前言 1
第二章 目的 3 第三章 研究架構 4 第四章 文獻回顧 6 4.1 國內外路殺研究的發展與案例 6 4.2 造成路殺事件發生的可能因素 7 4.2.1 生物學因素 8 4.2.2 環境因素 8 4.2.3 人為因素 9 4.3 路殺事件對於兩棲與爬蟲動物的影響與案例 10 4.4 以核密度估計來進行路殺事件的熱點分析 12 4.5 應用羅吉斯回歸來分析可能的路殺熱點影響因子 14 4.6 兩棲爬蟲動物之路殺改善工程 15 第五章 研究方法 17 5.1 研究區域 17 5.2 路殺資料調查 19 5.2.1 調查方式 19 5.2.2 調查頻率 19 5.3 路殺熱點分析 21 5.4 可能的路殺熱點影響因子分析 23 5.4.1 影響因子搜集與資料處理 23 1. 土地利用類別 23 2. 人造結構物 24 3. 水體 24 4. 坡度 24 5. 植物遮蔽區域 25 5.4.2 以羅吉斯回歸進行路殺熱點的影響因子分析 25 第六章 結果 26 6.1 路殺調查結果 26 6.2.1 路殺物種紀錄 26 6.2.2 路殺焦點物種 36 1. 盤古蟾蜍 ( Bufo bankorensis ) 36 2. 印度蜓蜥 ( Sphenomorphus indicus ) 38 3. 拉都希氏赤蛙 ( Hylarana latouchii ) 40 6.2 路殺熱點分佈 42 6.3 路殺熱點影響因子分析 56 6.3.1 土地利用類型 56 6.3.2 道路兩側人造結構物 59 6.3.3 水體 64 6.3.4 坡度 67 6.3.5 植物遮蔽 68 6.4 以羅吉斯回歸分析各項路殺熱點影響因子 72 1. 明渠: 74 2. 遮蔽邊界與遮蔽佔比: 75 3. 坡度 75 4. 漿砌卵石擋土牆 75 5. 植生邊坡 76 6. 水泥擋土牆 76 7. 建築用地 76 8. 水泥護欄 77 第七章 討論 78 7.1 路殺調查情形及其偏誤 78 7.2 熱點分析 81 7.3相關研究比較 83 7.4 路殺改善工程及其影響 85 第八章 結論與建議 89 8.1 結論 89 8.2 建議 91 第九章 參考文獻 92 第十章 附錄 102 10.1 道路兩側影響因子之圖例 102 | - |
dc.language.iso | zh_TW | - |
dc.title | 影響淺山道路兩棲爬蟲動物路殺熱點分佈之主因 以新北市土城區承天路與龍泉路為例 | zh_TW |
dc.title | Factors influencing the distribution of roadkill hotspots for amphibians and reptiles in suburban hills: A case study of Tucheng District, New Taipei City | en |
dc.type | Thesis | - |
dc.date.schoolyear | 111-2 | - |
dc.description.degree | 碩士 | - |
dc.contributor.oralexamcommittee | 方偉達;任秀慧;蕭旭峰 | zh_TW |
dc.contributor.oralexamcommittee | Wei-Ta Fang ;Rita Yam;Syu-Feng Shiao | en |
dc.subject.keyword | 路殺,路殺熱點,路殺影響因子,路殺改善工程,兩棲類,爬蟲類,核密度估計,羅吉斯回歸, | zh_TW |
dc.subject.keyword | roadkill,roadkill hotspots,roadkill influencing factors,roadkill improvement projects,amphibians,reptiles,kernel density estimation,logistic regression, | en |
dc.relation.page | 104 | - |
dc.identifier.doi | 10.6342/NTU202304133 | - |
dc.rights.note | 同意授權(全球公開) | - |
dc.date.accepted | 2023-08-14 | - |
dc.contributor.author-college | 生物資源暨農學院 | - |
dc.contributor.author-dept | 生物環境系統工程學系 | - |
顯示於系所單位: | 生物環境系統工程學系 |
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