PDF
Abstract
The subject of weather extremes, some climate-induced, cannot be wished away. Every economic sector is vulnerable, including nature-based tourism associated with national parks. This paper seeks to establish perceptions and experiences of park managers regarding what they consider to be the most prevalent weather extremes and their impacts on South African national parks. It also aims to determine response strategies adopted to minimise damage from such weather extremes across the six biomes covered by 13 parks studied. Data were generated from 61 middle- and top-level management, with extensive training and experience, and analysed using ATLAS.ti version 23 software. It emerged that certain climate-induced weather extremes were prevalent in specific biomes and national parks. Droughts, extreme heat, floods, and wildfires emerged as the topmost recurring, with strong winds, extreme cold and frost, hailstorms, high tides, and severe storms reported. Floods caused infrastructure damage, especially to roads, bridges, water pumps, camps, and electricity supply. Some flora and fauna species were declining due to droughts and wildfires. There were reports of bad flowering seasons, reduced water for waterfalls, and declining snow, which were key tourist attractions in some parks. Extreme heat was associated with staff and tourist fatigue, reduced tourist visits, penguin chick mortality, and bird species migration. Overall, parks were losing income. Park management responded by building back better infrastructure, creating fire breaks, drilling boreholes, adopting solar and green building, instituting water conservation measures, having a rehabilitation programme for erosion, instituting early warning systems, and changing staff work schedules. The study provides a picture of park managers' perceptions of weather extremes, environmental and socio-economic problems resulting from such, and strategies adopted to combat them.
Keywords
climate change
/
national parks
/
tourism
/
weather extremes
/
Sustainable Development Goal 13
Cite this article
Download citation ▾
Godwell Nhamo, Nthivhiseni Mashula, Gideon W. Mutanda.
Managers' perspectives on weather extremes prevalence in South African national parks.
International Journal of Geoheritage and Parks, 2025, 13(2): 205-219 DOI:10.1016/j.ijgeop.2025.01.004
| [1] |
B. Abrahms, N.H. Carter, T.J. Clark-Wolf, K.M. Gaynor, E. Johansson, A. McInturff, … L. West. Climate change as a global amplifier of human-wildlife conflict. Nature Climate Change, 13 (3) (2023), pp. 224-234, 10.1038/s41558-023-01608-5
|
| [2] |
H. Abukari, R.B. Mwalyosi.Local communities’ perceptions about the impact of protected areas on livelihoods and community development. Global Ecology and Conservation, 22 (2020), Article e00909,10.1016/j.gecco.2020.e00909
|
| [3] |
R.R. Bhandary. National climate funds: A new dataset on national financing vehicles for climate change. Climate Policy, 22 (3) (2022), pp. 401-410, 10.1080/14693062.2022.2027223
|
| [4] |
D. Bose, S. Becken.Tourism-related economic loss and damage from the North Island weather events on New Zealand conservation land and waters. Journal of Outdoor Recreation and Tourism, 46 (2024), Article 100767, 10.1016/j.jort.2024.100767
|
| [5] |
L. Chapungu, G. Nhamo, D. Chikodzi, K. Dube. Trends and impacts of temperature and fire regimes in South Africa’s coastal national parks: Implications for tourism. Natural Hazards, 120 (5) (2024), pp. 4485-4506, 10.1007/s11069-023-06384-1
|
| [6] |
X. Chen, L. Yu, Y. Cao, Y.D. Xu, Z.C. Zhao, Y.B. Zhuang, … P. Gong. Habitat quality dynamics in China’s first group of national parks in recent four decades: Evidence from land use and land cover changes.Journal of Environmental Management, 325 (2023), Article 116505, 10.1016/j.jenvman.2022.116505
|
| [7] |
D. Chikodzi, G. Nhamo, K. Dube, L. Chapungu. Climate change risk assessment of heritage tourism sites within South African national parks. International Journal of Geoheritage and Parks, 10 (3) (2022), pp. 417-434, 10.1016/j.ijgeop.2022.08.007
|
| [8] |
K.M. Coldrey, J.K. Turpie. Potential impacts of changing climate on nature-based tourism: A case study of South Africa’s national parks. Koedoe, 62 (1) (2020), Article a1629, 10.4102/koedoe.v62i1.1629
|
| [9] |
K.M. Coldrey, J.K. Turpie, G. Midgley, S. Scheiter, L. Hannah, P.R. Roehrdanz, W.B. Foden. Assessing protected area vulnerability to climate change in a case study of South African national parks. Conservation Biology, 36 (5) (2022), Article e13941, 10.1111/cobi.13941
|
| [10] |
C.A. Craig.Climate Resource View (CRV): A case of thermal safety at United States national parks. Journal of Outdoor Recreation and Tourism, 45 (2024), Article 100737, 10.1016/j.jort.2024.100737
|
| [11] |
M. De Felipe, D. Aragonés, C. Díaz-Paniagua.Thirty-four years of Landsat monitoring reveal long-term effects of groundwater abstractions on a World Heritage Site wetland. Science of the Total Environment, 880 (2023), Article 163329, 10.1016/j.scitotenv.2023.163329
|
| [12] |
S.Z. Dobrowski, C.E. Littlefield, D.S. Lyons, C. Hollenberg, C. Carroll, S.A. Parks, … J. Gage. Protected-area targets could be undermined by climate change-driven shifts in ecoregions and biomes. Communications Earth & Environment, 2 (1) (2021), p. 198, 10.1038/s43247-02100270-z
|
| [13] |
K. Dube, D. Chikodzi. Examining current and future challenges of sea level rise on coastal national parks. Geojournal of Tourism and Geosites, 50 (4) (2023), pp. 1573-1580, 10.30892/gtg.50436-1154
|
| [14] |
K. Dube, D. Chikodzi, G. Nhamo, L. Chapungu. Climate and conservation challenges facing Marakele National Park and their implications for tourism. Cogent Social Sciences, 9 (2) (2023), p. 2282705, 10.1080/23311886.2023.2282705
|
| [15] |
K. Dube, G. Nhamo.Vulnerability of nature-based tourism to climate variability and change: Case of Kariba resort town, Zimbabwe. Journal of Outdoor Recreation and Tourism, 29 (2020), Article 100281, 10.1016/j.jort.2020.100281
|
| [16] |
K. Dube, G. Nhamo.Evidence and impact of climate change on South African national parks. Potential implications for tourism in the Kruger National Park. Environmental Development, 33 (2020), Article 100485, 10.1016/j.envdev.2019.100485
|
| [17] |
K. Dube, G. Nhamo, D. Chikodzi, L. Chapungu.Mapping and evaluating the impact of flood hazards on tourism in South African national parks. Journal of Outdoor Recreation and Tourism, 43 (2023), Article 100661, 10.1016/j.jort.2023.100661
|
| [18] |
P. Gonzalez, F.Y. Wang, M. Notaro, D.J. Vimont, J.W. Williams. Disproportionate magnitude of climate change in United States national parks. Environmental Research Letters, 13 (10) (2018), Article 104001, 10.1088/1748-9326/aade09
|
| [19] |
A.J. Hansen, N. Piekielek, C. Davis, J. Haas, D.M. Theobald, J.E. Gross, … S.W. Running.Exposure of U.S. national parks to land use and climate change 1900-2100. Ecological Applications, 24 (3) (2014), pp. 484-502, 10.1890/13-0905.1
|
| [20] |
A. Hausmann, T. Toivonen, C. Fink, V. Heikinheimo, R. Kulkarni, H. Tenkanen, E. Di Minin. Understanding sentiment of national park visitors from social media data. People and Nature, 2 (3) (2020), pp. 750-760, 10.1002/pan3.10130
|
| [21] |
B. Jacobs, L. Boronyak, P. Mitchell, M. Vandenberg, B. Batten. Towards a climate change adaptation strategy for national parks: Adaptive management pathways under dynamic risk. Environmental Science & Policy, 89 (2018), pp. 206-215, 10.1016/j.envsci.2018.08.001
|
| [22] |
L.C. Jantarasami, J.J. Lawler, C.W. Thomas.Institutional barriers to climate change adaptation in U.S. national parks and forests. Ecology and Society, 15 (4) (2010), p. 33, 10.5751/ES-03715-150433
|
| [23] |
Y. Kobayashi, R. Seidl, W. Rammer, K.F. Suzuki, A.S. Mori. Identifying effective tree planting schemes to restore forest carbon and biodiversity in Shiretoko National Park, Japan. Restoration Ecology, 31 (1) (2023), Article e13681, 10.1111/rec.13681
|
| [24] |
M. Korená Hillayová, J. Holécy, K. Korísteková, M. Bakšová, M. Ostrihoň, J. Škvarenina.Ongoing climatic change increases the risk of wildfires. Case study: Carpathian spruce forests. Journal of Environmental Management, 337 (2023), Article 117620, 10.1016/j.jenvman.2023.117620
|
| [25] |
S. Luckeneder, S. Giljum, A. Schaffartzik, V. Maus, M. Tost.Surge in global metal mining threatens vulnerable ecosystems. Global Environmental Change, 69 (2021), Article 102303, 10.1016/j.gloenvcha.2021.102303
|
| [26] |
S. Ma, C.A. Craig, S. Feng, C. Liu. Climate resources at United States national parks: A tourism climate index approach. Tourism Recreation Research, 48 (5) (2023), pp. 710-724, 10.1080/02508281.2021.1946652
|
| [27] |
J. Malherbe, I.P.J. Smit, K.J. Wessels, P.J. Beukes. Recent droughts in the Kruger National Park as reflected in the extreme climate index. African Journal of Range & Forage Science, 37 (1) (2020), pp. 1-17, 10.2989/10220119.2020.1718755
|
| [28] |
B.W. Miller, G.W. Schuurman, A.J. Symstad, A.N. Runyon, B.C. Robb.Conservation under uncertainty: Innovations in participatory climate change scenario planning from U.S. national parks. Conservation Science and Practice, 4 (3) (2022), Article e12633, 10.1111/csp2.12633
|
| [29] |
W. Mushawemhuka, J.M. Fitchett, G. Hoogendoorn.Stakeholder perceptions of climate change threats to the Zimbabwean nature-based tourism sector. Environmental Development, 44 (2022), Article 100779, 10.1016/j.envdev.2022.100779
|
| [30] |
W. Mushawemhuka, G. Hoogendoorn, J. Fitchett.A comprehensive assessment of climate change threats and adaptation of nature based tourism in Zimbabwe. Retrieved from https://www.researchgate.net/publication/352063590 (2021)
|
| [31] |
W. Mushawemhuka, J.M. Rogerson, J. Saarinen. Nature-based tourism operators’ perceptions and adaptation to climate change in Hwange National Park, Zimbabwe. Bulletin of Geography: Socio-economic Series, 42 (42) (2018), pp. 115-127, 10.2478/bog-2018-0034
|
| [32] |
G. Nhamo, K. Dube, L. Chapungu, D. Chikodzi. Quest for NetZero emissions in South African national parks: A tourism perspective. Heliyon, 9 (6) (2023), Article e16410, 10.1016/j.heliyon.2023.e16410
|
| [33] |
S.A. Parks, L.M. Holsinger, J.T. Abatzoglou, C.E. Littlefield, K.A. Zeller. Protected areas not likely to serve as steppingstones for species undergoing climate-induced range shifts. Global Change Biology, 29 (10) (2023), pp. 2681-2696, 10.1111/gcb.16629
|
| [34] |
C. Parracciani, R. Buitenwerf, J.-C. Svenning. Impacts of climate change on vegetation in Kenya: Future projections and implications for protected areas. Land, 12 (11) (2023), p. 2052, 10.3390/land12112052
|
| [35] |
SANParks.Closure of facilities and roads at Table Mountain- and Tankwa Karoo national parks due to current floods and snow. Retrieved from https://www.sanparks.org/news/closure-of-facilities-and-roads-at-table-mountain-and-tankwa-karoo-national-parks-due-to-current-floods-and-snow (2024)
|
| [36] |
R. Scholtz, D. Twidwell. The last continuous grasslands on Earth: Identification and conservation importance. Conservation Science and Practice, 4 (3) (2022), Article e626, 10.1111/csp2.626
|
| [37] |
D. Scott, S. Gössling.A review of research into tourism and climate change—Launching the annals of tourism research curated collection on tourism and climate change. Annals of Tourism Research, 95 (2022), Article 103409, 10.1016/j.annals.2022.103409
|
| [38] |
Z.E. Sibitane, K. Dube, L. Lekaota. Global warming and its implications on nature tourism at Phinda private game reserve. International Journal of Environmental Research and Public Health, 19 (9) (2022), p. 5487, 10.3390/ijerph19095487
|
| [39] |
N.P. Simpson, K.J. Mach, A. Constable, J. Hess, R. Hogarth, M. Howden, … C.H. Trisos. A framework for complex climate change risk assessment. One Earth, 4 (4) (2021), pp. 489-501, 10.1016/j.oneear.2021.03.005
|
| [40] |
South African Biodiversity Institute.Drought threatens thousands of flamingo chicks in South Africa. Retrieved from https://www.sanbi.org/skep/drought-threatens-thousands-of-flamingo-chicks-in-south-africa/ (2019)
|
| [41] |
W.C. Turner, S. Périquet, C.E. Goelst, K.B. Vera, E.Z. Cameron, K.A. Alexander, … J.W. Kilian. Africa’s drylands in a changing world: Challenges for wildlife conservation under climate and land-use changes in the Greater Etosha Landscape. Global Ecology and Conservation, 38 (2022), Article e02221, 10.1016/j.gecco.2022.e02221
|
| [42] |
United Nations. Transforming our world: 2030 agenda for sustainable development. United Nations, New York (2015)
|
| [43] |
N.J. Van Wilgen, V. Goodall, S. Holness, S.L. Chown, M.A. Mcgeoch. Rising temperatures and changing rainfall patterns in South Africa’s national parks. International Journal of Climatology, 36 (2) (2016), pp. 706-721, 10.1002/joc.4377
|
| [44] |
C. Weinhäupl, E.S. Devenish-Nelson.Potential impacts of climate change on terrestrial Aotearoa New Zealand’s birds reveal high risk for endemic species. Biological Conservation, 296 (2024), Article 110668, 10.1016/j.biocon.2024.110668
|
| [45] |
C. Wigley-Coetsee, A.C. Staver. Grass community responses to drought in an African savanna. African Journal of Range & Forage Science, 37 (1) (2020), pp. 43-52, 10.2989/10220119.2020.1716072
|
| [46] |
K.R. Wilcox, S.E. Koerner, D.L. Hoover, A.K. Borkenhagen, D.E. Burkepile, S.L. Collins, … M.D. Smith. Rapid recovery of ecosystem function following extreme drought in a South African savanna grassland. Ecology, 101 (4) (2020), Article e2983, 10.1002/ecy.2983
|
| [47] |
J.C. Wingfield, J.H. Pérez, J.S. Krause, K.R. Word, P.L. González-Gómez, S. Lisovski, H.E. Chmura. How birds cope physiologically and behaviourally with extreme climatic events. Philosophical Transactions of the Royal Society B: Biological Sciences, 372 (1723) (2017), p. 20160140, 10.1098/rstb.2016.0140
|
