[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.7747/JFES.2022.38.2.75

Diversity, Interspecific Interaction and Abundance of Undergrowth in Monocultures and Integrated Systems of Natural Rubber Plantation in Danzhou, Southern China

Chima, Uzoma Darlington (Rubber Research Institute, Chinese Academy of Tropical Agricultural Sciences/Danzhou Investigation ＆ Experiment Station of Tropical Crops, Ministry of Agriculture and Rural Affairs)
Qi, Dongling (Rubber Research Institute, Chinese Academy of Tropical Agricultural Sciences/Danzhou Investigation ＆ Experiment Station of Tropical Crops, Ministry of Agriculture and Rural Affairs)
Wu, Zhixiang (Rubber Research Institute, Chinese Academy of Tropical Agricultural Sciences/Danzhou Investigation ＆ Experiment Station of Tropical Crops, Ministry of Agriculture and Rural Affairs)
Lan, Guoyu (Rubber Research Institute, Chinese Academy of Tropical Agricultural Sciences/Danzhou Investigation ＆ Experiment Station of Tropical Crops, Ministry of Agriculture and Rural Affairs)
Chen, Li (Rubber Research Institute, Chinese Academy of Tropical Agricultural Sciences/Danzhou Investigation ＆ Experiment Station of Tropical Crops, Ministry of Agriculture and Rural Affairs)

Publication Information

Journal of Forest and Environmental Science / v.38, no.2, 2022 , pp. 75-89 More about this Journal

Abstract

The negative impact of monoculture rubber plantations on biodiversity and associated ecological processes/ecosystem services has led to suggestions on the use of integrated land use systems for rubber cultivation and production in order to ensure environmental sustainability. However, there is paucity of information on the effect of such integrated land use systems on the diversity and abundance of the rubber plantation undergrowth. We evaluated and compared undergrowth plant species composition, richness, abundance, diversity and interaction, in three integrated systems (Rubber-Strelitzia reginae Integrated System - RSrIS, Rubber-Podocarpus nagi Integrated System - RPnIS & Naturally Managed Rubber Plantation - NMRP) with three Rubber Monoculture Plantations (RMP₁, RMP₂ & RMP₃) adjacent to the integrated systems, respectively, at the Investigation and Experiment Station of Tropical Crops, Danzhou, Hainan, China. Undergrowth species density was higher in the rubber monocultures than in the integrated systems except in RSrIS. Species richness and diversity were also higher in the monocultures except in NMRP. Species similarity/interaction between the monocultures and the integrated systems was highest between RMP₃ and NMRP. The NRMP proved to be the best model of natural rubber integrated system for the conservation of undergrowth species richness, diversity and interspecific interaction. However, the conservation of undergrowth species in other forms of integrated natural systems can be enhanced by considering the ecology of species to be integrated in terms of their growth characteristics, competitive nature, and ability to grow in association with other species.

Keywords

diversity; integrated land use; rubber monoculture; species interaction; undergrowth;

Citations & Related Records

Times Cited By KSCI : 3 (Citation Analysis)

Reference
Cited By KSCI

1	Bremer LL, Farley KA. 2010. Does plantation forestry restore biodiversity or create green deserts? A synthesis of the effects of land-use transitions on plant species richness. Biodivers Conserv 19: 3893-3915. DOI
2	Chen H, Cao M, Tang Y. 2013. Soil seed banks in plantations and tropical seasonal rainforests of Xishuangbanna, South-west China. J Trop For Sci 25: 375-386.
3	Cotter M, Grenz J, Sauerborn J. 2012. Biodiversity evaluation in tropical agricultural systems - how will rubber cultivation and land use change effect species diversity in SW China. Geophys Res Abstr 14: EGU2012-7435.
4	Hannerz M, Hanell B. 1997. Effects on the flora in Norway spruce forests following clearcutting and shelterwood cutting. For Ecol Manag 90: 29-49. DOI
5	Hidayat MR, Endris WM, Dwiyanti Y. 2018. Effect of a rubber plantation on termite diversity in Melawi, West Kalimantan, Indonesia. Agric Natl Resour 52: 439-444.
6	Li H, Aide TM, Ma Y, Liu WJ, Cao M. 2007. Demand for rubber is causing the loss of high diversity rain forest in SW China. Biodivers Conserv 16: 1731-1745. DOI
7	Li H, Ma Y, Liu W, Liu W. 2012. Soil changes induced by rubber and tea plantation establishment: comparison with tropical rain forest soil in Xishuangbanna, SW China. Environ Manage 50: 837-848. DOI
8	Luo K. 1985. Collection of Hainan Tropical Agricultural Zoning. Science Press, Beijing.
9	Luo QP, Liu WJ. 2012. [Comparison of the effect of different canopy of rubber plantation on soil splash erosion and through fall erosivity]. Chin J Soil Sci 43: 1348-1354. Chinese.
10	Gaertner M, Den Breeyen A, Hui C, Richardson DM. 2009. Impacts of alien plant invasions on species richness in Mediterranean-type ecosystems: a meta-analysis. Prog Phys Geogr Earth Environ 33: 319-338. DOI
11	Obasi KO, Ijere ND, Okechukwu RI. 2013. Species Diversity and Equitability Indices of Some Fresh Water Species in Aba River and Azumini Blue River, Abia State Nigeria. Int J Sci Technol 2: 238-242.
12	Phommexay P, Satasook C, Bates P, Pearch M, Bumrungsri S. 2011. The impact of rubber plantations on the diversity and activity of understorey insectivorous bats in southern Thailand. Biodivers Conserv 20: 1441-1456. DOI
13	Rahman MR, Hossain MK, Hossain MA. 2019. Diversity and Composition of Tree Species in Madhupur National Park, Tangail, Bangladesh. J For Environ Sci 35: 159-172.
14	Schmitz DC, Simberloff D. 1997. Biological Invasions: A Growing Threat. Issues Sci Technol 13: 33-40.
15	Xiao HF, Tian YH, Zhou HP, Ai XS, Yang XD, Schaefer DA. 2014. Intensive rubber cultivation degrades soil nematode communities in Xishuangbanna, southwest China. Soil Biol Biochem 76: 161-169. DOI
16	Chima UD, Adekunle AT, Okorie MCF. 2013. Ecological and Ethnomedicinal Survey of Plants within Homesteads in Abia State, Nigeria. J For Environ Sci 29: 257-274.
17	Aiyeloja AA, Chima UD. 2011. Economic and Ecological Consequences of Charcoal Production in Oyo State, Nigeria. Asia Pac J Rural Dev 21: 85-92. DOI
18	Amubode FO. 1996. Measuring and Monitoring of Faunal and Avifaunal Biodiversity. pp. 53-65, In: Ola-Adams B.A. and Ojo L.O. (Eds.) Proceedings of the Inception of a Training Workshop on Biosphere Reserves for Biodiversity Conservation and Sustainable Development in Anglophone Africa (BRAAF): Assessment and Monitoring Techniques in Nigeria, 9-11 January, 1996.
19	Bullock J. 1996. Plants. In: Ecological Census Techniques: A Handbook (Sutherland WJ, ed). Cambridge University Press, Cambridge, pp 111-138.
20	Chima UD, Uwaegbulem C. 2012. Comparative Evaluation of Tree Species Populations under Different Land Use Types within the University of Port Harcourt Environs. Trop Agric Res Ext 15: 1-7. DOI
21	Engel DH, Phummai S. 2008. A Field Guide to Tropical Plants of Asia. Select Books Pte. Ltd., Singapore.
22	Li Z, Fox JM. 2012. Mapping rubber tree growth in mainland Southeast Asia using time-series MODIS 250 m NDVI and statistical data. Appl Geogr 32: 420-432. DOI
23	He P, Martin K. 2015. Effects of rubber cultivation on biodiversity in the Mekong Region. CAB Rev 10: 1-7. DOI
24	Zheng G, Li SQ, Yang XD. 2015. Spider diversity in canopies of Xishuangbanna rainforest (China) indicates an alarming juggernaut effect of rubber plantations. For Ecol Manag 338: 200-207. DOI
25	Webster CR, Jenkins MA, Jose S. 2006. Woody Invaders and the Challenges They Pose to Forest Ecosystems in the Eastern United States. J For 104: 366-374.
26	FAO (Food & Agriculture Organization). 2013. Statistical Division (FAOSTAT). FAO Statistical Databases 2013. http://faostat.fao.org/. Accessed 6 Jul 2019.
27	Gilman EF, Watson DG. 1994. Podocarpus nagi. University of Florida Landscape Factsheet (ST - 497). https://horti.ifas.ufl.edu/database/documents/pdf/tree_fact_sheets/podnaga.pdf. Accessed 9 Oct 2019.
28	He K, Huang Z. 1987. Rubber Culture in the Northern Part of Tropical Area. Guangdong Science & Technology Press, Guangzhou.
29	Holzmueller EJ, Jose S. 2011. Invasion success of cogongrass, an alien C4 perennial grass, in the southeastern United States: exploration of the ecological basis. Biol Invasions 13: 435-442. DOI
30	Kent M, Coker P. 1992. Vegetation Description and Analysis: A Practical Approach. CRC press, London.
31	Leishangthem D, Singh MR. 2018. Tree Diversity, Distribution and Population Structure of a Riparian Forest from Certain Zones along the Dikhu River in Nagaland, India. J For Environ Sci 34: 31-45.
32	Magurran AE. 2004. Diversity and Its Measurements. Chapman and Hall, London, 395 pp.
33	Islam KR, Weil RR. 2000. Land use effects on soil quality in a tropical forest ecosystem of Bangladesh. Agric Ecosyst Environ 79: 9-16. DOI
34	Ziegler AD, Fox JM, Xu J. 2009. Agriculture. The rubber juggernaut. Science 324: 1024-1025. DOI
35	Xu, J, Grumbine RE, Beckschafer P. 2014. Landscape transformation through the use of ecological and socioeconomic indicators in Xishuangbanna, Southwest China, Mekong Region. Ecol Indic 36: 749-756. DOI
36	Zhang M, Zou XM. 2009. [Comparison of soil C and N in rubber plantation and seasonal rain forest]. Ying Yong Sheng Tai Xue Bao 20: 1013-1019. Chinese.
37	Zhou YJ, Li JH, Ross Friedman C, Wang HF. 2017. Variation of Soil Bacterial Communities in a Chronosequence of Rubber Tree (Hevea brasiliensis) Plantations. Front Plant Sci 8: 849. DOI
38	Wu Z, Xie G, Yang C, Tao Z., Zhou Z. 2010. Characteristics of Microclimate and Flux of a Rubber Plantation Ecosystem in Dry Season of Hainan Island,South China. Chin J Trop Crops 12: 2081-2090.
39	Guardiola-Claramonte M, Troch PA, Ziegler AD, Giambelluca TW, Vogler JB, Nullet MA. 2008. Local hydrologic effects of introducing non-native vegetation in a tropical catchment. Ecohydrology 1: 13-22. DOI
40	Ahrends A, Hollingsworth PM, Ziegler AD, Fox JM, Chen H, Su Y, Xu J. 2015. Current trends of rubber plantation expansion may threaten biodiversity and livelihoods. Glob Environ Change 34: 48-58. DOI
41	Prabowo WE, Darras K, Clough Y, Toledo-Hernandez M, Arlettaz R, Mulyani YA, Tscharntke T. 2016. Bird Responses to Lowland Rainforest Conversion in Sumatran Smallholder Landscapes, Indonesia. PLoS One 11: e0154876. DOI
42	Salami AT. 1998. Vegetation modification and man-induced environmental change in rural southwestern Nigeria. Agric Ecosyst Environ 70: 159-167. DOI
43	Singh D, Slik JWF, Jeon YS, Tomlinson KW, Yang X, Wang J, Kerfahi D, Porazinska DL, Adams JM. 2019. Tropical forest conversion to rubber plantation affects soil micro- & mesofaunal community & diversity. Sci Rep 9: 5893. DOI
44	Sun Y, Ma Y, Cao K, Li H, Shen J, Liu W, Di L, Mei C. 2017. Temporal Changes of Ecosystem Carbon Stocks in Rubber Plantations in Xishuangbanna, Southwest China. Pedosphere 27: 737-746. DOI
45	Jones DT, Susilo FX, Bignell DE, Hardiwinoto S, Gillison AN, Eggleton P. 2003. Termite assemblage collapse along a land-use intensification gradient in lowland central Sumatra, Indonesia. J Appl Ecol 40: 380-391. DOI
46	Chaudhary A, Burivalova Z, Koh LP, Hellweg S. 2016. Impact of Forest Management on Species Richness: Global Meta-Analysis and Economic Trade-Offs. Sci Rep 6: 23954. DOI
47	Jegede A. 2019. Top 10 Largest Rubber Producing Countries in the World. http://www.thedailyrecords.com/2018-2019-2020-2021/world-famous-top-10-list/world/largest-rubber-producing-countries-world-10-top/6857/. Accessed 18 Jul 2019.
48	Lan G, Wu Z, Chen B, Xie G. 2017. Species Diversity in a Naturally Managed Rubber Plantation in Hainan Island, South China. Trop Conserv Sci 10: 1-7.
49	Warren-Thomas E, Dolman PM, Edwards DP. 2015. Increasing Demand for Natural Rubber Necessitates a Robust Sustainability Initiative to Mitigate Impacts on Tropical Biodiversity. Conserv Lett 8: 230-241. DOI