Effect of Vachellia tortilis on understory vegetation, herbaceous biomass and soil nutrients along a grazing gradient in a semi-arid African savanna

Temesgen Yadeta; Elmar Veenendaal; Karle Sykora; Zewdu K. Tessema; Addisu Asefa

doi:10.1007/s11676-017-0585-2

Journal of Forestry Research ›› 2018, Vol. 29 ›› Issue (6) : 1601 -1609. DOI: 10.1007/s11676-017-0585-2

Original Paper

Effect of Vachellia tortilis on understory vegetation, herbaceous biomass and soil nutrients along a grazing gradient in a semi-arid African savanna

Author information +

History +

PDF

Abstract

The spatial pattern and abundance of herbaceous vegetation in semi-arid savannas are dictated by a complex and dynamic interaction between trees and grasses. Scattered trees alter the composition and spatial distribution of herbaceous vegetation under their canopies. Therefore, we studied the effect of Vachellia tortilis on herbaceous vegetation composition, biomass and basal area, and soil nutrients on sites with varying grazing intensities in the central rift valley of Ethiopia. Data were collected on species composition, cover and biomass of herbs and grasses, and soil moisture and nutrient contents under light, medium, and heavy grazing pressures, both under the inside and outside of V. tortilis canopies. Species richness was similar in both locations but decreased with increased grazing. Only the overall biomass and herb cover were significantly greater under the canopy than outside, and overall biomass showed significant unchanging decline with increased grazing. However, vegetation cover was significantly greater on moderately grazed sites compared to low and heavily grazed sites. All soil variables were significantly higher under V. tortilis canopies than outside. Our findings suggest that V. tortilis has more effect on composition and diversity of herbaceous vegetation than on species richness, and that V. tortilis promotes the herbaceous layer biomass by reducing soil moisture loss and increasing soil fertility under the inside than outside the canopies. Therefore, we suggest that management practices should be directed on reducing pressure on V. tortilis by regulating grazing. Low to moderate grazing levels (i.e., a stocking rate less than 39.6 TLU ha⁻¹ yr⁻¹) seems to be tolerable to ensure sustainable conservation of the species in the study area in particular and in semi-arid savannas in general.

Keywords

Basal area cover / Grazing pressure / Inside/outside canopy / Soil moisture

Cite this article

Download citation ▾

Temesgen Yadeta, Elmar Veenendaal, Karle Sykora, Zewdu K. Tessema, Addisu Asefa. Effect of Vachellia tortilis on understory vegetation, herbaceous biomass and soil nutrients along a grazing gradient in a semi-arid African savanna. Journal of Forestry Research, 2018, 29(6): 1601-1609 DOI:10.1007/s11676-017-0585-2

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Abule E, Smit GN, Snyman HA. The influence of woody plants and livestock grazing on grass species composition, yield and soil nutrients in the Middle Awash Valley of Ethiopia. J Arid Environ, 2005, 60(2): 343-358.

[2]	Angassa A, Oba G. Effects of grazing pressure, age of enclosures and seasonality on bush cover dynamics and vegetation composition in southern Ethiopia. J Arid Environ, 2010, 74: 111-120.

[3]	Argaw M, Teketay D, Olsson M. Soil seed flora, germination and regeneration pattern of woody species in an Acacia woodland of the Rift Valley in Ethiopia. J Arid Environ, 1999, 43: 411-435.

[4]	Asefa A, Mengesha G, Shimelis A, Mamo Y. Livestock grazing in Afromontane mountains, Ethiopia: implications for bird conservation. Sci Technol Arts Res J, 2015, 4(2): 112-121.

[5]	Asefa A, Mamo Y, Mengesha G, Shimelis A. Woody plant diversity along disturbance gradients in the northern Afromontane forests of the Bale Mountains, Ethiopia. Int J Dev Res, 2015, 5(03): 3745-3754.

[6]	Belsky J. Influences of trees on savanna biomass: tests of shade, nutrients, and tree-grass competition. Ecology, 1994, 75(4): 922-932.

[7]	Belsky AJ, Amundson RG, Duxbury JM, Riha SJ, Ali AR, Mwonga SM. The effects of trees on their physical, chemical and biological environments in a semi-arid savanna in Kenya. J Appl Ecol, 1989, 26: 1005-1024.

[8]	Belsky AJ, Mwonga SM, Amundson RG, Duxbury JM, Ali AR. Comparative effects of isolated trees on their under crown environments in high- and low-rainfall savannas. J Appl Ecol, 1993, 30(1): 143-155.

[9]	Belsky AJ, Mwonga SM, Duxbury JM. Effects of widely spaced trees and livestock grazing in understory environments in tropical savannas. Agrofor Syst, 1993, 24: 1-20.

[10]	Bikila NG, Tessema ZK, Abule EG. Carbon sequestration potentials of semi-arid rangelands under traditional management practices in Borana, Southern Ethiopia. Agric Ecosyst Environ, 2016, 223: 108-114.

[11]	Bradd WG, Michelle VN, MichaelI B, Beetona RJS, Neal WM. Carbon sequestration and biodiversity restoration potential of semi-arid Mulga lands of Australia interpreted from long-term grazing exclosure. Agric Ecosyst Environ, 2011, 141: 108-118.

[12]	Clarke KR, Gorley RN. PRIMER V6: user manual/tutorial, 2006, Plymouth: PRIMER-E.

[13]	Colwell RK (2013) EstimateS 9.1.0 User’s Guide. http://purl.oclc.org/estimates or http://viceroy.eeb.uconn.edu/estimates

[14]	Dabasso BH, Zerihun T, Dana H. Carbon stocks in semi-arid pastoral ecosystems of northern Kenya. Pastoralism: Res Policy Pract, 2014, 4(5): 1-8.

[15]	Dyer AR. Burning and grazing management in California grassland: effect on bunchgrass seed viability. Restor Ecol, 2002, 10(1): 107-111.

[16]	Eshete G, Sathi G. Functions for multi-phase assessment of biomass in Acacia woodlands of the Rift Valley of Ethiopia. For Ecol Manag, 1998, 105: 79-90.

[17]	EWNHS (2009) Settlement expansion and natural resource management problems in the Abijiata-Shalla Lakes National Park, Walia. In: Hailu T (ed) Ethiopian Wildlife and Natural History Society (EWNHS), pp 1–54

[18]	Gebrekirstos A, Mitlöhner R, Teketay D, Worbes M. Climate-growth relationships of the dominant tree species from semi-arid savanna woodland in Ethiopia. Trees, 2008, 22: 631-641.

[19]	Hailu A, Gure A, Mengesha G, Mamo Y, Asefa A. Response of Swayne’s Hartebeest to fire-induced habitat change in Senkelle Sanctuary, Ethiopia. Sci Technol Arts Res J, 2015, 4(2): 112-121.

[20]	Jake F, Michael B. Savanna tree influence on understory vegetation and soil nutrients in north-western Kenya. J Veg Sci, 1990, 1: 325-334.

[21]	Jones JC, Reynolds JD, Raffaelli D. Sutherland JW. Environmental variables. Ecological census techniques: a handbook, 2006 2 Cambridge: Cambridge University Press.

[22]	Kelecha W. Glossary of Ethiopian plant names, 1987 4 Addis Ababa: Addis Ababa University.

[23]	Kumssa T, Bekele A. Attitude and perceptions of local residents toward the protected area of Abijata-Shalla Lakes National Park (ASLNP), Ethiopia. J Ecosyst Ecogr, 2014, 4: 138.

[24]	Kyalangalilwa B, Boatwright JS, Daru BH, Maurin O, van der Bank M. Phylogenetic position and revised classification of Acacia s.l. (Fabaceae: mimosoideae) in Africa, including new combinations in Vachellia and Senegalia. Bot J Linn Soc, 2013, 172: 500-523.

[25]	Linstädter A, Bora Z, Tolera A, Angassa A. Are trees of intermediate density more facilitative? Canopy effects of four East African legume trees. Appl Veg Sci, 2016, 19: 291-303.

[26]	Ludwig F, De Kroon H, Prins HHT, Berendse F. Effects of nutrients and shade on tree-grass interactions in an East African savanna. J Veg Sci, 2001, 1: 579-588.

[27]	Ludwig F, Dawson TE, Kroon H, Berendse F, Prins HHT. Hydraulic lift in Acacia tortilis trees on an East African savanna. Oecol, 2003, 134: 293-300.

[28]	Ludwig F, Dawson TE, Prins HHT, Berendse F, De Kroon H. Below-ground competition between trees and grasses may overwhelm the facilitative effects of hydraulic lift. Ecol Lett, 2004, 7: 623-631.

[29]	Ludwig F, De Kroon H, Berendse F, Prins HHT. The influence of savanna trees on nutrient, water and light availability and the understory vegetation. Plant Ecol, 2004, 170: 93-105.

[30]	McCune B, Mefford MJ. Multivariate analysis of ecological data, version 4, 1999, Beach: Gleneden MJM Software Design.

[31]	Mengesha G, Mamo Y, Bekele A. A comparison of terrestrial bird community structure in the undisturbed and disturbed areas of the Abijata Shalla Lakes National Park, Ethiopia. Int J Biodivers Conserv, 2011, 3(9): 389-404.

[32]	Moyo CS, Campbell BM. Grass species composition, yield and quality under and outside tree crown in a semi-arid rangeland in south-western Zimbabwe. Afr J Range For Sci, 1998, 15(1): 23-34.

[33]	Newton AC. Forest ecology and conservation: a handbook of techniques in ecology and conservation series, 2007, Oxford: Oxford University Press

[34]	Phillips C (1995) Poaceae (Gramineeae). In: Hedberg I, Edwards S (eds) Flora of Ethiopia and Eritrea, vol 7. Addis Ababa University, Addis Ababa, and Uppsala University, Uppsala

[35]	Quinn G, Keough M. Experimental design and data analysis for biologists, 2002, Cambridge: Cambridge University Press

[36]	Sankaran M, Ratnam J, Hanan NP. Tree-grass coexistence in savannas revisited-insights from an examination of assumptions and mechanisms invoked in existing models. Ecol Lett, 2004, 7: 480-490.

[37]	Scholes RJ, Archer SR. Tree-grass interactions in savanna. Annu Rev Ecol Syst, 1997, 28: 517-544.

[38]	Senbeta F, Tefera F. Environmental crises in Abijata Shalla Lakes National Park. Walia, 2001, 22: 28-36.

[39]	Tessema ZK, Belay EF. Effect of tree species on understory vegetation, herbaceous biomass and soil nutrients in a semi-arid savanna of Ethiopia. J Arid Environ, 2017, 139: 76-84.

[40]	Tessema ZK, de Boer WF, Baars MRT, Prins HHT. Changes in soil nutrients, vegetation structure and herbaceous biomass in response to grazing in a semi-arid savanna of Ethiopia. J Arid Environ, 2011, 75(7): 662-670.

[41]	Tessema ZK, de Boer WF, Baars RT, Prins HHT. Influence of grazing on soil seed banks determines the restoration potential of aboveground vegetation in a semi-arid savanna of Ethiopia. Biotropica, 2012, 44: 211-219.

[42]	Treydte AC, Heitkonig IMA, Prins HHT, Ludwig F. Trees improve grass quality for herbivores in African savannas. Perspect Plant Ecol Evol Syst, 2007, 8: 197-205.