Abstract
Sustaining soil and forest resources, ensuring food security, and reducing poverty under changing climate in Africa are major challenges. The ever-increasing population, which may reach 1.4 billion by 2030, demands that food production must increase by 20% as compared to the present production. The population growth rate of 2.7% in 2017 in SSA region is also the highest in the world. This has intensified the problem of food insecurity as nearly 34% of population in SSA appears to be food insecure. Soils of SSA are prone to a range of soil degradation processes, and this is further aggravated by the increase in frequency and intensity of extreme events. The biophysical process of soil degradation is strongly influenced by the socio-economic, political, and cultural factors including the land tenure and gender-related issues. Indeed, soil-climate-human factors are intricately interlinked, and humanity’s impact on soil is increasing with the increase in population, affluence with which the population lives, and changes in technologies. Use of innovative technologies, financing value-added investments, and promotion of value addition to agricultural products are the ways of increasing and ensuring sustainable agricultural and livestock production. The adoption of new technologies, such as integrated dairy and cropping systems, leading to increased farm productivity and income, is spreading in central Malawi and the southern highlands of Tanzania. For example, integrated dairy and cropping systems are spreading and farmers are keeping few but more high-yielding cows in both regions. These cows produce milk and meat for household consumption and sale, but the dung provided is used for biogas production for cooking and light, as well as fertilizer for the crops. Currently, dairy goats provide milk and meat for approximately 100,000 Tanzanian smallholder farmers. The idea of personal transformation for changing our attitude for greater good and for sustainable agriculture is also a part of this process.
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References
Amuri NA (2015) Enhancing resilience of food production systems under changing climate and soil degradation in semi-arid and highlands of Tanzania. In: Lal R et al (eds) Sustainable intensification to advance food security and enhance climate resilience in Africa. Springer International Publishing Switzerland, Cham, pp 385–405. https://doi.org/10.1007/978-3-319-09360-4
Aune J, Lal R (1997) Agricultural productivity in the tropics and critical limits of properties of Oxisols, Ultisols and Alfisols. Trop Agric (Trinidad) 74:96–103
Bidwell OW, Hole FD (1965) Man as a factor of soil formation. Soil Sci 99:65–72
Burian A, Karaya R, Wernerssond JEV, Egberthf M, Lokorwah B, Nyberg G (2019) A community-based evaluation of population growth and agro-pastoralist resilience in sub-Saharan drylands. Environ Sci Pol 92:323–330
Carswell G (1997) Agricultural intensification and rural sustainable livelihoods: A think piece. IDS working paper 64. Sustainable Livelihood Programme, IDS, University of Sussex, Brighton
Charles H, Godfray J, Beddington JR, Crute IR, Haddad L, Lawrence D, Muir JF, Pretty J, Robinson S, Thomas SM, Toulmin C (2010) Food security: the challenge of feeding 9 billion people. Science 327:812–818
Deininger K, Hilhorst T, Songwe V (2014) Identifying and addressing land governance constraints to support intensification and land market operation: evidence from 10 African countries. Food Policy 38:76–83
Dicks LV, Rose DC, Ang F, Aston S, Birch ANE, Boatman N, Bowles EL, Chadwick D, Dinsdale A, Durham S, Elliott J, Firbank L, Humphreys S, Jarvis P, Jones D, Kindred D, Knight SM, Lee MRF, Leifert C, Lobley M, Matthews K, Midmer A, Moore M, Morris C, Mortimer S, Murray TC, Norman K, Ramsden S, Roberts D, Smith LG, Soffe R, Stoate C, Taylor B, Tinker D, Topliff M, Wallace J, Williams P, Wilson P, Winter M, Sutherland WJ (2019) What agricultural practices are most likely to deliver “sustainable intensification” in the UK? Food Energy Secur 8:e00148
Dorosh P, Thurlow J (2018) Beyond agriculture versus non-agriculture: decomposing sectoral growth–poverty linkages in five African countries. World Dev 109:440–451
Dudal R (2004) The sixth factor of soil formation. Paper presented at the international conference on soil classification 2004, Petrozavodsk, Russia, 3–5 August 2004
E.C. (2017) Evaluation Study of the Payment of Agricultural Practices Beneficial for the Climate and the Environment. Alliance Environment and Thunen Institute
FAO (2015) The State of Food Insecurity in the World 2015. Meeting the 2015 international hunger targets: taking stock of uneven progress. Rome, FAO
FAOstat (2019a) Crops. June 2019. http://www.fao.org/faostat/en/#data/QC
FAOstat (2019b) Land use. Available at http://www.fao.org/faostat/en/#data/RL
FinMark Trust (2016) Report agricultural subsidies in SADC countries – current status and impact. Agricultural Subsidies in SADC: Final Report, p 187
Food and Agriculture Organization of the United Nations (FAO) and United Nations Economic Commission for Africa (ECA) (2018) Regional Overview of Food Security and Nutrition. Addressing the threat from climate variability and extremes for food security and nutrition. Accra. 116 pp
IMF (International Monetary Fund) (2018) Malawi, IMF country report no. 18/336. https://www.imf.org, site visited 30.8.2019
IPCC (2018) Global warming of 1.5 °C. Summary for Policy Makers. https://report.ipcc.ch/sr15/pdf/sr15_spm_final.pdf
Jayne TS, Mather D, Mghenyi E (2010) Principal challenges confronting smallholder agriculture in Sub-Saharan Africa. World Dev 38:1384–1398
Jayne TS, Yeboah FK, Henry C (2017) The future of work in African agriculture: trends and drivers of change. International Labour Office. Research Department working paper no. 25, p 32
Jenny H (1941) Factors of soil formation: a system of quantitative pedology. McGraw-Hill, New York
Josephson AL, Ricker-Gilbert J, Florax RJGM (2014) How does population density influence agricultural intensification and productivity? Evidence from Ethiopia. Food Policy 48:142–152
Kafle AK, Garcia X, Wang PE, Pfeffer GD, Strahan HB (2019) Nutrient demand and fungal access to resources control the carbon allocation to the symbiotic partners in tripartite interactions of Medicago truncatula. Plant Cell Environ 42:270–284
Kalabamu FT (2019) Land tenure reforms and persistence of land conflicts in Sub-Saharan Africa – the case of Botswana. Land Use Policy 81:337–345
Lal R (2007a) Promoting technology in Sub-Saharan Africa, South Asia. CSA News 52(7):10–13
Lal R (2007b) Tragedy of the global commons: soil, water and air. CSA News 52:10–11
Lal R (2015) Sustainable intensification for adaptation and mitigation of climate change and advancement of food security in Africa. In: Lal R et al (eds) Sustainable intensification to advance food security and enhance climate resilience in Africa. Springer International Publishing Switzerland, Cham, pp 1–17. https://doi.org/10.1007/978-3-319-09360-4
Lal R (2016a) Beyond COP 21: potential and challenges of the “4 per thousand” initiative. J Soil Water Conserv 71:20A–25A
Lal R (2016c) Soil health and carbon management. Food Energy Secur 5(4):212–222
Lal R (2018a) Digging deeper. A wholistic perspective of factors affecting SOC sequestration. Glob Chang Biol 24(8). https://doi.org/10.1111/gcb.14054
Lal R (2018b) Sustainable development goals and the IUSS. In: Lal R, Horn R, Kosaki T (eds) Soil and sustainable development goals. Catena Schweizerbart, Stuttgart, pp 189–196
Lal R (2019) Ecointensification through soil carbon sequestration: harnessing ecosystem services and advancing sustainable development goals. J Soil Water Conserv 74(3):55A–61A
Lal R, Smith P, Jungkunst HF, Mitsch W et al (2018a) The carbon sequestration potential of terrestrial ecosystems. J Soil Water Conserv 73:145A–152A
Lal R, Horn R, Kosaki T (eds) (2018b) Soil and sustainable development goals. Catena Schweizerbart, Stuttgart, p 196
Le Quéré C, Andrew RM, Friedlingstein O, Sitch S, Hauck J, Pongratza J et al (2018) Global carbon budget. Earth Syst Sci Data 10:2141–2194
Leopold A (1949) The land ethic. In: A sand county Almanac. University of Colorado, Boulder
Lindsey R (2018) Climate change: atmospheric carbon dioxide. NOAA. Climate.gov
Loveland P, Webb J (2003) Is there critical level of organic matter in the agricultural soils of temperate regions: review. Soil Tillage Res 70:1–18
Malawi Government (2017) Malawi national agricultural investment plan (NAIP)
Mathews GA, Tunstall JP (2006) Smallholder cotton production in sub-Saharan Africa: an assessment of the way forward. Int J Pest Manag 52:149–153
Muyanga M, Jayne TS (2014) Effects of rising rural population density on smallholder agriculture. Food Policy 48:98–113
New Partnership for Africa’s Development (NEPAD) (2013) Agriculture in Africa. Transformation and outlook. NEPAD, Midrand
NOAA-ESRL (2019) All time records high of for CO2 daily averages. Daily CO2. https://www.co2.earth/daily-co2
Tache B and Oba G (2010) Is poverty driving borana herders in southern ethiopia to crop cultivation? Human Ecology Vol. 38, No. 5 (OCTOBER 2010), pp. 639–649
United Nations, Department of Economic and Social Affairs, Population Division (2015) World Population Prospects: The 2015 Revision, Key Findings and Advance Tables. Working Paper No. ESA/P/WP.241
VIB Fact Series (2017) IBPO’s fact series -Maize in Africa. http://www.vib.be/en/about-vib/Documents/VIB_MaizeInAfrica_EN_2017.pdf
World Bank (2017) World Development Indicators 2017. Washington, DC. © World Bank. https://openknowledge.worldbank.org/handle/10986/26447 License: CC BY 3.0 IGO., accessed June 5, 2019.
World Bank (2018) Malawi systematic country diagnostic: breaking the cycle of low growth and slow poverty reduction. The World Bank, Washington, DC
ITPS and FAO 2018. Global soil organic carbon map. Technical Report. Rome. 162 pp.
World Bank data (2019) https://data.worldbank.org/indicator/SP.POP.GROW?locations=ZG-ZF
WMO (2019) Greenhouse Gas Bulletin #15. The State of Greenhouse Gases in the Atmosphere Based on Global Observations Through 2018. World Meteorological Organization, Geneva, Switzerland.
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Singh, B.R., Safalaoh, A., Amuri, N.A., Eik, L.O., Sitaula, B.K., Lal, R. (2020). Agricultural and Natural Resource Sustainability Under Changing Climate in Africa. In: Singh, B., Safalaoh, A., Amuri, N., Eik, L., Sitaula, B., Lal, R. (eds) Climate Impacts on Agricultural and Natural Resource Sustainability in Africa. Springer, Cham. https://doi.org/10.1007/978-3-030-37537-9_1
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