Research article Special Issues

Towards Conservation Agriculture systems in Moldova

  • Received: 07 August 2016 Accepted: 10 October 2016 Published: 17 October 2016
  • As the world population and food production demands rise, keeping agricultural soils and landscapes healthy and productive are of paramount importance to sustaining local and global food security and the flow of ecosystem services to society. The global population, expected to reach 9.7 billion people by 2050, will put additional pressure on the available land area and resources for agricultural production. Sustainable production intensification for food security is a major challenge to both industrialized and developing countries. The paper focuses on the results from long-term multi-factorial experiments involving tillage practices, crop rotations and fertilization to study the interactions amongst the treatments in the context of sustainable production intensification. The paper discusses the results in relation to reported performance of crops and soil quality in Conservation Agriculture systems that are based on no or minimum soil disturbance (no-till seeding and weeding), maintenance of soil mulch cover with crop biomass and cover crops, and diversified cropping s involving annuals and perennials. Conservation Agriculture also emphasizes the necessity of an agro-ecosystems approach to the management of agricultural land for sustainable production intensification, as well as to the site-specificity of agricultural production. Arguments in favor of avoiding the use of soil tillage are discussed together with agro-ecological principles for sustainable intensification of agriculture. More interdisciplinary systems research is required to support the transformation of agriculture from the conventional tillage agriculture to a more sustainable agriculture based on the principles and practices of Conservation Agriculture, along with other complementary practices of integrated crop, nutrient, water, pest, energy and farm power management.

    Citation: Boris Boincean, Amir Kassam, Gottlieb Basch, Don Reicosky, Emilio Gonzalez, Tony Reynolds, Marina Ilusca, Marin Cebotari, Grigore Rusnac, Vadim Cuzeac, Lidia Bulat, Dorian Pasat, Stanislav Stadnic, Sergiu Gavrilas, Ion Boaghii. Towards Conservation Agriculture systems in Moldova[J]. AIMS Agriculture and Food, 2016, 1(4): 369-386. doi: 10.3934/agrfood.2016.4.369

    Related Papers:

  • As the world population and food production demands rise, keeping agricultural soils and landscapes healthy and productive are of paramount importance to sustaining local and global food security and the flow of ecosystem services to society. The global population, expected to reach 9.7 billion people by 2050, will put additional pressure on the available land area and resources for agricultural production. Sustainable production intensification for food security is a major challenge to both industrialized and developing countries. The paper focuses on the results from long-term multi-factorial experiments involving tillage practices, crop rotations and fertilization to study the interactions amongst the treatments in the context of sustainable production intensification. The paper discusses the results in relation to reported performance of crops and soil quality in Conservation Agriculture systems that are based on no or minimum soil disturbance (no-till seeding and weeding), maintenance of soil mulch cover with crop biomass and cover crops, and diversified cropping s involving annuals and perennials. Conservation Agriculture also emphasizes the necessity of an agro-ecosystems approach to the management of agricultural land for sustainable production intensification, as well as to the site-specificity of agricultural production. Arguments in favor of avoiding the use of soil tillage are discussed together with agro-ecological principles for sustainable intensification of agriculture. More interdisciplinary systems research is required to support the transformation of agriculture from the conventional tillage agriculture to a more sustainable agriculture based on the principles and practices of Conservation Agriculture, along with other complementary practices of integrated crop, nutrient, water, pest, energy and farm power management.


    加载中
    [1] Ovsinschi I (1909) New system of agriculture. Translation from Polish language, S. Sicorschi: 229 (Russian).
    [2] Trubetscoi PR (1913) 18th Report of Ploteansk Agricultural Station for 1912, Odessa: 380 (Russian).
    [3] Faulkner E (1959) Plowman’s Folly. University of Oklahoma. Press, Norman, OK.
    [4] Lester B (2012) Full planet, empty plates. The New Geopolitics of Food Scarcity. Earth Policy Institute, Agriculture at a Crossroads, IAASTD, Synthesis Report, USA, 81.
    [5] Lal R, Reicosky DC, Hanson JD (2007) Evolution of the plow over 10,000 years and the rationale for no-till farming. Soil Tillage Res 93: 1-12. doi: 10.1016/j.still.2006.11.004
    [6] Montgomery D (2015) Dirt. Erosion of civilizations. FAO, Ankara, 409 (Russian).
    [7] Jat R, Sahrawat K, Kassam A (2013) Conservation Agriculture: Global Prospects and Challenges. CABI, Wallingford, 393.
    [8] Corsi S, Friedrich T, Kassam A, et al. (2012) Soil organic carbon accumulation and carbon budget in conservation agriculture: a review of evidence. Integrated Crop Management Vol. 16. FAO, Rome, Italy.
    [9] Kassam A, Friedrich T, Shaxson F, et al. (2009) The spread of Conservation Agriculture: Justification, sustainability and uptake. Int J Agric Sustain 7: 292-320. doi: 10.3763/ijas.2009.0477
    [10] Friedrich T, Derpsch R, Kassam AH (2012) Overview of the global spread of Conservation Agriculture. Facts Rep Special Issue 6: 1-7.
    [11] Kassam A, Basch G, Friedrich T, et al. (2014) Sustainable soil management is more than what and how crops are grown. In: International Scientific Conference “The role of agriculture in providing ecosystem and social services”, Balti, November 25, 2014: 230-270.
    [12] Palm C, Blanco-Canqui H, DeClerk F, et al. (2014) Conservation agriculture and ecosystem services: An overview. Agric Ecosyst Environ 187: 87-105. doi: 10.1016/j.agee.2013.10.010
    [13] Izmailski AA (1937) How dried our steeps. Selihozgiz, Moscow, Leningrad: 75 (Russian).
    [14] Izmailski AA (1949) Selected works. State Publisher of Agricultural literature, Moscow: 335 (Russian).
    [15] Docuceaev VV (1948) Selected works. Vol. 1-2, Moscow (Russian).
    [16] Unger PW, Cassel DK (1991) Tillage implement disturbance effects on soil properties related to soil and water conservation: a literature review. Soil Till Res 19: 363-382. doi: 10.1016/0167-1987(91)90113-C
    [17] Lal R (2009) The plough and agricultural sustainability. J Sustain Agric 3: 66-87. doi: 10.1080/10440040802548555
    [18] Boincean BP (1999) Ecological agriculture in the Republic of Moldova (crop rotation and soil organic matter), Chisinau, Stiinta, 270 (Russian).
    [19] Sidorov MI, Vanicovici Gh, Coltun V, et al. (2006) Agriculture (textbook). Balti, University Press, 293 (Romanian).
    [20] Stebut IA (1957) Selected works. State Publisher of Agricultural Literature, Moscow, vol.2, 631.
    [21] Cole JS, Mathews R (1938) Tillage. In: Soil and Men. In Yearbook of agriculture, USA, 321-328.
    [22] Boincean BP (2013) Soil tillage for sustainable farming Systems. ProEnvironment. Journal of Documentation, Research and Professional Training. The 7th International Symposium “Soil Minimum Tillage Systems”, Cluj-Napoca, May 2-3, 2013, 194-198.
    [23] Boincean BP (2011) Soil tillage – tendencies and perspectives. Akademos 3: 61-67 (Romanian).
    [24] Licov AM, Makarov IP, Rassadin II, (1982) Methodological basis for the theory of soil tillage in intensive agriculture. Agriculture 6: 14-17 (Russian).
    [25] Puponin AI, Kiriusin BD (1989) Minimalization of soil tillage. Information review, Moscow, 55 (Russian).
    [26] Kant G (1980) Agriculture without plough. Moscow, Kolos, 156 (Russian).
    [27] Soane BD, Ball BC, Arvidsson J, et al. (2012) No-till in northern, western and south-western Europe: A review of problems and opportunities for crop production and the environment. Soil Till Res 118: 66-87. doi: 10.1016/j.still.2011.10.015
    [28] Gonsalez-Sanchez EJ, Veroz-Gonsalez O, Blanco-Roldan GL, et al. (2014) A renewed view of conservation agriculture and its evolution over the last decade in Spain. Soil Till Res 146: 204-212. doi: 10.1016/j.still.2014.10.016
    [29] Boincean BP, Kassam A (2014) Soil Fertility and productivity under different crop rotations and systems of fertilization in the Balti steppe of Moldova. In: European Conference – Green Carbon: Making Sustainable Agriculture Real. Book of Abstracts. Brussels, April 1-3, 2014, 34.
    [30] Pittelkow CM, Liang X, Bruce A, et al. (2014) Productivity limits and potentials of the principles of conservation agriculture. Letter, Nature, Macmillan Publisher Limited, 4.
    [31] Pretty J, Bharucha ZP (2014) Sustainable intensification in agricultural systems. Ann Bot 114: 1571-1596. doi: 10.1093/aob/mcu205
    [32] Chibasov PT (1982) Soil tillage for field crops. Chisinau, Cartea Moldoveneasca, 235 (Russian).
    [33] Rotmistrov VG (1913) The essence of the drought. According the data from Odessa Experimental Field, Odessa, 66 (Russian).
    [34] Kosticev PA (1892) Soil tillage and fertilization of chernozem soil. Publisher A.F. Devrien, Sanct-Petersburg, 303 (Russian).
    [35] Krauze M (1931) Soil tillage as yield factor. Leningrad, State Publisher of agriculture and kolhoz-cooperativ literature, 296 (Russian).
    [36] Dent D (2014) Soil as World Heritage. Springer Dordrecht Heidelberg, New York, London, 501.
    [37] Sidorov MI (1981) Soil fertility and soil tillage. Central-chernozem Book Publisher, Voronej, 95 (Russian).
    [38] Wolny E (1902) La decomposition des matieres organiques et la forms d’humus dans leurs raports avec l’agriculture, Paris, 657.
    [39] Magdoff F, van Es H (2000) Building soils for better crops. Second edition: Sustainable Agriculture Network, USA, 229.
    [40] Bardgett RD, Tardy V, Spor A, et al. (2015) Shifts in microbial diversity through land use intensity as drivers of carbon mineralization in soil. Soil Biol Biochem 90: 204-213. doi: 10.1016/j.soilbio.2015.08.010
    [41] Williams VR (1950-1952) Complete works. Volumes 5, 6, 10. Moscow, State Publisher of Agricultural Literature.
    [42] Misustin EN, Teper EZ (1963) The influence of long-term crop rotation, monoculture and fertilizers on the composition of soil microorganisms. Izvestia TSHA 6: 85-92 (Russian).
    [43] Russel E (1955) Soil conditions and crop growing. The Publisher of Foreign literature, Moscow, 623 (Russian).
    [44] Sokolovschi AN (1956) Agricultural soil science. Selihozgiz, Moscow, 335 (Russian).
    [45] Gliessman SR (2000) Agroecology. Ecological process in sustainable agriculture. Lewis Publisher. CRC Press LLC, Boca Raton, USA, 357.
    [46] Khan SA, Mulvaney RL, Ellsworth TR, et al. (2007) The myth of nitrogen fertilization for soil carbon sequestration. Environ Qual 36: 1821-1832. doi: 10.2134/jeq2007.0099
    [47] Albrecht WA (1938) Loss of soil organic matter and its restoration. In: Soil and Men, Yearbook of Agriculture, USA, 341-360.
    [48] Fokin AD (1994) Regarding the role of soil organic matter in the functioning of natural and agricultural ecosystems. Soil Sci 4: 40-45 (Russian).
    [49] Kononova MA (1963) Soil organic matter. Publisher Academy of Sciences of USSR, Moscow, 313 (Russian).
    [50] Licov AM, Esikov AI, Novikov MN (2004) Soil organic matter of arable non-black soils. Russian Academy of Agricultural Sciences, 630 (Russian).
    [51] Puponin AI (1979) Scientific and practical basis of minimum soil tillage. Izvestia TSHA, №2, 10-18 (Russian).
    [52] Boincean BP, Bulat LI, Boaghi IV (2010) Interaction between soil tillage, alternation of crops and soil fertilization. In: “Resource conserving technologies for soil tillage in the adaptive agriculture”. Materials of the All-Russian scientific-practical conference, Moscow Agricultural Academy by name of K.A. Timiriazev, 6-12.
    [53] Boincean BP (1982) The processes of soil organic matter transformation for intensively tillagedpodzol soils and the productivity of field crops. Dissertation on the scientific title candidate of agricultural sciences. Moscow Agricultural Academy by name of K.A. Timiriazev (Russian).
    [54] Bruce RR, Hendrix PF, Langdale GW (1991) Role of cover crops in recovery and maintenance of soil productivity. In: W. L. Hargrove (ed.). Cover Crops for Clean Water. Soil and Water Conservation Society. Ankeny, Iowa, 109-114.
    [55] Franzluebbers AJ, Stuedemann JA (2015) Does grazing of cover crops impact biologically active soil carbon and nitrogen fractions under inversion or no tillage management? J Soil Water Conserv 70:365-373. doi: 10.2489/jswc.70.6.365
    [56] Mulvaney RL, Khan SA, Ellsworth TR (2009) Synthetic nitrogen fertilizers deplete soil nitrogen: a global dilemma of sustainable cereal production. Environ Qual 38: 2295-2314. doi: 10.2134/jeq2008.0527
    [57] Boincean BP, Lal R, Kassam A, et al. (2014) Resolution of the International Scientific Conference “The role of agriculture in providing ecosystem and social services”, Balti, Republic of Moldova, November 25, 2014, Agriculture of Moldova, №9-10, 15-17.
    [58] Kassam A, Friedrich T, Derpsch R, et al. (2015) Overview of the worldwide spread of Conservation Agriculture. Field Actions Sci Rep (Online) 8.
  • Reader Comments
  • © 2016 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)
通讯作者: 陈斌, bchen63@163.com
  • 1. 

    沈阳化工大学材料科学与工程学院 沈阳 110142

  1. 本站搜索
  2. 百度学术搜索
  3. 万方数据库搜索
  4. CNKI搜索

Metrics

Article views(5720) PDF downloads(1218) Cited by(2)

Article outline

Figures and Tables

Tables(3)

/

DownLoad:  Full-Size Img  PowerPoint
Return
Return

Catalog