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2022 Volume 2
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REVIEW   Open Access    

A sustainable way of increasing productivity of coconut cultivation using cover crops: A review

  • 1.

    Agronomy Division, Coconut Research Institute, Bandirippuwa Estate, Lunuwila 61150, Sri Lanka

More Information
  • Coconut, as one of the main components of the daily Sri Lankan diet and one of the predominant crops grown in different agroecological zones except in higher elevations, has become a major export-earning crop. Its productivity is limited by adverse climatic changes in coconut growing areas, biotic and abiotic stresses, and poor agronomic practices. Cover cropping has been identified as a rewarding and time-tested farming solution that increases the productivity of most coconut land while addressing the above issues. It is the practice of growing plants for modifying soil properties, controlling pests and diseases, facilitating crop growth and yield, reducing chemical dependency, enabling the coconut-animal farming system, and generating extra profit. Legumes, fodder and pasture grasses have been identified as the common and trending cover crops for Sri Lanka. Comprehensive knowledge of selecting suitable cover crops, planting materials and proper agronomic practices are important for a successful cover cropping system under coconut. Farmers avoid this practice due to their ignorance on cover cropping, and its benefits, and due to the aggressive characteristics of cover crops such as reappearing behaviour, being an alternative host for pathogens, and competitiveness for natural resources. In this review, the unique attributes of common cover crop species are explained. Furthermore, the variety of on-farm benefits and ecosystem services of cover cropping and some important agronomic considerations are reviewed. Finally, future research potential for recommending new species and their adaptability to a wide range of ecological and ecosystem circumstances under coconut cultivation are investigated.
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  • [1]

    Thomas GV, Krishnakumar V, Dhanapal R, Srinivasa Reddy DV. 2018. Agro-management practices for sustainable coconut production. In The Coconut Palm (Cocos nucifera L. ) - Research and Development Perspectives, eds. Krishnakumar V, Thampan PK, Nair MA. Singapore: Springer. pp. 227–322 https://doi.org/10.1007/978-981-13-2754-4_7
    [2]

    Godage RSW, Gajanayake B, Jayasinghe-Mudalige UK. 2021. Coconut growers knowledge, perception and adoption on impacts of climate change in Gampaha and Puttalam Districts in Sri Lanka: An index-based approach. Current Research in Agricultural Sciences 8:97−109

    doi: 10.18488/journal.68.2021.82.97.109

    CrossRef   Google Scholar

    [3]

    Pathiraja E, Griffith G, Farquharson B, Faggian R. 2017. The Economic cost of climate change and the benefits from investments in adaptation options for Sri Lankan coconut value chains. Proceedings in System Dynamics and Innovation in Food Networks, 2017, CentMa, International Center for Management, Communication and Research, Kiel, Innsbruck-Igls, Austria. pp. 460–85 https://doi.org/10.18461/pfsd.2017.1746
    [4]

    Herath HMPM, Herath HMIK, Ratnayake WM. 2017. Potential use of Mucuna bracteate as a cover crop for coconut plantations in the low country intermediate zone of Sri Lanka. Journal of Food and Agriculture 10:26−34

    doi: 10.4038/jfa.v10i1-2.5210

    CrossRef   Google Scholar

    [5]

    Atapattu AAAJ, Senarathne SHS, Raveendra SAST, Egodawatte WCP, Mensah S. 2017. Effect of short term agroforestry systems on soil quality in marginal coconut lands in Sri Lanka. Agricultural Research Journal 54:324−28

    doi: 10.5958/2395-146X.2017.00060.6

    CrossRef   Google Scholar

    [6]

    Herath HMIK, Silva HM, Synthya PG, Vidhana Arachchi LP. 2016. Impact of cover crops on soil quality parameters of coconut (Cocos nucifera L.) grown red yellow podzolic soil. Journal of Food and Agriculture 9:14−23

    doi: 10.4038/jfa.v9i1-2.5203

    CrossRef   Google Scholar

    [7]

    Kumaragamage D, Indraratne SP. 2011. Systematic approach to diagnosing fertility problems in soils of Sri Lanka. Communications in Soil Science and Plant Analysis 42:2699−715

    doi: 10.1080/00103624.2011.622818

    CrossRef   Google Scholar

    [8]

    Peiris TSG, Hansen JW, Zubair L. 2007. Use of seasonal climate information to predict coconut production in Sri Lanka. International Journal of Climatology 28:103−10

    doi: 10.1002/joc.1517

    CrossRef   Google Scholar

    [9]

    Scholberg JMS, Dogliotti S, Leoni C, Cherr CM, Zotarelli L, et al. 2010. Cover crops for sustainable agrosystems in the Americas. In Genetic engineering, biofertilisation, soil quality and organic farming, ed. Lichtfouse E. Netherlands: Springer. pp. 23–58 https://doi.org/10.1007/978-90-481-8741-6_2
    [10]

    Sharma P, Singh A, Kahlon CS, Brar AS, Grover KK, et al. 2018. The role of cover crops towards sustainable soil health and agriculture: A review paper. American Journal of Plant Sciences 9:1935−51

    doi: 10.4236/ajps.2018.99140

    CrossRef   Google Scholar

    [11]

    He H, Liu L, Munir S, Bashir NH, Wang Y, et al. 2019. Crop diversity and pest management in sustainable agriculture. Journal of Integrative Agriculture 18:1945−52

    doi: 10.1016/S2095-3119(19)62689-4

    CrossRef   Google Scholar

    [12]

    Haramoto ER, Gallandt ER. 2004. Brassica cover cropping for weed management: A review. Renewable Agriculture and Food Systems 19:187−98

    doi: 10.1079/RAFS200490

    CrossRef   Google Scholar

    [13]

    Premarathne S, Samarasinghe K. 2020. Animal feed production in Sri Lanka: Past, present and future. In Agricultural Research for Sustainable Food Systems in Sri Lanka, eds. Marambe B, Weerahewa J, Dandeniya WS, Vol. 1. Singapore: Springer. pp. 277–301 https://doi.org/10.1007/978-981-15-2152-2_12
    [14]

    Raveendra SAST, Nissanka SP, Somasundaram D, Atapattu AJ, Mensah S. 2021. Coconut-gliricidia mixed cropping systems improve soil nutrients in dry and wet regions of Sri Lanka. Agroforestry Systems 95:307−19

    doi: 10.1007/s10457-020-00587-2

    CrossRef   Google Scholar

    [15]

    Senarathne SHS, Atapattu AJ, Raveendra T, Mensah S, Dassanayake KB. 2019. Biomass allocation and growth performance of Tithonia diversifolia (Hemsl.) A. Gray in coconut plantations in Sri Lanka. Agroforestry Systems 93:1865−75

    doi: 10.1007/s10457-018-0290-y

    CrossRef   Google Scholar

    [16]

    Reddy PP. (Ed) 2017. Cover/green manure cropping. In Agro-ecological Approaches to Pest Management for Sustainable Agriculture. Singapore: Springer. pp. 91–107 https://doi.org/10.1007/978-981-10-4325-3_7
    [17]

    Hartwig NL, Ammon HU. 2002. Cover crops and living mulches. Weed Science 50:688−99

    doi: 10.1614/0043-1745(2002)050[0688:AIACCA]2.0.CO;2

    CrossRef   Google Scholar

    [18]

    Haruna SI, Anderson SH, Udawatta RP, Gantzer CJ, Phillips NC, et al. 2020. Improving soil physical properties through the use of cover crops: A review. Agrosystems, Geosciences & Environment 3:e20105

    doi: 10.1002/agg2.20105

    CrossRef   Google Scholar

    [19]

    Osipitan OA, Dille JA, Assefa Y, Knezevic SZ. 2018. Cover crop for early season weed suppression in crops: Systematic review and meta-analysis. Agronomy Journal 110:2211−21

    doi: 10.2134/agronj2017.12.0752

    CrossRef   Google Scholar

    [20]

    Sturm DJ, Peteinatos G, Gerhards R. 2018. Contribution of allelopathic effects to the overall weed suppression by different cover crops. Weed Research 58:331−37

    doi: 10.1111/wre.12316

    CrossRef   Google Scholar

    [21]

    Sias C, Wolters BR, Reiter MS, Flessner ML. 2021. Cover crops as a weed seed bank management tool: A soil down review. Italian Journal of Agronomy 16:1852

    doi: 10.4081/ija.2021.1852

    CrossRef   Google Scholar

    [22]

    Senarathne SHS, Udumann SS. 2019. Effect of different weed management strategies on population changing pattern of Pennisetum polystachion in coconut plantations of Sri Lanka. CORD 35:43−50

    doi: 10.37833/cord.v35i01.12

    CrossRef   Google Scholar

    [23]

    Senarathne SHS, Sangakkara UR, Raveendra SAST. 2015. Weed biomass and seedling emergence patterns as affected by different ground cover management systems in coconut plantations of Asian humid tropics Sri Lanka. International Journal of Research in Agricultural Sciences 2:245−52

    Google Scholar

    [24]

    Larkin RP, Griffin TS. 2007. Control of soilborne potato diseases using Brassica green manures. Crop Protection 26:1067−77

    doi: 10.1016/j.cropro.2006.10.004

    CrossRef   Google Scholar

    [25]

    Daryanto S, Fu B, Wang L, Jacinthe PA, Zhao W. 2018. Quantitative synthesis on the ecosystem services of cover crops. Earth-Science Reviews 185:357−73

    doi: 10.1016/j.earscirev.2018.06.013

    CrossRef   Google Scholar

    [26]

    Irmak S, Sharma V, Mohammed AT, Djaman K. 2018. Impacts of cover crops on soil physical properties: Field capacity, permanent wilting point, soil-water holding capacity, bulk density, hydraulic conductivity, and infiltration. Transactions of the ASABE 61:1307−21

    doi: 10.13031/trans.12700

    CrossRef   Google Scholar

    [27]

    Blanco-Canqui H. 2018. Cover crops and water quality. Agronomy Journal 110:1633−47

    doi: 10.2134/agronj2018.02.0077

    CrossRef   Google Scholar

    [28]

    Dinesh R, Ghoshal Chaudhuri S, Sheeja TE, Shiva KN. 2009. Soil microbial activity and biomass is stimulated by leguminous cover crops. Journal of Plant Nutrition and Soil Science 172:288−96

    doi: 10.1002/jpln.200700300

    CrossRef   Google Scholar

    [29]

    Abdalla M, Hastings A, Cheng K, Yue Q, Chadwick, D, et al. 2019. A critical review of the impacts of cover crops on nitrogen leaching, net greenhouse gas balance and crop productivity. Global Change Biology 25:2530−43

    doi: 10.1111/gcb.14644

    CrossRef   Google Scholar

    [30]

    Delgado JA, Barrera Mosquera VH, Alwang JR, Villacis-Aveiga A, Cartagena Ayala YE, et al. 2021. Potential use of cover crops for soil and water conservation, nutrient management, and climate change adaptation across the tropics. In Advances in Agronomy, ed. Sparks DL. vol. 165. UK: Academic Press, Elsevier. pp. 175–247 https://doi.org/10.1016/bs.agron.2020.09.003
    [31]

    Mitchell JP, Shrestha A, Mathesius K, Scow KM, Southard RJ, et al. 2017. Cover cropping and no-tillage improve soil health in an arid irrigated cropping system in California's San Joaquin Valley, USA. Soil and Tillage Research 165:325−35

    doi: 10.1016/j.still.2016.09.001

    CrossRef   Google Scholar

    [32]

    Basche AD, Kaspar TC, Archontoulis SV, Jaynes DB, Sauer TJ, et al. 2016. Soil water improvements with the long-term use of a winter rye cover crop. Agricultural Water Management 172:40−50

    doi: 10.1016/j.agwat.2016.04.006

    CrossRef   Google Scholar

    [33]

    Kaspar TC, Singer JW. 2015. The use of cover crops to manage soil. In Soil Management: Building a Stable Base for Agriculture, eds. Hatfield JL, Sauer TJ. US: John Wiley & Sons. pp. 321–37 https://doi.org/10.2136/2011.soilmanagement.c21
    [34]

    Kim N, Zabaloy MC, Guan K, Villamil MB. 2020. Do cover crops benefit soil microbiome? A meta-analysis of current research Soil Biology and Biochemistry 142:107701

    doi: 10.1016/j.soilbio.2019.107701

    CrossRef   Google Scholar

    [35]

    Vukicevich E, Lowery T, Bowen P, Úrbez-Torres JR, Hart M. 2016. Cover crops to increase soil microbial diversity and mitigate decline in perennial agriculture: A review. Agronomy for Sustainable Development 36:48

    doi: 10.1007/s13593-016-0385-7

    CrossRef   Google Scholar

    [36]

    Singh G, Mukerji KG. 2006. Root Exudates as determinant of rhizospheric microbial biodiversity. In Microbial Activity in the Rhizoshere. Soil Biology, eds. Mukerji KG, Manoharachary C, Singh J. Vol. 7. Heidelberg: Springer, Berlin. pp. 39–53. https://doi.org/10.1007/3-540-29420-1_3
    [37]

    Badri DV, Vivanco JM. 2009. Regulation and function of root exudates. Plant, Cell & Environment 32:666−681

    doi: 10.1111/j.1365-3040.2009.01926.x

    CrossRef   Google Scholar

    [38]

    Lange M, Habekost M, Eisenhauer N, Roscher C, Bessler H, et al. 2014. Biotic and abiotic properties mediating plant diversity effects on soil microbial communities in an experimental grassland. PLoS ONE 9:e96182

    doi: 10.1371/journal.pone.0096182

    CrossRef   Google Scholar

    [39]

    Ghimire R, Ghimire B, Mesbah AO, Idowu OJ, O’Neill MK, et al. 2018. Current status, opportunities, and challenges of cover cropping for sustainable dryland farming in the Southern Great Plains. Journal of Crop Improvement 32:579−98

    doi: 10.1080/15427528.2018.1471432

    CrossRef   Google Scholar

    [40]

    Senarathne SHS, Udumann SS. 2022. Effect of selected leguminous cover crop species on the productivity of coconut cultivated in reddish brown latosolic soils in Sri Lanka. CORD 37:33−44

    doi: 10.37833/cord.v37i.435

    CrossRef   Google Scholar

    [41]

    Baligar VC, Fageria NK. 2007. Agronomy and physiology of tropical cover crops. Journal of Plant Nutrition 30:1287−339

    doi: 10.1080/01904160701554997

    CrossRef   Google Scholar

    [42]

    Blanco-Canqui H, Drewnoski ME, MacDonald JC, Redfearn DD, Parsons J, et al. 2020. Does cover crop grazing damage soils and reduce crop yields. Agrosystems, Geosciences & Environment 3:e20102

    doi: 10.1002/agg2.20102

    CrossRef   Google Scholar

    [43]

    Ramos ME, Altieri MA, Garcia PA, Robles AB. 2011. Oat and oat-vetch as rainfed fodder-cover crops in semiarid environments: Effects of fertilization and harvest time on forage yield and quality. Journal of Sustainable Agriculture 35:726−44

    doi: 10.1080/10440046.2011.606490

    CrossRef   Google Scholar

    [44]

    Moll HAJ, Staal SJ, Ibrahim MNM. 2007. Smallholder dairy production and markets: A comparison of production systems in Zambia, Kenya and Sri Lanka. Agricultural Systems 94:593−603

    doi: 10.1016/j.agsy.2007.02.005

    CrossRef   Google Scholar

    [45]

    Ramirez-Garcia J, Gabriel JL, Alonso-Ayuso M, Quemada M. 2015. Quantitative characterization of five cover crop species. The Journal of Agricultural Science 153:1174−85

    doi: 10.1017/S0021859614000811

    CrossRef   Google Scholar

    [46]

    Mertens DR, Grant RJ. 2020. Digestibility and intake. In Forages: The Science of Grassland Agriculture, eds. Moore KJ, Collins M, Nelson CJ, Redfearn DD. Vol. 2, 7th Edition. UK: John Wiley & Sons. pp. 609–31. https://doi.org/10.1002/9781119436669.ch34
    [47]

    Mutimura M, Ghimire S. 2021. Brachiaria grass for sustainable livestock production in rwanda under climate change. In Handbook of Climate Change Management, eds. Leal Filho W, Luetz J, Ayal D. Switzerland: Springer, Cham. pp. 1–17. https://doi.org/10.1007/978-3-030-22759-3_314-1
    [48]

    Atapattu AAAJ, Pushpakumara DKNG, Rupasinghe WMD, Senarathne SHS, Raveendra SAST. 2017. Potential of Gliricidia sepium as a fuelwood species for sustainable energy generation in Sri Lanka. Agricultural Research Journal 54:34−39

    doi: 10.5958/2395-146X.2017.00006.0

    CrossRef   Google Scholar

    [49]

    Kaye JP, Quemada M. 2017. Using cover crops to mitigate and adapt to climate change: A review. Agronomy for Sustainable Development 37:4

    doi: 10.1007/s13593-016-0410-x

    CrossRef   Google Scholar

    [50]

    Advisory Circular No A 10. 2018. Cultivation of cover crops in coconut land. Coconut Research Institute of Sri Lanka. https://cri.gov.lk/wp-content/uploads/2021/10/a10.pdf
    [51]

    Nielsen DC, Lyon DJ, Higgins RK, Hergert GW, Holman JD, et al. 2016. Cover crop effect on subsequent wheat yield in the Central Great Plains. Agronomy Journal 108:243−56

    doi: 10.2134/agronj2015.0372

    CrossRef   Google Scholar

    [52]

    Clark A (ed). 2008. Managing Cover Crops Profitably. 3rd Edition. USA: Sustainable Agriculture Network (SAN). 248 pp
    [53]

    Singh A, Kang JS, Singh H. 2016. Growth and development of baby corn (Zea mays L.) as influenced by non-leguminous forage cover crops and their spell of chopping under conservation agriculture. Research on Crops 17:679−84

    doi: 10.5958/2348-7542.2016.00114.5

    CrossRef   Google Scholar

    [54]

    Dabney SM, Delgado JA, Reeves DW. 2001. Using winter cover crops to improve soil and water quality. Communications in Soil Science and Plant Analysis 32:1221−50

    doi: 10.1081/CSS-100104110

    CrossRef   Google Scholar

    [55]

    Choudhury BI, Khan ML, Das AK. 2009. Seed dormancy and germination in Gymnocladus assamicus: An endemic legume tree from Northeast India. Seed Science and Technology 37:582−88

    doi: 10.15258/sst.2009.37.3.07

    CrossRef   Google Scholar

    [56]

    de Morais LF, Almeida JCC, Deminicis BB, de Pádua FT, Morenz MJF, et al. 2014. Methods for breaking dormancy of seeds of tropical forage legumes. American Journal of Plant Sciences 5:1831−35

    doi: 10.4236/ajps.2014.513196

    CrossRef   Google Scholar

    [57]

    Qiu Y, Amirkhani M, Mayton H, Chen Z, Taylor AG. 2020. Biostimulant seed coating treatments to improve cover crop germination and seedling growth. Agronomy 10:154

    doi: 10.3390/agronomy10020154

    CrossRef   Google Scholar

    [58]

    Koehler-Cole K, Elmore RW. 2020. Seeding rates and productivity of broadcast interseeded cover crops. Agronomy 10:1723

    doi: 10.3390/agronomy10111723

    CrossRef   Google Scholar

    [59]

    Haramoto ER. 2019. Species, seeding rate, and planting method influence cover crop services prior to soybean. Agronomy Journal 111:1068−78

    doi: 10.2134/agronj2018.09.0560

    CrossRef   Google Scholar

    [60]

    Atapattu AAAJ, Raveendra SAST, Pushpakumara DKNG, Rupasinghe WMD. 2017. Regeneration potential of Gliricidia Sepium (Jacq.) Kunth Ex Walp. as a fuelwood species. Indian Journal of Plant Sciences 6:32−39

    Google Scholar

    [61]

    Belfry KD, Van Eerd LL. 2016. Establishment and impact of cover crops intersown into corn. Crop Science 56:1245−56

    doi: 10.2135/cropsci2015.06.0351

    CrossRef   Google Scholar

    [62]

    Nascente AS, Crusciol CAC, Cobucci T, Velini ED. 2013. Cover crop termination timing on rice crop production in a no-till system. Crop Science 53:2659−69

    doi: 10.2135/cropsci2013.01.0047

    CrossRef   Google Scholar

    [63]

    Lu YC, Watkins KB, Teasdale JR, Abdul-Baki AA. 2000. Cover crops in sustainable food production. Food Reviews International 16:121−57

    doi: 10.1081/FRI-100100285

    CrossRef   Google Scholar

    [64]

    Palhano MG, Norsworthy JK, Barber T. 2018. Evaluation of chemical termination options for cover crops. Weed Technology 32:227−35

    doi: 10.1017/wet.2017.113

    CrossRef   Google Scholar

    [65]

    Ortiz Ceballos AI, Aguirre Rivera JR, Osorio Arce MM, Pea C. 2012. Velvet bean (Mucuna pruriens var. utilis) a cover crop as bioherbicide to preserve the environmental services of soil. In Herbicides - Environmental Impact Studies and Management Approaches, ed. Alvarez-Fernandez R. London: IntechOpen. pp. 167–84 https://doi.org/10.5772/31833
    [66]

    Osterholz WR, Culman SW, Herms C, Joaquim de Oliveira F, Robinson A, et al. 2021. Knowledge gaps in organic research: understanding interactions of cover crops and tillage for weed control and soil health. Organic Agriculture 11:13−25

    doi: 10.1007/s13165-020-00313-3

    CrossRef   Google Scholar

    [67]

    Soti P, Racelis A. 2020. Cover crops for weed suppression in organic vegetable systems in semiarid subtropical Texas. Organic Agriculture 10:429−36

    doi: 10.1007/s13165-020-00285-4

    CrossRef   Google Scholar

  • Cite this article

    Dissanayaka DMNS, Nuwarapaksha TD, Udumann SS, Dissanayake DKRPL, Atapattu AJ. 2022. A sustainable way of increasing productivity of coconut cultivation using cover crops: A review. Circular Agricultural Systems 2:7 doi: 10.48130/CAS-2022-0007
    Dissanayaka DMNS, Nuwarapaksha TD, Udumann SS, Dissanayake DKRPL, Atapattu AJ. 2022. A sustainable way of increasing productivity of coconut cultivation using cover crops: A review. Circular Agricultural Systems 2:7 doi: 10.48130/CAS-2022-0007
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REVIEW   Open Access    

A sustainable way of increasing productivity of coconut cultivation using cover crops: A review

  • 1.

    Agronomy Division, Coconut Research Institute, Bandirippuwa Estate, Lunuwila 61150, Sri Lanka

  • Received: 06 July 2022
  • Accepted: 19 October 2022
  • Published online: 17 November 2022
Circular Agricultural Systems  2 Article number: 7  (2022)  |  Cite this article

Abstract: Coconut, as one of the main components of the daily Sri Lankan diet and one of the predominant crops grown in different agroecological zones except in higher elevations, has become a major export-earning crop. Its productivity is limited by adverse climatic changes in coconut growing areas, biotic and abiotic stresses, and poor agronomic practices. Cover cropping has been identified as a rewarding and time-tested farming solution that increases the productivity of most coconut land while addressing the above issues. It is the practice of growing plants for modifying soil properties, controlling pests and diseases, facilitating crop growth and yield, reducing chemical dependency, enabling the coconut-animal farming system, and generating extra profit. Legumes, fodder and pasture grasses have been identified as the common and trending cover crops for Sri Lanka. Comprehensive knowledge of selecting suitable cover crops, planting materials and proper agronomic practices are important for a successful cover cropping system under coconut. Farmers avoid this practice due to their ignorance on cover cropping, and its benefits, and due to the aggressive characteristics of cover crops such as reappearing behaviour, being an alternative host for pathogens, and competitiveness for natural resources. In this review, the unique attributes of common cover crop species are explained. Furthermore, the variety of on-farm benefits and ecosystem services of cover cropping and some important agronomic considerations are reviewed. Finally, future research potential for recommending new species and their adaptability to a wide range of ecological and ecosystem circumstances under coconut cultivation are investigated.

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    Introduction

    • Coconut (Cocos nucifera L.), is a palm listed under the Arecaceae family and is a predominant agricultural crop in tropical regions globally. The 'Tree of Life' is a term used worldwide to describe the utility of all parts of the coconut tree (as a source of drink, food, oil, construction materials, fiber, charcoal, etc.). Asia, Oceania, West Indies, and some parts of the African, and American regions are considered prevalent coconut-growing regions. The majority of coconut production however comes from Asia and the Pacific regions[1]. Demand for coconut nuts and related products. is steadily increasing in the international market.

      The Sri Lankan coconut industry is expanding rapidly, with nearly around 400,000 hectares across the island giving 3,086 million nut yields in 2019, making it the world's fourth-largest producer[2]. In Sri Lanka, it is popular as 'Kapruka', which has become an essential component in Sri Lankan culture. Significant large-scale coconut plantations, covering more than 57% of arable coconut farm land, occur in the 'coconut triangle' of Sri Lanka, including the administrative districts of Kurunegala, Gampaha, and Puttalam. Furthermore, the Southern province, known as the 'mini-coconut triangle', contains around 12% of coconut cultivating land[3]. Although coconut can be grown in most of the areas on the island below the elevation level of 750 m amsl, coastal areas in the wet and intermediate zones in Sri Lanka with high humidity, 1,250–2,500 mm average mean annual precipitation and 27 to 29 °C average annual temperature are the best[2,4] .

      Long-term coconut cultivation will degrade soil quality due to less adoption of recommended practices such as fertilization, soil, and moisture conservation methods leading to less coconut yield[5,6]. Most of the Sri Lankan agricultural soils show deficiencies in available nutrient content including nitrogen, potassium, phosphorus, boron, sulfur, calcium, and magnesium, but high levels of iron[7]. Since the majority of local coconut-growing soils are sandy, such incidences can occur regularly[1]. Other than that, climate changes in coconut growing areas, poor agronomic practices, and biotic and abiotic stresses (pest, diseases, drought, and heat stresses) are key factors influencing the nut yield[8]. Strategic priorities should be taken to address these issues while increasing coconut productivity. Cover cropping is one of the most rewarding and time-tested farming solutions that can be easily utilised to address to some of above mentioned issues, mainly related to infertile soil and less productivity in coconut cultivation[4,9].

      Cover crops are the variety of plant species used to cover the soil surface[10]. It is a live plant, established before or after the cash crop and has a shorter life cycle than the main crop[11]. According to some reports, crops from Poaceae and Fabaceae families such as cereals, grasses, and legumes and crops from the Brassicaceae family have high potential to be a cover crops globally[6,12]. Depending on the climatic conditions in Sri Lanka, legumes, fodder and pasture grasses have been identified as commonly used and trending cover crops, especially for coconut cultivations (Table 1; Fig. 1).

      Table 1.  High potential cover crops for Sri Lankan coconut land[6,1315].

      FamilyScientific nameCommon nameLife spanGrowing habit
      FabaceaePueraria phaseoloidesPueroPerennialClimber or creeper
      Calopogonium mucunoidesCalopoPerennialClimber or creeper
      Centrosema pubescensCentroPerennialClimber or creeper
      Macroptilium atropurpureumSiratroPerennialClimber or creeper
      Mucuna spp.MucunaPerennialClimber or creeper
      Gliricidia sepiumGliricidiaPerennialTree
      Gliricidia maculataGliricidiaPerennialTree
      Leucaena leucocephalaIpil-ipilPerennialTree
      Tithonia diversifoliaWild sunflowerPerennialShrub
      Crotalaria junceaSunn hempAnnualHerb
      PoaceaeBrachiaria brizanthaSignal grassPerennialHerb
      Brachiaria ruziziensisRuzi grassPerennialHerb
      Brachiaria milliformisCori grassPerennialHerb
      Zea maysFodder-maizeAnnualHerb

      Figure 1. 

      Widely cultivated cover crop species in Sri Lanka. (a) Pueraria phaseoloides Roxb. (b) Calopogonium mucunoides. (c) Centrosema pubescens. (d) Macroptilium atropurpureum. (e) Gliricidia sepium. (f) Gliricidia maculata. (g) Tithonia diversifolia. (h) Leucaena leucocephala. (i) Brachiaria brizantha. (j) Brachiaria ruziziensis. (k) Brachiaria milliformis. (l) Zea mays.

      The objectives of this review are to review and understand the current state of knowledge on: (1) benefits of cover cropping in coconut plantations; and (2) planting and management of cover crops in coconut plantations for optimization of the national coconut productivity and land productivity through cover cropping.

    Advantages of cover cropping

      Living ground cover for crop protection

    • Generally, growing cover crops is one of the most effective and cost-effective ways to control pests, diseases, nematode incidence, and weeds in the agricultural field[16]. As a result, there will be less dependence on chemicals, such as pesticides, herbicides, and insecticides, a reduction in production costs, profit maximization, and food safety and environmental safety[17,18]. Cover crops can suppress weeds in the fields which compete for resources such as sunlight and nutrients, modifying soil temperature and moisture by producing allelopathic exudates, smothering, competition and modifying seed environments[19,20]. Allelochemicals are the biochemical of a particular plant that has an ability to stimulate or inhibit the growth of another plant. Since those plants behave as a mulch on the ground surface or act as a smother plant, the amount of light that reaches the soil can be easily controlled and heat absorption will be prevented[21]. Weed seeds are unable to germinate as a result of these conditions. But, the effectiveness of weed suppression varies with the cover crop species (Table 2).

      Table 2.  Weed suppression percentage by different cover crop species in a cotton field[16].

      Cover crop speciesSuppression % of
      grassy weeds      		Suppression % of
      broad-leaf weeds
      Calopogonium mucunoides496
      Mucuna spp.793
      Crotalaria juncea991
      No cover cropped land1981

      In the Sri Lankan context, it has been demonstrated that cover cropping (with for example, Pueraria phaseoloides) has similar effects as herbicides (glyphosate) for controlling weeds and is more effective than mechanical weed control methods such as harrowing, slashing, and ploughing in coconut plantations[22,23] (Fig. 2).

      Figure 2. 

      Comparison of different weed control methods in coconut plantations[22].

      Growing cover crops with coconut palms may extend the length of a crop rotation for breaking the regular pest cycles, modify the soil structure for enhancing the soil health, act as a barrier for protecting soil cover from other pests and pathogen carriers such as farm equipment, labor, and other crop materials and it also increases the colonization of non-harmful, pathogen suppressive fungi which results in the control of pests and pathogens[16]. Moreover, the flowering cover crop species attract predatory and beneficial insects including pollinators, lacewings, ladybirds, hoverflies, and parasitic wasps to the field due to the provision of nectar and pollen[16]. This will promote pollination activities of crops in addition to suppressing diseases and pests occurrences. Cover crops take two routes to protect the main crop from diseases and nematode activity. The first is the production of toxic elements such as glucosinolates and the bio-fumigation process, both of which can have a direct impact on pathogens[24]. The second is the provision of organic substrates to ensure better growth of beneficial microbes on the field, particularly bacteria, nonpathogenic Fusarium species, Actinomycetes, and Streptomyces communities[16].

      The impact of cover cropping on soil characteristics

    • Cover crops improve soil's chemical, physical, and biological properties[6,25,26]; but not all plants are equally effective. These crops act as a barrier to nutrient leaching; depending on the nutrient type[27]. Generally, cover cropping is an effective practice to enhance soil nutrient storage[14]. For example, cover cropping can return 2.1−4.3 Mg ha−1 of carbon and 0.11−0.31 Mg ha−1 of nitrogen per annum[28]. It is more effective at controlling the loss of sediment-associated nutrients like nitrogen than nutrients that are leached by dissolving in runoff water like soluble phosphorus[27]. Cover crops that have a deep rooting system may have better nitrogen use efficiency, nitrogen scavenging abilities, and lesser nitrogen leaching[29]. According to previous findings, the average nitrate leaching reduction due to non-legume cover crops was about 70%, while there is a 23% reduction with legume cover crops[30]. Therefore, this practice has been proposed as a better solution for avoiding surface and groundwater pollution because it reduces nutrient losses from agricultural fields. Thereby, it helps to maintain better water quality and conditions, which is considered a major challenge for modern agriculture[25].

      Integrating living ground cover into farmland can change the soil structure and conditions, providing better crop anchorage. This may improve the movement of water through soil, modify soil temperature, minimizing water runoff and soil erosion, due to variable rooting properties, which include length, distribution patterns, densities, radius, thickness, and morphological characteristics[27]. Aside from that, it affects soil salinity, sodicity, and ion exchange capacity[10]. Formation of allelopathic compounds, reduction of damage to the soil surface mainly due to rain and wind, modifying water infiltration and increasing both soil organic carbon content and water-extractable organic carbon level will enhance the soil aggregation formation and its’ stability[10,18,31]. When comparing fibrous-rooted cover crops with tap root plants, grasses like B. brizantha form a soil which has higher mean weight diameter (1.78 mm) over legumes like P. phaseoloides indicating greater aggregate formation and better aeration in the coconut root zone[6]. As a result of that, water availability at field capacity level in the root zone (0−11 cm depth) is greater (32.98%) than in deep soil layers (11−42 cm) (28.50%) in coconut plantations with grass cover. These cover crops assist in minimizing soil evaporation, conserve soil moisture, and increase water retention concerning field capacity with plant available water[32]. Furthermore, cover cropping helps with carbon sequestration, thereby reducing the global climate change effect[9]. It was proven that the annual reduction of sediment erosion by cover crops like Stellaria media, Poa compressa, and Bromus tectorum is about 87%, 95%, and 96% respectively compared to bare land[33].

      Ground cover vegetation can benefit the soil microbial fauna (bacteria and fungi) by increasing abundance (27%), diversity (22%), and activity (2.5%)[6,34]. This could occur as a result of: 1) an increase in the diversity of plants in the field[35]; 2) the influence of root exudates made with carbon-rich compounds[36,37]; 3) changing soil moisture conditions[38]; 4) presence diversity of plant functional groups, such as C3 grasses, C4 grasses, legumes, and non-legumes[35], and 5) using native species as cover crops because they are easily adaptable to the natural environment[35]. For example, growing leguminous cover crops (i.e. P. phaseoloides, C. pubescens) can enhance the microbial biomass in terms of carbon, nitrogen, and phosphorus by 61%, 51%, and 50% respectively compared to no-cover cropped coconut plantations[28]. As described by Senarathne et al., incorporating T. diversifolia into adult coconut palm manure cycles would increase the microbial activity in both wet and dry zones in the long term (Table 3)[15].

      Table 3.  Variation of microbial activity on T. diversifolia added coconut land[15].

      Zone in Sri LankaMicrobial activity (mg day−1)
      2009201020112012
      Walpita Research Station
      (Wet zone)      		72.5476.8988.3696.74
      Potthukulama Research Station
      (Dry zone)      		48.6255.2270.3668.94

      Coconut is a plantation crop that is extremely sensitive to low moisture levels in the soil[4]. Furthermore, it reduces bulk density in coconut land, facilitating good root penetration and better fauna activities[4] (Table 4).

      Table 4.  Effect of cover cropping on soil bulk density and soil moisture content[40].

      TreatmentSoil bulk density
      (g cm−3)      		Soil moisture content
      (%)
      201020112012201020112012
      Coconut with G. sepium1.491.421.361.444.562.98
      Coconut with P. phaseoloides1.361.321.243.276.785.68
      Coconut with no cover crop1.681.731.691.272.981.58

      The influence of ground cover on the above-mentioned properties will differ with field environmental factors including soil characteristics such as soil texture, soil type, soil depth, cover crop frequency, and species, tillage pattern in the field, and crop rotation[33]. However, some studies reported that the cultivation of these plants in agricultural land has a negligible influence on some soil physical parameters (i.e. pore size distribution, field capacity, and permanent wilting point) [26]. This indicates the need for more research on what has an overall effect of all these influences, the coconut yield will be increased with well-maintained cover cropping (Table 5).

      Table 5.  Effect of cover cropping on average nut yield[40].

      TreatmentNut yield (nuts/palm/year)
      2009201020112012
      Coconut with G. sepium53336863
      Coconut with P. phaseoloides51427168
      Coconut with no cover crop43324243

      According to previous studies, cover cropping is important as a moisture conservation method because of minimizing transpiration and evaporation of water loss from bare soil[1,39] (Table 6). Considering several factors, growing legume cover crops has gathered more attention than Poaceae family ground cover. Higher nutritional composition and greater nutrient transferring ability in leguminous ground cover species has greater positive influence on the soil surface and subsoil chemical properties than others (Fig. 3 & 4). Instead of synthetic fertilizer, the application of 30 kg of Gliricidia sepium or Leucaena leucocephala fresh leaves for a coconut palm can supply 100% of the annual nitrogen requirement and 20% of both annual phosphorus and potassium requirements of an adult coconut palm[1]. In addition to that, it can fix atmospheric nitrogen, which helps to raise soil nitrogen levels. C/N ratio which is used as an indicator for measuring decomposition rate is comparatively lower in legume plant residuals than non-legume types[41]. It facilitates the fast decomposition ability of legume cover crops. According to the literature, legumes are able to create strong and active rhizosphere with diverted macro and microorganisms due to secretion of higher amino nitrogen concentration[36].

      Table 6.  Summarization of cost and benefits of cover cropping systems.

      CostBenefits
      OutputsOutcomes
      Cost for planting materials
      		Suppressing weedsEnhancing plant growth
      Increased cost for machinery and other equipment
      • Tractors
      • Disc-harrowers
      • Mammoties
      • Knives
      		Modifying soil hydraulic properties
      • Enhancing the water infiltration
      • Soil moisture conservation
      • Reduce soil temperature
      		Less dependency on chemicals such as
      • Pesticides
      • Weedicides
      • Insecticides
      • Synthetic fertilizers
      Increased cost for labor for field
      activities planting land preparation
      fertilization pruning Irrigation
      		Increasing soil chemical properties
      • Supplying nutrients
      • Supplying organic matter
      • Nitrogen fixation      		Protect the biodiversity by maximizing the ecosystem services
      Increased cost for farming practices
      • Fertilizing
      • Irrigation
      		The attraction of predators and beneficial insects
      such as pollinators, hoverflies, lacewings, ladybirds, parasitic wasps
      		Minimizing land, water, and environmental pollution
      Knowledge of cover crop species and management practices
      		Minimizing pest and diseases incidenceReduce nutrient leaching
      Modifying soil physical properties
      		Control sediment and water erosion
      Habitat for flora and faunaFlood control
      Modifying soil biological properties
      		Comfort livelihood
      Source of food, feeding materials, fuel, medicinal and pharmaceutical products, and genetic materials
      		Increasing the resource utilization in the farm field
      Carbon sequestration
      		Increasing farmers' income
      Reducing the cost of production
      Chance for animal husbandry on coconut plantations
      Less dependency on main cash crop
      Source for food; milk, meat
      Reducing the global climate changes

      Figure 3. 

      Comparison of nutrient composition of different legume cover crops[28].

      Figure 4. 

      Comparison of nutrient additions of different legume cover crops for the 12 y period[28].

      Suitability of cover crops as food and feeding materials

    • Cover crops are often used for rotational grazing of farm animals[42]. These types of cover crops are known as 'dual purpose cover crops'[43]. Coconut farmers will be able to supplement their income because they will have an additional source of animal-based products like milk, meat, and manure to sell[9]. According to some case studies, a significant area under coconut plantations is home to a variety of cattle, including clean, cross-bred, and indigenous cattle[44]. This suggests that fodder species used as cover crops in coconut plantations is a viable option where livestock integration is maintained. Therefore, it is important to consider the forage quality including digestibility, nutrient concentration, amount of dietary fiber or plant cell wall concentration (low lignin content) of ground cover that are to be used as fodder material[45,46]. As a result, before using it as a feeding material, better identification and quantification of the chemical composition of species is required. Fodder grasses similar to Brachiaria brizantha, are preferred over some conventional fodder materials such as Napier (Pennisetum purpureum) and Guinea grasses (Panicum maximum) due to their higher palatability and resistance toward biotic and abiotic stresses[47]. Furthermore, the suitability and practicability of Coimbatore-3 or Hybrid Napier (CO-3), the hybrid of Pennisetum perpureum × Pennisetum americarnum, multi-cut hybrid fodder sorghum, and wild sorghum (Sorghum bicolor L. Moench) have been locally identified[13]. Cover crops like Mucuna spp., Vigna unguiculata, Vigna radiate, and Pennisetum americanum give edible seeds, leaves, and flowers consumed by humans.

      Other benefits of cover crops

    • Certain ecosystem functions can be negatively affected by continuous farming practices. As an overall effect, cover crops help to maintain many ecosystem services such as provisioning, regulating, and supporting categories that can sustain the life of living organisms on earth[25]. Other than the above-mentioned benefits from cover crops, they are sources of economically important products such as medicinal, pharmaceutical, and valued nutritional products, fiber and fuel, and a source of genetic materials for the production of genetically improved varieties and edible materials such as grains[48]. Cover crops also aid in mitigating climatic changes by controlling the outflow of greenhouse gasses and regulating environmental factors like temperature, global warming, and precipitation[49]. According to that, the greenhouse mitigating capacity of legume cover crops (≈135 g CO2 e/m2/year) is higher than non-legume cover crops (≈116 g CO2 e/m2/year). When compared with no-cover cropped land, it is less than 100−150 g CO2 e/m2/year[10]. Moreover, establishing cover crops with cash crops helps to enhance both above-ground and below-ground biodiversity and species richness in the field[10]. Considering all those effects, it might be stated that ground cover increase the crop yield both directly and indirectly. The benefits and costs of cover crops are summarized below (Table 6).

    Planting and management of cover crops in coconut plantations

    • Cover crops are primarily recommended for perennial crops with a wider row spacing, and the area between cash crop rows is used for establishing ground cover[10]. Even though cover crops can be allowed to grow within the manure cycle in the adult palms, in the seedling stage, there should be at least a 2 m radius area between the palm root base and growing cover crops[50]. The performance of these cover crops in terms of growing and biomass production is primarily determined by environmental parameters including precipitation and temperature[51].

      Selection procedure

    • An overview of current crop management practices should be carried out first at the field level to get an idea of the selection of cover crop species, and cover cropping objectives. This could include information on major crops, cropping methods, the cropping calendar, soil conditions such as soil texture, soil pH, soil nutrient conditions, electrical conductivity, and soil hydraulic properties, and a risk assessment of biotic stresses[9,52]. The key factors in ensuring the best profit from cover cropping are selecting the correct species, using the best establishment and management practices, and selecting the best planting location[30]. Plant species with the following characteristics will perform better in cover cropping situations[4,9,50]:

      • Fast growth rate and easy propagation techniques and not be seen as a threat to the main crop;

      • Adaptation to adverse weather conditions (drought, flooding), varying soil conditions (variable soil pH conditions and nutrient limiting events), and light limiting environments;

      • Ability for excellent above-ground and below-ground performance, including growth and development, canopy and root architecture to complement the main crops;

      • Lack of harmful traits;

      - Residue properties (such as inordinately higher carbon content compared to nitrogen amount, coarse and recalcitrant residues, harmful allelopathic properties);

      - Minimum crop-crop competition with main crops for the resources (e.g., sunlight, space, moisture, nutrients);

      • Minimum possibility to show weediness;

      • Does not host pests and diseases for coconut and other intercropping species;

      • Being dormant during drought to conserve moisture for coconuts.

      Constraints for cover cropping in coconut plantations

    • Even though cover cropping provides farmers with a variety of benefits and ecosystem services, this is not widely used in Sri Lankan agricultural fields. The lack of required inputs such as machinery, labor, and lack of know-how about cover cropping and its benefits may be the main reasons for avoiding cover cropping in the field[10]. Several cover cropping species can be alternative hosts for some insects and pathogens[10]. After being removed from the field, some species, such as sorghum, pearl millet, or corn-like non-legumes, can reappear and compete for natural resources with the main crops[53]. In addition to that, labor intensiveness, especially in planting and controlling the risk for pests and diseases, allelopathy may be a disadvantage of incorporating cover crops with coconut[54].

      Management practices on cover cropping

    • There are a few management practices to achieve better establishment and growth of the cover crop (Table 7).

      Table 7.  Management practices on cover cropping.

      Management practiceRecommendationsReference
      Integrating ground covers into the farming systems
      		Relay-cropping, over-seeding, inter-seeding, and double-cropping[17]
      Collection of planting materialSeed collection (annual and perennial)
      Seeds can be collected from January−March.
      Sun-drying for 2−3 days.
      Quality seeds should be sorted, packed, and stored properly
      		[50]
      Collection of cuttings (perennial)
      Cutting can be collected from stems of one-year old plants.
      Propagating cuttings with adventitious roots are recommended.
      Land preparationPlanting beds can be non-prepared fields or weed-free seedbeds after removing existing plants before seeding.[50]
      Land preparation is not always necessary (no-tillage)
      Selection of methods and conditions can be done by focusing on The properties of the soil The land parameters Availability of planting materials and other inputs.
      Ploughing, slashing, burning or chemical applications can be practiced for land preparation.
      Pre-seeding fertilizer application will be beneficial. As examples,
      • Cow dung
      • 0.5 kg of Urea, 1−2 kg of Saphos phosphate, and 1 kg of Muriate of Potash per one coconut square
      Seed treatmentSeeds can be treated with hot water for a few minutes as an easy and low-cost method for breaking seed dormancy.
      		[55]
      Mechanical methods such as light treatments and scarification with sandpaper or chemical methods like sowing in gibberellic acid and sulfuric acid solutions also can be practiced specifically for legume seeds.
      		[56]
      Seed coating using bio-stimulants such as microbial inoculants, beneficial bacteria, and fungi, containing compounds, biopolymers, and plant extracts while establishing may increase the germination percentage, seedling vigor, and plant uniformity.
      		[57]
      Planting and seedingIf planting materials are very expensive or unavailable, nurseries can be maintained.[50]
      Using coconut husks filled with soil and dung mixture or using polythene tubes filled with the above mixture can be used as growing media.
      Selection of proper seed rate is also important for obtaining optimum cover crop productivity and reducing cost for seeds. This depends on crop species.
      		[58]
      Row-wise or broadcasting over the entire field can be practiced. Generally, for legumes, 5−6 Kg seeds/ha is recommended for broadcasting as rows, while 8−10 Kg seeds/ha are broadcasting in total space.
      		[50]
      Drilling, aerial seeding, or broadcasting of seeds can be practiced for planting. Even though broadcasting is easy, drilling shows a faster establishment rate due to higher seed-soil contact.
      		[59]

      Cover crop managementTo control the vegetative growth of cover crops;
      Use of the 'Mulch roller' or light harrowing once a year or even twice a year can be practiced.
      Ploughing once every two years and digging and envelope-forked are recommended.
      If it is a bush-type cover crop, like Gliricidia, pruning should be done once plant height reaches about 1.5 m.

      [50,60]
      To facilitate the recovery of these crops;
      All these practices should be initiated;
      • The onset of rainy periods
      • As alternating rows in the field
      • Avoid overgrazing in the dry season
      • Practice manuring
      Depending on preferences and other resource availability, two or more cover crop species can be grown on the same land.
      		[61]
      Controlling cover cropsTiming of cover crop termination is critical.
      The cover crop should be grown enough to provide adequate nutrients and farmers' objectives but overgrowth should be avoided.
      		[62]
      Mechanical killing methods like tillage, mowing, undercutting, or rolling can be used.
      		[63]
      Herbicides are commonly used in inorganic fields. It should be sprayed at the time of flowering when biomass production is greatest.
      Although the earlier application may reduce the biomass produced by cover crops, it will improve the control over the difficulties of killing cover crops.
      		[64]
      Killed biomass can be buried in the soil or scattered on the soil, or converted into the secondary product as compost.
      		[65]
    Future research potential on cover cropping

    • The majority of farmers anticipate additional income from each step they take on their farmland. Since organic farming is trending worldwide, future research on organic production with cover crops should be prioritized. Studies on the ability of ground cover to improve soil health and control weeds under various tillage regimes could be beneficial to the success of organic agriculture[66]. Furthermore, using recently updated soil health indicators to evaluate cover-cropped farming systems may reveal new research paths[66]. Some literature had expressed the importance of cultivating fodder-type cover crops as a cash crop to meet the increasing demand for ruminants' animal feed[13]. Findings on the cost-effectiveness of the integrated cover cropping farming system and cost-benefit analysis (particularly for seed costs and other opportunity costs) will be useful in future improvements[67]. Delgado et al.[30] stated that monitoring the long-term impacts of combining ground covering on nutrient cycling, soil organic matter content, greenhouse gas emissions, carbon sequestration, and effects on the harvest of following cash crops after two or three decades, especially in tropical areas, was difficult[30]. They also emphasize the importance of advanced technologies for cover crops, such as machine learning and artificial intelligence.

    Conclusions

    • Intensive cropping patterns and changes in environmental conditions drives several adverse effects on Sri Lankan coconut farming. This review indicates that practicing cover cropping in coconut plantations can improve a variety of on-farm benefits and ecosystem services in most cases, while addressing some of the issues related to the farmer and the environment. It aims to improve most of the soil properties, control pests, diseases, and weediness in the field, facilitate crop growth and yield, reduce chemical dependency, and enable the coconut-animal integrated farming system. Farmers may less apply this practice on coconut plantations due to a lack of awareness about cover cropping techniques and their benefits, as well as some aggressive characteristics of several cover crops. Available information suggests, introducing cover crops can forward coconut cultivation in Sri Lanka more profitable and sustainable. Efforts should be made to identify suitable cover crop species that can fulfill the ultimate target depending on environmental factors and other available resources under coconut. It is timely need and necessary to adapt and modify new technologies and explore new research areas with cover crops to achieve sustainable farming while maximizing yields.

    Acknowledgements

    • We would like to express our appreciation to the technical staff of the Agronomy Division of the Coconut Research Institute. We would like to thank the editor and two anonymous reviewers for their valuable comments and constructive evaluation.

      Conflict of interest

      • The authors declare that they have no conflict of interest.

      Rights and permissions
      • Copyright: © 2022 by the author(s). Published by Maximum Academic Press, Fayetteville, GA. This article is an open access article distributed under Creative Commons Attribution License (CC BY 4.0), visithttps://creativecommons.org/licenses/by/4.0/.
    Figure (4)  Table (7) References (67)
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    Dissanayaka DMNS, Nuwarapaksha TD, Udumann SS, Dissanayake DKRPL, Atapattu AJ. 2022. A sustainable way of increasing productivity of coconut cultivation using cover crops: A review. Circular Agricultural Systems 2:7 doi: 10.48130/CAS-2022-0007
    Dissanayaka DMNS, Nuwarapaksha TD, Udumann SS, Dissanayake DKRPL, Atapattu AJ. 2022. A sustainable way of increasing productivity of coconut cultivation using cover crops: A review. Circular Agricultural Systems 2:7 doi: 10.48130/CAS-2022-0007
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