Vegetos

References

Agbim NN (1987) Dry season decomposition of leaf litter from five common plant species of West Africa. Biol Agric Hortic 4(3):213–224


Allen SE, Grimshaw HM, Rowland AP (1986) Chemical analysis. In: Moore PD, Chapman SB (eds) Methods in plant ecology. Blackwell Scientific Publications, pp 285–344


Andrade DS, Leal AC, Ramos ALM, de Goes KCGP (2015) Growth of Casuarina cunninghamiana inoculated with arbuscular mycorrhizal fungi and Frankia actinomycetes. Symbiosis 66(2):65–73


Arshad M, Frankenberger WT Jr (1997) Plant growth-regulating substances in the rhizosphere: microbial production and functions. Adv Agron 62:45–151


Beer J (1988) Litter production and nutrient cycling in coffee (Coffea arabica) or cacao (Theobroma cacao) plantations with shade trees. Agrofor Syst 7(2):103–114


Bocock KL, Gilbert O, Capstick CK, Twinn DC, Waid JS, Woodman MJ (1960) Changes in leaf litter when placed on the surface of soils with contrasting humus types: I. Losses in dry weight of oak and ash leaf litter. J Soil Sci 11(1):1–9


Cairns M, Keitzar S, Yaden TA (2010) Shifting forests in Northeast India: Management of Alnus nepalensis as an improved fallow in Nagaland. Voices from the forest. Routledge, Cham, pp 362–399


Ceccon E, Sánchez I, Powers JS (2015) Biological potential of four indigenous tree species from seasonally dry tropical forest for soil restoration. Agrofor Syst 89(3):455–467


Chopra SL, Kanwar JS (1976) Analytical agricultural chemistry. Kalyani Publications


Cizungu L, Staelens J, Huygens D, Walangululu J, Muhindo D, Van Cleemput O, Boeckx P (2014) Litterfall and leaf litter decomposition in a central African tropical mountain forest and Eucalyptus plantation. For Ecol Manage 326:109–116


Clarkson DT (1969) Metabolic aspects of aluminium toxicity and some possible mechanisms for its resistance. In: Rorison H (ed) Ecological aspects of the mineral nutrition of Plants, 1st edn. Blackwell Scientific Publications, Oxford, pp 381–397


Cook A, Marriott CA, Seel W, Mullins CE (1996) Effects of soil mechanical impedance on root and shoot growth of Lolium perenne L, Agrostis capillaris and Trifolium repens L. J Exp Bot 47(8):1075–1084


Cox P, Wilkinson SP, Anderson JM (2001) Effects of fungal inocula on the decomposition of lignin and structural polysaccharides in Pinus sylvestris litter. Biol Fertil Soils 33(3):246–251


Danga BO, Ouma JP, Wakindiki II, Bar-Tal A (2009) Legume–wheat rotation effects on residual soil moisture, nitrogen and wheat yield in tropical regions. Adv Agron 101:315–349


Das DK, Chaturvedi OP (2003) Litter quality effects on decomposition rates of forestry plantations. Trop Ecol 44(2):259–262


Davidson RL (1969) Effects of soil nutrients and moisture on root/shoot ratios in Lolium perenne L. and Trifolium repens L. Ann Bot 33(3):571–577


De Corato U (2020) Improving the shelf-life and quality of fresh and minimally-processed fruits and vegetables for a modern food industry: a comprehensive critical review from the traditional technologies into the most promising advancements. Crit Rev Food Sci Nutr 60(6):940–975


Dechert G, Veldkamp E, Brumme R (2005) Are partial nutrient balances suitable to evaluate nutrient sustainability of land use systems? Results from a case study in Central Sulawesi, Indonesia. Nutr Cycl Agroecosyst 72(3):201–212


Dugan FM (2017) The identification of fungi: an illustrated introduction with keys, glossary, and guide to literature. The American Phytopathological Society


Ewel JJ (1976) Litter fall and leaf decomposition in a tropical forest succession in eastern Guatemala. J Ecol 64(1):293–308


Gaisie E, Sadick A, Agyeman K, Adjei-Gyapong T, Quansah G (2015) Leaf decomposition and the nutrients release from multipurpose trees for crop production. Int J Sci Res Sci Eng Technol 2(1):345–352


Garcia Salamone IED, Hynes RK, Nelson LM (2005) Role of cytokinins in plant growth promotion by rhizosphere bacteria. PGPR: biocontrol and biofertilization. Springer, pp 173–195


Gulati S, Chitralekha P, Pandit MA, Katyal R, Bhandari N, Mehta P, Rawat CD, Kaur S, Kaur J (2022) Diversity, succession and seasonal variation of phylloplane mycoflora of Leucaena leucocephala in relation to its leaf litter decomposition. J Fungi 8(6):608


Hartemink AE, Osullivan JN (2001) Leaf litter decomposition of Piper aduncum, Gliricidia sepium and Imperata cylindrica in the humid lowlands of Papua New Guinea. Plant Soil 230(1):115–124


Ikram M, Ali N, Jan G, Jan FG, Rahman IU, Iqbal A, Hamayun M (2018) IAA producing fungal endophyte Penicillium roqueforti Thom., enhances stress tolerance and nutrients uptake in wheat plants grown on heavy metal contaminated soils. PLoS ONE 13(11):e0208150


Isaac ME, Gordon AM, Thevathasan N, Oppong SK, Quashie-Sam J (2005) Temporal changes in soil carbon and nitrogen in west African multistrata agroforestry systems: a chronosequence of pools and fluxes. Agrofor Syst 65(1):23–31


Ishihara KL, Honda MD, Bageel A, Borthakur D (2018) Leucaena leucocephala: a leguminous tree suitable for eroded habitats of Hawaiian Islands. ravine lands: greening for livelihood and environmental security. Springer, pp 413–431


Jama BA, Nair PKR (1996) Decomposition-and nitrogen-mineralization patterns of Leucaena leucocephala and Cassia siamea mulch under tropical semi- arid conditions in Kenya. Plant Soil 179(2):275–285


Jordan CF (1985) Nutrient cycling in tropical forest ecosystems. Principles and their application in management and conservation. John Wiley & Sons, p 190


Kang BT, Reynolds L, Atta-Krah AN (1990) Alley farming. Adv Agron 43:315–359


Mubarak AR, Elbashir AA, Elamin LA, Daldoum DMA, Steffens D, Benckiser G (2008) Decomposition and nutrient release from litter fall in the semiarid tropics of Sudan. Commun Soil Sci Plant Anal 39(15–16):2359–2377


Nguyen MP, Vaast P, Pagella T, Sinclair F (2020) Local knowledge about ecosystem services provided by trees in coffee agroforestry practices in northwest Vietnam. Land 9(12):486


Nouri E, Breuillin-Sessoms F, Feller U, Reinhardt D (2014) Phosphorus and nitrogen regulate arbuscular mycorrhizal symbiosis in Petunia hybrida. PLoS ONE 9(3):e90841


Nuberg IK, Evans DG (1993) Alley cropping and analog forests for soil conservation in the dry uplands of Sri Lanka. Agrofor Syst 24(3):247–269


Oladoye AO, Ola-Adams BA, Adedire MA, Agboola DA (2008) Nutrient dynamics and litter decomposition in Leucaena leucocephala (Lam.) De Wit plantation in the Nigerian derived savanna. West Afr J Appl Ecol 13(1):96–103


Othieno CO (1973) The effect of organic mulches on yields and phosphorus utilization by plants in acid soils. Plant Soil 38(1):17–32


Pandey CB, Sharma DK, Bargali SS (2006) Decomposition and nitrogen release from Leucaena leucocephala in Central India. Trop Ecol 47(1):149–152


Pandit MA, Gulati S, Bhandari N, Mehta P, Katyal R, Rawat CD, Kaur J (2022) Sustainable management strategies and biological control in apple orchards. Plant Sci Today 9(2):443–453


Phillips JM, Hayman DS (1970) Improved procedures for clearing roots and staining parasitic and vesicular-arbuscular mycorrhizal fungi for rapid assessment of infection. Trans Br Mycol Soc 55(1):158–218


Rao NSS (1995) Soil microorganisms and plant growth, 3rd edn. Science Publishers Inc


Repo A, Tuomi M, Liski J (2011) Indirect carbon dioxide emissions from producing bioenergy from forest harvest residues. GCB Bioenergy 3(2):107–115


Ryu JH, Madhaiyan M, Poonguzhali S, Yim WJ, Indiragandhi P, Kim KA, Sa T (2006) Plant growth substances produced by Methylobacterium spp. and their effect on tomato (Lycopersicon esculentum L.) and red pepper (Capsicum annuum L.) growth. J Microbiol Biotechnol 16(10):1622–1628


Sadaf S, Nuzhat A, Nasreen SK (2009) Indole acetic acid production and enhanced plant growth promotion by indigenous PSBs. Afr J Agric Res 4(11):1312–1316


Sandhu J, Sinha M, Ambasht RS (1990) Nitrogen release from decomposing litter of Leucaena leucocephala in the dry tropics. Soil Biol Biochem 22(6):859–863


Sarkar D, Rakshit A (2021) Bio-priming in combination with mineral fertilizer improves nutritional quality and yield of red cabbage under Middle Gangetic Plains, India. Sci Hortic 283:110075


Sarkar S, Singh SR (2007) Interactive effect of tillage depth and mulch on soil temperature, productivity and water use pattern of rainfed barley (Hordium vulgare L.). Soil Tillage Res 92(1–2):79–86


Shanmugam V, Pothiraj G, Dauda WP (2021) Endophytes for postharvest disease management in vegetables and fruits. Postharvest handling and diseases of horticultural produce. CRC Press, pp 93–110


Singhal V, Roy T, Singh C, Ghosh J, Bhat S (2019) Leaf litter production and decomposition dynamics in four agroforestry tree species of western Himalayas. J Pharmacogn Phytochem 8(1):198–201


Smiley GL, Kroschel J (2010) Yield development and nutrient dynamics in Cocoa gliricidia agroforests of Central Sulawesi, Indonesia. Agrofor Syst 78(2):97–114


St John TV (1980) Influence of litterbags on growth of fungal vegetative structures. Oecologia 46(1):130–132


Tedersoo L, Bahram M, Põlme S, Kõljalg U, Yorou NS, Wijesundera R, Ruiz LV, Vasco-Palacios AM, Thu PQ, Suija A, Smith ME (2014) Global diversity and geography of soil fungi. Science 346(6213):1256688


Thakur TK, Thakur A (2014) Litter fall patterns of a dry tropical forest ecosystem of central India. Ecol Environ Conserv 20(3):1325–1328


Timonin MI (1940) The interaction of higher plants and soil microorganisms: I. Microbial population of rhizosphere of seedlings of certain cultivated plants. Can J Res 18(7):307–317


Vitorello VA, Capaldi FR, Stefanuto VA (2005) Recent advances in aluminum toxicity and resistance in higher plants. Braz J Plant Physiol 17:129–143


Vitousek PM, Sanford RL (1986) Nutrient cycling in moist tropical forest. Annu Rev Ecol Syst 17(1):137–167


Walkley A, Black IA (1934) An examination of the Degtjareff method for determining soil organic matter, and a proposed modification of the chromic acid titration method. Soil Sci 37(1):29–38


Witkamp M, Olson JS (1963) Breakdown of confined and nonconfined oak litter. Oikos 14:138–147


Yadav GS, Babu S, Das A, Mohapatra KP, Singh R, Avasthe RK, Roy S (2020) No-till and mulching enhance energy use efficiency and reduce carbon footprint of a direct-seeded upland rice production system. J Clean Prod 271:122700