Influence of lime, fertilizer and manure applications on soil organic matter content and soil physical conditions: a review (original) (raw)
- Aldrich DG, Parker ER & Chapman HD (1945) Effects of several nitrogenous fertilizers and soil amendments on the physical and chemical properties of an irrigated soil. Soil Sci 59: 299–312
Google Scholar - Andersen NC (1983) Nitrogen turnover by earthworms in arable plots treated with farmyard manure and slurry. In: Satchell JE (ed) Earthworm Ecology, pp 123–137. London, Chapman & Hall
Google Scholar - Badalucco L, Grego S, Dell'Orco S & Nannipieri P (1992) Effect of liming on some chemical, biochemical, and microbiological properties of acid soils under spruce (_Picea abies_L.). Biol Fertil Soils. 14: 76–83
Google Scholar - Baver LD (1956) Soil Physics New York, John Wiley
Google Scholar - Buckerfield JC & Doube BM (1993) Responses of native and introduced earthworm species to limed soil. In: Fawcett RG (ed) Workshop on Tillage Systems, Rotations and Associated Root Diseases, pp 68–69. Adelaide, South Australian Department of Agriculture
Google Scholar - Burns RG & Davies JA (1986) The microbiology of soil structure. In: Lopez–Real JM & Hodges RD (eds) The Role of Microorganisms in a Sustainable Agriculture, pp 9–27. Berkhamstead, Academic Publishers
Google Scholar - Castro C & Logan TJ (1991) Liming effects on the stability and erodibility of some Brazilian Oxisols. Soil Sci Soc Am J 55: 1407–1413
Google Scholar - Chan KY & Heenan DP (1996) Lime affected structural stability of red earth under different tillage, stubble and rotation management. Proceedings of the Australia and New Zealand National Soils Conference 1996, Vol 3, pp 39–40
Google Scholar - Chaney K & Swift RS (1984) The influence organic matter on aggregate stability in some British soils. J. Soil Sci 35: 223–230
Google Scholar - Chawla KL & Chabra R (1991) Physical properties of a gypsum amended sodic soil as affected by long–term use of fertilizers. J Indian Soc Soil Sci 39: 40–45
Google Scholar - Cheshire MV & Hayes MHB (1990) Composition, origins, structures, and reactivities of soil polysaccharides. In: De Boodt MF, Hayes MHB & Herbillon A (eds) Soil Colloids and their Associations in Aggregates, pp 307–336. New York, Plenum
Google Scholar - Christensen BT (1988) Effects of animal manure and mineral fertilizers on the total carbon and nitrogen contents of soil size fractions. Biol Fertil Soils 5: 304–307
Google Scholar - Cross OE & Fischbach PE (1972). Water intake rates on a silt loam soil with various manure applications. ASAE Paper no. 72–218. St. Joseph, Michigan, Amer Soc Agric Eng.
Google Scholar - Cross OE, Mazurak AP & Chesnin L (1973). Animal waste utilization for pollution abatement. Trans Am Soc Agr Eng 16: 160–163
Google Scholar - Czeratzki W(1972) Die Beeinflussung von Aggregatstabilität, Plastizit ät une Wasserbindung bei der Bodenstabilisierung durch mittlere und hohe Gaben von Kalkhydrat. Z Pflanzeneräehr Düng Bodenk 133: 45–53
Google Scholar - Darusman LR, Stone DA, Janssen KA & Long JH (1991) Soil properties after twenty years of fertilization with different nitrogen sources. Soil Sci Soc Am J 55: 1097–1100
Google Scholar - Davies DB & Payne D (1988) Management of soil physical properties. In: Wild A (ed) Russell's Soil Conditions and Plant Growth, Eleventh Edition, pp 412–448. Harlow, Essex, Longman
Google Scholar - Dick RP (1992) A review: long–term effects of agricultural systems on soil biochemical and microbial parameters. Agric Ecosystems Environ 40: 25–36
Google Scholar - Dick RP, Rasmussen PE & Kerle EA (1988) Influence of long–term residue management on soil enzyme activities in relation to soil chemical properties of a wheat–fallow system. Biol Fertil Soils 6: 159–164
Google Scholar - Doekson J & van Wingerden CG (1964) Notes on the activity of earthworms. 2. Observations on diapause in the earthworm Allolobophora caliginosa. Jaarb I B S: 181–186
- Edmeades DC, Judd M & Sarathchandra SU (1981) The effect of lime on nitrogen mineralization as measured by grass growth. Plant Soil 60: 177–186
Google Scholar - Edwards CA & Lofty JR (1982) Nitrogenous fertilizers and earthworm populations in agricultural soils. Soil Biol Biochem 14: 515–521
Google Scholar - Ekwue EI (1992) Effect of organic and fertilizer treatments on soil physical properties and erodibility. Soil Tillage Res 22: 199–209
Google Scholar - El Rayah HME & Rowell DL (1973) The influence of iron and aluminium hydroxides on the swelling of Na–montmorillonite and the permeability of a Na–soil. J Soil Sci 24: 137–144
Google Scholar - El–Swaify SA & Emerson WW (1975) Changes in the physical properties of soil clays due to precipitated aluminium and iron hydroxides: I. Swelling and aggregate stability after drying. Soil Sci Soc Am Proc 39: 1056–1063
Google Scholar - Epstein E, Taylor JM& Chaney RL (1976) Effects of sewage sludge and sludge compost applied to soil on some soil physical and chemical properties. J Environ Qual 5: 422–426
Google Scholar - Fox RL, Olson RA & Mazurak AP (1952) Persistence of ammonium ion and its effect upon physical and chemical properties of soil. Agron J 44: 509–513
Google Scholar - Fraser PM, Haynes RJ & Williams PH (1994) Effect of pasture improvement and intensive cultivation on size of microbial biomass, enzyme activities and composition and size of earthworm populations. Biol Fertil Soils (in press)
- Ghani MO, Hasan KA & Khan MFA (1955) Effect of liming on aggregation, noncapillary pore space, and permeability of a Lateritic soil. Soil Sci 80: 469–478
Google Scholar - Gregory PJ (1988) Growth functioning of plant roots. In: Wild A (ed) Russell's Soil Conditions and Plant Growth, Eleventh edition, pp 113–167, Harlow, Essex, Longman
Google Scholar - Goldberg S & Glauig RA (1987) Effect of saturating cation, pH, and aluminium and iron oxide on the flocculation of kaolinite and montmorillonite. Clays Clay Miner 35: 220–227
Google Scholar - Greene RSB, Posner AM & Quirk JP (1978) Interactions of suspensions of Ca–illite with PVA and Ca(OH)2. In: Emerson WW, Bond RD & Dexter AR (eds) Modification of Soil Structure, pp 157–163. Chichester, John Wiley
Google Scholar - Griffiths E & Jones D (1965) Microbiological aspects of soil structure. I. Relationships between organic amendments, microbial colonisation and changes in aggregate stability. Plant Soil 23: 23–28
Google Scholar - Gu B & Doner HE (1993) Dispersion and aggregation of soils as influenced by organic and inorganic polymers. Soil Sci Soc Am J 57: 709–716
Google Scholar - Gupta SC, Dowdy RH & Larson WE (1977) Hydraulic and thermal properties of a sandy soil as influenced by incorporation of sewage sludge. Soil Sci Soc Am Proc 41: 601–605
Google Scholar - Hafez AAA (1974) Comparative changes in soil physical properties induced by admixtures of manures from various domestic animals. Soil Sci 118: 53–59
Google Scholar - Hayes MHB & Swift RS (1990) Genesis, isolation, composition and structures of soil humic substances. In: De Boodt MF, Hayes MHB & Herbillon A (eds) Soil Colloids and their Associations in Aggregates, pp 245–305. New York, Plenum
Google Scholar - Haynes RJ (1982) Effects of liming on phosphate and availability in acid soils. A critical review. Plant Soil 68: 289–308
Google Scholar - Haynes RJ (1984) Lime and phosphate in the soil–plant system. Adv Agron 37: 249–315
Google Scholar - Haynes RJ (1986) Nitrification. In: Haynes RJ (ed) Nitrogen in the Plant–Soil System, pp 127–165. Orlando, Academic Press
Google Scholar - Haynes RJ & Beare MH (1994) Aggregation and organic carbon storage in meso–thermal humid soils. Adv Soil Sci
- Haynes RJ & Swift RS (1988) Effects of lime and phosphate addition on changes in enzyme activities, microbial biomass and levels of extractable nitrogen, sulphur, and phosphorus in an acid soil. Biol Fertil Soils 6: 153–158
Google Scholar - Haynes RJ & Williams PH (1992a) An overview of pasture response, nutrient turnover and nutrient accumulation on the grazed, long–term superphosphate trial at Winchmore, New Zealand. Proc XVII Inter Grassl Congr, Hamilton (in press).
- Haynes RJ & Williams PH (1992b) Accumulation of soil organic matter and the forms, mineralization potential and plantavailability of accumulated organic sulphur: effects of pasture improvement and intensive cultivation. Soil Biol Biochem 24: 209–217
Google Scholar - Haynes RJ & Williams PH (1993) Nutrient cycling and soil fertility in the grazed pasture ecosystem. Adv Agron 49: 119–199
Google Scholar - Haynes RJ, Swift RS & Stephen RC (1991) Influence of mixed cropping rotations (pasture–arable) on organic matter content, water stable aggregation and clod porosity in a group of soils. Soil Tillage Res 19: 77–87
Google Scholar - Hensler RF, Olsen RJ, Witzel SA, Altoe OJ, Paulson WH & Johannes RF (1970) Effects of method of manure handling on crop yields, nutrient recovery and runoff losses. Trans ASAE 13: 726–731
Google Scholar - Hoyt PB (1981) Improvement in soil tilth and rape seed emergence by lime application on acid soils in the Peace River region. Can J Soil Sci 61: 91–98
Google Scholar - Ingles OG & Metcalf JB (1972) Soil Stabilization. Sydney, Butter–worths
Google Scholar - Intrawech A, Stone LR, Ellis R & Whitney DA (1982) Influence of fertilizer nitrogen source on soil physical and chemical properties. Soil Sci Soc Am J 46: 832–836
Google Scholar - Johnston AE (1969) Plant nutrients in Broadbalk soils. Rothamsted Exp Sta Rep 1968, Part 2: 93–115
- Johnston AE (1975) The Woburn market garden experiment, 1942–69. II. Effects of the treatments on soil pH, soil carbon, nitrogen, phosphorous and potassium. Rothamsted Exp Sta Rep 1974, Part 2: 103–131
Google Scholar - Johnston AE (1986) Soil organic matter effects on soils and crops. Soil Use Management 2: 97–105
Google Scholar - Kamprath EJ (1971) Potential detrimental effects from liming highly weathered soils to neutrality. Soil Crop Sci Soc Fla Proc 31: 200–203
Google Scholar - Kamprath EJ (1984) Crop response to lime on soils in the tropics. In: Adams F (ed) Soil Acidity and Liming, pp 349–368. American Society of Agronomy, Madison, Wisconsin
Google Scholar - Khaleel R, Reddy KR & Overcash MR (1981) Changes in soil physical properties due to organic waste applications: A review. J Environ Qual 10: 133–141
Google Scholar - Khan SU (1970) Enzymatic activity in a grey wooded soil as influenced by cropping systems and fertilizers. Soil Biol Biochem 2: 137–139
Google Scholar - Kladivko EJ & Nelson DW (1979) Changes in soil properties from application of anaerobic sludge. J Water Pollut Control Fed 51: 315–332
Google Scholar - Köhn W (1975) The influence of long–term soil cultivation, fertilization and rotation on the chemical and physical properties and yielding ability of a sandy loam soil. I. Soil chemical and physical properties. Bayer Landwirtsh Jahrb 52: 928–955
Google Scholar - Lal R (1991) Soil structure and sustainability. J Sustain Agric 1: 67–91
Google Scholar - Lal R & Kang BT (1982) Management of organic matter in soils of the tropics and subtropics. Trans 12th Int Cong Soil Sci IV: 152–178
Google Scholar - Lee KE (1985) Earthworms: Their Ecology and Relationships with Soils and Land Use. Sydney, Academic Press
Google Scholar - Lee KE & Foster RC (1991) Soil fauna and soil structure. Aust J Soil Res 29: 745–775
Google Scholar - Lemmermann O & Behrens WU (1935) On the influence of manuring on the permeability of soils. Z Pflanzenernähr Düng Bodenk 37: 174–192
Google Scholar - Low AJ (1954) The study of soil structure in the field and in the laboratory. J Soil Sci 5: 57–74
Google Scholar - Lutz JF, Garcia–Lagos R & Hilton HG (1960) The effect of phosphate fertilizers on some physical properties of soil. Trans 7th Int Congr Soil Sci VI: 241–248
Google Scholar - Lutz JF, Pinto RA, Garcia–Lagos R & Hilton HG (1966). Effect of phosphorus on some physical properties of soils: II. Water retention. Soil Sci Soc Am Proc 30: 433–437.
Google Scholar - Lutz JF & Pinto RA (1965). Effect of phosphorus on some physical properties of soils: I. Modulus of rupture. Soil Sci Soc Am Proc 29: 458–460
Google Scholar - Martyniuk S & Wagner GH (1978) Quantitative and qualitative examination of soil microflora associated with different management systems. Soil Sci 125: 353–350
Google Scholar - Mazurak AP, Chesnin L & Tiarks AE (1975) Detachment of soil aggregates by simulated rainfall from heavily manured soils in eastern Nebraska. Soil Sci Soc Am Proc 39: 732–736
Google Scholar - McGill WB, Cannon KR, Robertson JA & Cook FD (1986) Dynamics of soil microbial biomass and water–soluble organic C in Breton L after 50 years of cropping to two rotations. Can J Soil Sci 66: 1–19
Google Scholar - Metzger L & Yaron B (1987) Influence of sludge organic matter on soil physical properties. Adv Soil Sci 7: 141–163
Google Scholar - Monnier G (1965) Action des matieres organiques sur la stabilité structurale des sols. Ann Agron 16: 471–534
Google Scholar - Naidu R, Merry RH, Churchman GJ, Wright MJ, Murray RS, Fitzpatric RW & Zarcinus BA (1993) Sodicity in South Australia–a review. Aust J Soil Res 31: 911–929
Google Scholar - Newman EI (1985) The rhizosphere: carbon sources and microbial populations. In: Fitter AH (ed) Ecological Interactions in Soil. Plants, Microbes and Animals, pp 107–121. Oxford, Blackwell
Google Scholar - Nguyen ML & Goh KM (1990) Accumulation of soil sulphur fractions in grazed pastures receiving long–term superphosphate applications. N Z J Agric Res 32: 245–262
Google Scholar - Nuttall WF, Bowren KE & Campbell CA (1986) Crop residue management practices, and N and P fertilizer effects on crop response and on some physical and chemical properties of a black chernozem over 25 years in a continuous wheat rotation. Can J Soil Sci 66: 159–171
Google Scholar - Oades JM (1978) Mucilages at the root surface. J Soil Sci 29: 1–16
Google Scholar - Oades JM (1979) Interactions of metal ion species with clays. In: Yates DE (ed) Colloids in Soils–Principles and Practice. Proceedings of the Symposium on Colloids in Soils–Principles and Practice, pp 6?1–6?34. Victoria, Australia, Royal Australian Chemical Institute
Google Scholar - Olsen RJ, Hensler RF & Attoe OJ (1970) Effect of manure application, aeration, and soil pH on soil nitrogen transformations and on certain soil test values. Soil Sci Soc Am Proc 34: 222–225
Google Scholar - Pagliai M, Guidi G, La Marca M, Giachetti M & Lucamante G (1981) Effects of sewage sludges and composts on soil porosity and aggregation. J Environ Qual 10: 556–561
Google Scholar - Pearson RW (1975) Soil acidity and liming in the humid tropics. Cornell Int Agric Bull No 30
- Pillsbury AF (1947) Factors influencing infiltration rates into Yolo loam. Soil Sci 64: 177–181
Google Scholar - Rengasamy P & Oades JM (1978) Interaction of monomeric and polymeric species of metal ions with clay surfaces. III. Aluminium (III) and chromium(III). Aust J Soil Res 16: 53–66
Google Scholar - Rennie DA, Truog E & Allen ON (1954) Soil aggregation as influenced bymicrobial gums, level of fertility and kind of crop. Soil Sci Soc Am Proc 18: 399–403
Google Scholar - Rimmer DL & Greenland DJ (1976) Effects of calcium carbonate on the swelling behaviour of a soil clay. J Soil Sci 27: 129–139
Google Scholar - Robbins CW, Carter DL & Leggett GE (1972) Controlling soil crusting with phosphoric acid to enhance seedling emergence. Agron J 64: 180–183
Google Scholar - Roth CH (1992) Soil sealing and crusting in tropical South America. In: Sumner ME & Stewart BA (eds) Advances in Soil Science. Soil Crusting–Chemical and Physical Processes, pp 267–300. Boca Raton, Lewis Publishers
Google Scholar - Roth CH & Pavan MA (1991) Effects of lime and gypsum on clay dispersion and infiltration in samples of a Brazilian Oxisol. Geoderma 48: 351–361
Google Scholar - Roth CH, Pavan MA, Chaves JCD, Meyer B & Frede HG (1986) Efeitos das aplicacacões de calcário e gesso sobre a estabilidade de agregados e infiltrabilidade de água em un Latossolo Roxo cultivado com cafeeiros. Rev Bras Ci Solo 10: 163–166
Google Scholar - Sanchez PA, Palm CA, Szott LT, Cuevas E & Lal R (1989) Organic input management in tropical agroecosystems. In: Coleman DC, Oades JM & Uehara G (eds) Dynamics of Soil Organic Matter in Tropical Ecosystems. pp. 125–152, Honolulu, University of Hawaii Press
Google Scholar - Sauerbeck DR (1982) Influence of crop rotation, manurial treatment and soil tillage on the organic matter content of German soils. In: Boels D, Davies DB & Johnston AE (eds) Soil Degradation, Proceedings of the EEC Seminar held in Wageningen, Netherlands, pp 163–179. Rotterdam, A A Balkema
Google Scholar - Schjønning P, Christensen BT & Carstensen B (1994) Physical and chemical properties of a sandy loam receiving animal manure, mineral fertilizer or no fertilizer for 90 years. European J Soil Sci 45: 257–268
Google Scholar - Schnürer J, Clarholm M & Rosswall T (1985) Microbial biomass and activity in an agricultural soil with different organic matter contents. Soil Biol Biochem 17: 611–618
Google Scholar - Shainberg I, Sumner ME, Miller WP, Farina MPW, Pavan MA & Fey MV (1989) Use of gypsum on soils: a review. Adv Soil Sci 9: 1–11
Google Scholar - Sparling GP (1985) The soil biomass. In: Vaughn D & Malcolm RE (eds) Soil Organic Matter and Biological Activity, pp 223–262. The Hague, Martinus Nijhoff
Google Scholar - Springett JA & Syers JK (1984) Effect of pH and calcium content of soil on earthworm cast production in the laboratory. Soil Biol Biochem 16: 185–189
Google Scholar - Standen V (1984) Production and diversity of enchytraeids, earthworms and plants in fertilized hay meadow plots. J Appl Ecol 21: 293–312
Google Scholar - Stockdill SMJ & Cossens GC (1966) The role of earthworms in pasture production and moisture conservation. Proc N Z Grassl Assoc p 168–183
- Sumner ME (1992) The electrical double layer and clay dispersion. In: Sumner ME & Stewart BA (eds) Advances in Soil Science. Soil Crusting–Chemical and Physical Processes, pp 1–31. Boca Raton, Lewis Publishers.
Google Scholar - Tama K & El–Swaify SA (1978) Charge, colloidal, and structural stability relationships in oxidic soils. In: Emerson WW, Bond RD & Dexter AR (eds) Modification of Soil Structure, pp 41–52. Chichester, John Wiley
Google Scholar - Thein SJ (1976) Stabilizing soil aggregates with phosphoric acid. Soil Sci Soc Am Proc 40: 105–108
Google Scholar - Tiarks A, Mazurak AP & Chesnin L (1974) Physical and chemical properties of soil associated with heavy applications of manure from cattle feedlots. Soil Sci Soc Am Proc 38: 826–830
Google Scholar - Tisdall JM(1991) Fungal hyphae and structural stability of soil. Aust J Soil Res 29: 729–743
Google Scholar - Tisdall JM & Oades JM (1982) Organic matter and water–stable aggregates in soils. J Soil Sci 33: 141–163
Google Scholar - Utomo WH & Dexter AR (1981) Soil friability. J Soil Sci 32: 203– 213
Google Scholar - Verstraete W & Voets JP (1977) Soil microbial and biochemical characteristics in relation to soil management and fertility. Soil Biol Biochem 9: 253–258
Google Scholar - Weil RR & Kroontje W (1979) Physical condition of a Davidson clay loam after five years of heavy poultry manure applications. J Environ Qual 8: 387–391
Google Scholar - Williams RJB & Cook GW (1961) Some effects of farmyard manure and of grass residues on soil structure. Soil Sci 92: 30–39
Google Scholar - Yeoh NS & Oades JM (1981a) Properties of soils and clays after acid treatment. I. Clay minerals. Aust J Soil Res 19: 147–158
Google Scholar - Yeoh NS & Oades JM (1981b) Properties of soils and clays after acid treatment. II. Urrbrae fine sandy loam. Aust J Soil Res 19: 159–166
Google Scholar - Young RA & Mutchler CK (1976) Pollution potential of manure spread on frozen ground. J Environ Qual 5: 174–179
Google Scholar