Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-27T13:29:26.680Z Has data issue: false hasContentIssue false

The effect of over 50 years of liming on soil aluminium forms in a Retisol

Published online by Cambridge University Press:  28 March 2019

Z. Kryzevicius*
Affiliation:
Vėžaičiai Branch of Lithuanian Research Centre for Agriculture and Forestry, Gargždų St. 29, Vėžaičiai, Klaipėda distr., Lithuania Klaipeda University, Faculty of Marine Technology and Natural Sciences, Klaipėda, Lithuania
D. Karcauskiene
Affiliation:
Vėžaičiai Branch of Lithuanian Research Centre for Agriculture and Forestry, Gargždų St. 29, Vėžaičiai, Klaipėda distr., Lithuania
E. Álvarez-Rodríguez
Affiliation:
Department of Soil Science and Agricultural Chemistry, University of Santiago de Compostela, Lugo, Spain
A. Zukauskaite
Affiliation:
Klaipeda University, Faculty of Marine Technology and Natural Sciences, Klaipėda, Lithuania
A. Slepetiene
Affiliation:
Institute of Agriculture, Lithuanian Research Centre for Agriculture and Forestry, Akademija, Kėdainiai distr., Lithuania
J. Volungevicius
Affiliation:
Institute of Agriculture, Lithuanian Research Centre for Agriculture and Forestry, Akademija, Kėdainiai distr., Lithuania
*
Author for correspondence: Z. Kryzevicius, E-mail: zilvinas.kryzevicius@lammc.lt

Abstract

The aim of the current study was to evaluate the effect of long-term (56 years) liming on changes in soil pH and aluminium (Al) forms in the soil profile compared with an unlimed soil in a sandy moraine loam of a Dystric Glossic Retisol. Long-term liming had a significant influence on soil acidity of the whole profile, causing increased pH values in the following horizons to 120 cm depth: the ploughing horizon (Ahp), where humus accumulates; the eluvial horizon (E), from which clay particles are leached; a horizon having retic properties and predominantly coarser-textured albic material (E/B); and a horizon with retic properties and predominantly finer-textured argic material (B/E). In the solid phase, non-crystalline Al in limed soil decreased in the Ahp horizon; meanwhile a decrease in total organically bound Al (Alp) and organo–Al complexes of low to medium stability was detected in the deeper El and ElBt horizons. High-stability Al complexes with organic matter were the predominant form of Alp in the unlimed and limed whole soil profile. The concentration of total water-soluble Al ranged from 0.61 to 0.80 mg/l in the limed soil profile but 0.62–1.15 mg/l in the unlimed soil. The highest concentration of exchangeable Al was determined in the upper horizons of the unlimed soil profile and the concentration decreased significantly in the same horizons of the limed soil profile. Long-term liming promoted changes in Al compounds throughout the soil profile.

Type
Crops and Soils Research Paper
Copyright
Copyright © Cambridge University Press 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Álvarez, E, Monterroso, C and Fernández-Marcos, ML (2002) Aluminium fractionation in Galician (NW Spain) forest soils as related to vegetation and parent material. Forest Ecology and Management 166, 193206.Google Scholar
Álvarez, E, Viadé, A and Fernández-Marcos, ML (2009) Effect of liming with different sized limestone on the forms of aluminium in a Galician soil (NW Spain). Geoderma 152, 18.Google Scholar
Álvarez, E, Fernández-Sanjurjo, MJ, Otero, XL and Macías, F (2010) Aluminium geochemistry in the bulk and rhizospheric soil of the species colonising an abandoned copper mine in Galicia (NW Spain). Journal of Soils and Sediments 10, 12361245.Google Scholar
Álvarez, E, Fernández-Sanjurjo, MJ, Seco, N and Núñez, A (2012) Use of mussel shells as a soil amendment: effects on bulk and rhizosphere soil, and pasture production. Pedosphere 22, 152164.Google Scholar
Bascomb, CL (1968) Distribution of pyrophosphate extractable iron and organic carbon in soils of various groups. Journal of Soil Science 19, 251268.Google Scholar
Blakemore, LC (1978) Exchange complex dominated by amorphous material ECDAM). In Smith, GD (ed), The Andisol Proposal. Wellington, New Zealand: Soil Bureau, DSIR, pp. 2122.Google Scholar
Bronick, CJ and Lal, R (2005) Soil structure and management: a review. Geoderma 124, 322.Google Scholar
Caires, EF, Churka, S, Garbuio, FJ, Ferrari, RA and Morgano, MA (2006) Soybean yield and quality as a function of lime and gypsum applications. Scientia Agricola (Piracicaba, Brazil) 63, 370379.Google Scholar
Caires, EF, Garbuio, FJ, Churka, S, Barth, G and Corrêa, JCL (2008) Effects of soil acidity amelioration by surface liming on no-till corn, soybean, and wheat root growth and yield. European Journal of Agronomy 28, 5764.Google Scholar
Conyers, MK, Heenan, DP, McGhie, WJ and Poile, GP (2003) Amelioration of acidity with time by limestone under contrasting tillage. Soil and Tillage Research 72, 8594.Google Scholar
Đalović, IG, Jocković, ĐS, Dugalić, GJ, Bekavac, GF, Purar, B, Šeremešić, SI and Jocković, (2012) Soil acidity and mobile aluminum status in pseudogley soils in the Čačak–Kraljevo Basin. Journal of the Serbian Chemical Society 77, 833843.Google Scholar
Delhaize, E, Gruber, BD and Ryan, PR (2007) The roles of organic anion permeates in aluminium resistance and mineral nutrition. FEBS Letters 581, 22552262.Google Scholar
Dougan, WK and Wilson, AL (1974) The absorptiometric determination of aluminium in water. A comparison of some chromogenic reagents and the development of an improved method. The Analyst 99, 413430.Google Scholar
Eidukeviciene, M, Ozheraitiene, DJ, Tripolskaja, LN and Marcinkonis, SI (2001) The effect of long-term liming on the chemical properties of Lithuanian soils. Eurasian Soil Science 34, 9991005.Google Scholar
Eidukeviciene, M, Volungevicius, J, Marcinkonis, S, Tripolskaja, L, Karcauskiene, D, Fullen, MA and Booth, CA (2010) Interdisciplinary analysis of soil acidification hazard and its legacy effects in Lithuania. Natural Hazards and Earth System Sciences 10, 14771485.Google Scholar
Eimil-Fraga, C, Álvarez-Rodríguez, E, Rodríguez-Soalleiro, R and Fernández-Sanjurjo, MJ (2015) Influence of parent material on the aluminium fractions in acidic soils under Pinus pinaster in Galicia (NW Spain). Geoderma 255–256, 5057.Google Scholar
Fernández-Sanjurjo, MJ, Urrutia Mera, M and García-Rodeja, E (1991) Efecto del encalado de base y de mantenimiento sobre las propiedades de un suelo sobre esquistos de Galicia. NACC: Nova Acta Científica Compostelana. Bioloxía 2, 6578.Google Scholar
Fernández-Sanjurjo, MJ, Álvarez, E and García-Rodeja, E (1995) Efecto del encalado sobre ciertas propiedades de la solución del suelo, la fracción coloidal y la disponibilidad de fósforo. Edafología 1, 119127 (in Spanish).Google Scholar
Fernández-Sanjurjo, MJ, Álvarez, E and García-Rodeja, E (1998) Speciation and solubility control of aluminium in soils developed from slates of the river Sor watershed (Galicia, NW Spain). Water, Air, and Soil Pollution 103, 3553.Google Scholar
Ferro-Vazquez, C, Novoa-Munoz, JC, Costa-Casais, M, Klaminder, J and Martinez-Cortizas, A (2014) Metal and organic matter immobilization in temperate podzols: a high resolution study. Geoderma 217–218, 225234.Google Scholar
Fuentes, JP, Bezdicek, DF, Flury, M, Albrecht, S and Smith, JL (2006) Microbial activity affected by lime in a long-term no-till soil. Soil and Tillage Research 88, 123131.Google Scholar
García-Rodeja, E, Novoa, JC, Pontevedra, X, Martinez-Cortizas, A and Buurman, P (2004) Aluminium fractionation of European volcanic soils by selective dissolution techniques. Catena 56, 155183.Google Scholar
Guo, J, Vogt, RD, Zhang, X, Zhang, Y, Seip, H, Xiao, J and Tang, H (2006) Aluminium mobilization from acidic forest soils in Leigongshan area, Southwestern China: laboratory and field study. Archives of Environmental Contamination and Toxicology 51, 321328.Google Scholar
Guo, J, Zhang, X, Vogt, RD, Xiao, J, Zhao, D, Xiang, R and Luo, J (2007) Evaluating main factors controlling aluminum solubility in acid forest soils, southern and Southwestern China. Applied Geochemistry 22, 388396.Google Scholar
Hargrove, WL and Thomas, GW (1984) Extraction of aluminum from aluminum-organic matter in relation to titratable acidity. Soil Science Society of America Journal 48, 14581460.Google Scholar
Holmström, SJM, Riise, G, Tau Strand, L, Geibe, C, van Hees, PAW, Wu, Q and Lundström, US (2003) Effects of lime and ash treatments on DOC fractions and low molecular weight organic acids in soil solutions of acidified podzolic soils. Water, Air and Soil Pollution: Focus 3, 97120.Google Scholar
Kamprath, EJ (1970) Exchangeable aluminum as a criterion for liming leached mineral soils. Soil Science Society of America Journal 34, 252254.Google Scholar
Kovácik, J, Štork, F, Klejdus, B, Grúz, J and Hedbavny, J (2012) Effect of metabolic regulators on aluminium uptake and toxicity in Matricaria chamomilla plants. Plant Physiology and Biochemistry 54, 140148.Google Scholar
Kunhikrishnan, A, Thangarajan, R, Bolan, NS, Xu, Y, Mandal, S, Gleeson, D, Seshadri, B, Zaman, M, Barton, L, Tang, C, Luo, J, Dalal, R, Ding, W, Kirkham, MB and Naidu, R (2016) Functional relationships of soil acidification, liming, and greenhouse gas flux. Advances in Agronomy 139, 171.Google Scholar
Lee, GH, Song, YG, Moon, JW and Moon, HS (2012) Aluminum solubility of Andisols in Jeju Island, Korea. Economic and Environmental Geology 45, 89104.Google Scholar
Llorente, M and Turrion, MB (2010) Microbiological parameters as indicators of soil organic carbon dynamics in relation to different land use management. European Journal of Forest Research 129, 7381.Google Scholar
Marcinkonis, S and Tripolskaja, L (2008) The soil acidity parameters of soils with stopped liming. Latvian Journal of Agronomy 11, 250256.Google Scholar
Meriga, B, Reddy, BK, Jogeswar, G, Reddy, LA and Kishor, PBK (2003) Alleviating effect of citrate on aluminium toxicity of rice (Oryza sativa L.) seedlings. Current Science 85, 383386.Google Scholar
Moir, JL and Moot, DJ (2010) Soil pH, exchangeable aluminium and lucerne yield responses to lime in a South Island high country soil. Proceedings of the New Zealand Grassland Association 72, 191196.Google Scholar
Nazarkiewicz, M and Kaniuczak, J (2012) The effect of liming and mineral fertilization on the reaction, hydrolitic acidity, exchangeable acidity and content of exchangeable aluminium in haplic luvisols. Soil Science Annual 63, 4348.Google Scholar
Nikitin, BA (1999) Methods for soil humus determination. AgroChemistry 3, 156158.Google Scholar
Nikorych, VA, Szymański, W, Polchyna, SM and Skiba, M (2014) Genesis and evolution of the fragipan in Albeluvisols in the Precarpathians in Ukraine. Catena 119, 154165.Google Scholar
Núñez-Delgado, A, López-Perıago, E and Dıaz-Fierros-Viqueira, F (2002) Pollution attenuation by soils receiving cattle slurry after passage of a slurry-like feed solution: column experiments. Bioresource Technology 84, 229236.Google Scholar
Peech, L, Alexander, LT and Dean, LA (1947) Methods of Analysis for Soil Fertility Investigations. USDA, Circular No. 757. Washington, DC, USA: USDA.Google Scholar
Pousada-Ferradás, Y, Seoane-Labandeira, S, Mora-Gutiérrez, A and Núñez-Delgado, A (2012) Risk of water pollution due to ash–sludge mixtures: column trials. International Journal of Environmental Science and Technology 9, 2129.Google Scholar
Prado, RM, Natale, W and Rozane, DE (2007) Soil-liming effects on the development and nutritional status of the carambola tree and its fruit-yielding capacity. Communications in Soil Science and Plant Analysis 38, 493511.Google Scholar
Repsiene, R and Karcauskiene, D (2016) Changes in the chemical properties of acid soil and aggregate stability in the whole profile under long-term management history. Acta Agriculturae Scandinavica, Section B – Soil & Plant Science 66, 671676.Google Scholar
Rezaee, F, Ghanati, F and Behmanesh, M (2013) Antioxidant activity and expression of catalase gene of (Eustoma grandiflorum L) in response to boron and aluminum. South African Journal of Botany 84, 1318.Google Scholar
Rivas-Pérez, I, Fernández-Sanjurjo, MJ, Núñez-Delgado, A, Macías, F, Monterroso, C and Álvarez-Rodríguez, E (2016) Aluminum fractionation and speciation in a coal mine dump: twenty years of time-course evolution. Geoderma 273, 4553.Google Scholar
SAS Institute (2011). The SAS System for Windows Version 9.3. Cary, NC, USA: SAS Institute.Google Scholar
Seco, N, Fernández-Sanjurjo, MJ, Núñez-Delgado, A and Alvarez, E (2014) Spreading of mixtures including wastes from the mussel shell treatment industry on an acid soil: effects on the dissolved aluminum species and on pasture production. Journal of Cleaner Production 70, 154163.Google Scholar
Singh, A and Agrawal, M (2008) Acid rain and its ecological consequences. Journal of Environmental Biology 29, 1524.Google Scholar
Staugaitis, G and Vaišvila, Z (2015) Inovatyvūs Dirvotyros ir Agrochemijos Mokslo Sprendimai. Kaunas, Lithuania: Lithuanian Center for Agrarian and Forest Sciences (in Lithuanian).Google Scholar
Urrutia, M, Macías, F and Garcíıa-Rodeja, E (1995) Evaluación del CuCl2 y del LaCl3 como extractantes de aluminio en suelos ácidos de Galicia. NACC: Nova Acta Científica Compostelana. Bioloxía 5, 173182.Google Scholar
Walna, B, Spychalski, W and Siepak, J (2005) Assessment of potentially reactive pools of aluminium in poor forest soils using two methods of fractionation analysis. Journal of Inorganic Biochemistry 99, 18071816.Google Scholar
Wang, X, Cammeraat, ELH, Cerli, C and Kalbitz, K (2014) Soil aggregation and the stabilization of organic carbon as affected by erosion and deposition. Soil Biology and Biochemistry 72, 5565.Google Scholar
WRB IUSS Working Group (2014). World Reference Base for Soil Resources. World Soil Resources Reports 106. Rome, Italy: FAO.Google Scholar
Yamamoto, T, Okuda, H, Nozawa, R, Furukawa, J and Miura, K (2015) Enhancement of cold tolerance promotes resistance to aluminum stress. International Journal of Plant Biology and Research 3, 16.Google Scholar
Zhu, M, Jiang, X and Ji, G (2004) Experimental investigation on aluminum release from haplic acrisols in Southeastern China. Applied Geochemistry 19, 981990.Google Scholar