Abstract
Purpose
The influence of iron and aluminium (hydr)oxide on soil aggregation is still not sufficiently understood. Therefore, we undertook a study on the effects of Al and Fe forms on soil structure and their mutual relationships in sandy soil under long-term fertilisation experiments near Skierniewice (Poland).
Materials and methods
In this study, we examined three treatments of soil under long-term fertilisation: in 94- and 41-year- experiments: (1) control—without mineral fertilisation (Co); (2) mineral fertilisation (NPK); (3) mineral fertilisation + calcium (CaNPK). Treatments in the 25-year experiment included the following: (1) farmyard manure and no mineral fertilisation (FYM); (2) farmyard manure + mineral fertilisation (FYM + NPK); (3) farmyard manure + mineral fertilisation with calcium (FYM + CaNPK). We analysed parameters of soil structure such as dry-sieved aggregate and water-stable aggregate contents as well as calculating soil structure indices. Total contents of Al and Fe and their free oxides were determined.
Results and discussion
The results showed that in 94-year experiment, for NPK and CaNPK treatments, the content of dry-sieved macro-aggregates (DSAma) in the 5–3- and 3–1-mm size classes was significantly higher by 144 and 192% as well as by 37 and 36%, respectively, compared with that in the Co treatment. In comparison with the control, a lower percentage of macro-aggregate destruction (by 50%) and crusting index (Ic) (by 16%) was seen during the treatment with NPK fertilisation with added Ca. In the 41-year experiment, the structure coefficient significantly decreased after NPK and CaNPK fertilisation. In the 25-year experiment, the mineral fertilisation in combination with FYM did not affect individual size classes of DSAma. Values of Ic significantly decreased after the application of FYM in both NPK and CaNPK treatments. Overall, the highest number of correlations between Al and Fe free oxides and the soil structure was in the 94-year experiment, followed by the 25-year experiment, and the lowest number of significant correlations was in the 41-year experiment.
Conclusions
Fe and Al oxides might act as important agents for stabilising mainly the higher size classes of DSAma. On the other hand, Fe, Al and their oxides did not have effect on the smaller size classes of DSAma, particularly in the 94-year experiment. Overall, the application of mineral fertilisers with farmyard manure could accelerate the positive changes in the structure of sandy soil, even, in particular, through Fe oxides.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Amézketa E (1999) Soil aggregate stability: a review. J Sustain Agric 14:83–151
Barral MT, Arias M, Guerif J (1998) Effects of iron and organic matter on the porosity and structural stability of soil aggregates. Soil Tillage Res 46:261–272
Barrón V, Torrent J (2013) Iron, manganese and aluminium oxides and oxyhydroxides. EMU Notes Mineral 14:297–336
Barthes B, Kouakoua E, Larre-Larrouy MC, Razafimbelo T, deLuca EF, Azontonde A, Neves C, deFreitas PL, Feller C (2008) Texture and sesquioxide effects on water-stable aggregates and organic matter in some tropical soils. Geoderma 143:14–25
Bartoli F, Burtin G, Herbillon AJ (1991) Disaggregation and clay dispersion of oxisols: Na resin, a recommended methodology. Geoderma 49:301–317
Briedis C, Caires EF, Navarro JF, Ingaki TM (2012) Soil organic matter pools and carbon protection mechanisms in aggregate classes influenced by surface liming in a no-till system. Geoderma 170:80–88
Bronick CJ, Lal R (2005) Soil structure and management: a review. Geoderma 124:3–22
Chandra J, Guéguen P, Bonilla LF (2017) PGA – PGVs considered as a stress-strain proxy for predicting nonlinear soil response. Soil Dyn Eathq Eng 85:146–160
Duiker SW, Rhoton FE, Torrent J, Smeck NE, Lal R (2003) Iron (hydr) oxide crystallinity effects on soil aggregation. Soil Sci Soc Am J 67:606–611
Foth HD (1990) Fundamentals of soil science. John Wiley and Sons, New York
Gleboznawcze PT (2009) Particle size distribution and textural classes of soils and mineral materials - classification of Polish Society of Soil Science 2008. Soil Sci Annu 60:5–16
Graham MH, Haynes RJ, Meyer JH (2002) Soil organic matter content and quality: effects of fertilizer applications, burning and trash retention on a long-term sugarcane experiment in South Africa. Soil Biol Biochem 34:93–102
Gruggenberger G, Elliot ET, Frey SD, Six J, Paustian K (1999) Microbial contributions to the aggregation of a cultivated grassland soil amended with starch. Soil Biol Biochem 31:407–419
Hanes J (1999) Analyzes of sorptive characteristics. SSCRI, Bratislava
Haynes R, Naidu R (1998) Influence of lime, fertilizer and manure applications on soil organic matter content and soil physical conditions: a review. Nutr Cycl Agroecosyst 51:123–137
Huang L, Wang CY, Tan WF, Hu HQ, Cai CF, Wang MK (2010) Distribution of organic matter in aggregates of eroded Ultisols, Central China. Soil Tillage Res 108:59–67
IUSS Working Group WRB(2015) World Reference Base for Soil Resources 2014, update 2015. International soil classification system for naming soils and creating legends for soil maps. World Soil Resources Reports No. 106. FAO, Rome
Keren R, Singer MJ (1991) Hydroxy-aluminum’s effect on permeability of clay-sand mixtures. Soil Sci Soc Am J 55:61–65
Kiem R, Kandeler E (1997) Stabilization of aggregates by the microbial biomass as affected by soil texture and type. Applied Soil Ecology 5(3):221–230. https://doi.org/10.1016/S0929-1393(96)00132-1
Kobierski M, Kondratowicz-Maciejewska K, Banach-Szott M, Wojewódzki P, Castejón JMP (2018) Humic substances and aggregate stability in rhizospheric and non-rhizospheric soil. J Soils Sediments 18:2777–2789
Lal R, Shukla MK (2004) Principles of soil physics. Marcel Dekker, New York
Levy GJ, Miller WP (1997) Aggregate stabilities of some southeastern U.S. soils. Soil Sci Soc Am J 61:1176–1182
Lugato E, Simonetti G, Morari F, Nardi S, Berti A, Giardini L (2010) Distribution of organic and humic carbon in wet-sieved aggregates of different soils under long-term fertilization experiment. Geoderma 157:80–85
Mehra O, Jackson J (1960) Iron oxide removal from soils and clays by a dithionite-citrate system buffered with sodium bicarbonate. Clay Clay Miner 5:317–327
Mehra P, Sarkar S, Bolan N, Chowdhury S, Desbiolles J (2019) Impact of carbonates on the mineralisation of surface soil organic carbon in response to shift in tillage practice. Geoderma 339:94–105
Mikhailova EA, Post CJ (2006) Effects of land use on soil inorganic carbon stocks in the Russian Chernozem. J Environ Qual 35:1384–1388
Nouwakpo SK, Song J, Gonzalez JM (2018) Soil structural stability assessment with the fluidized bed, aggregate stability, and rainfall simulation on long-term tillage and crop rotation systems. Soil Tillage Res 178:65–71
Oades JM, Waters AG (1991) Aggregate hierarchy in soils. Austr J Soil Res 29:815–828
Onweremadu EU, Onyia VN, Anikwe MAN (2007) Carbon and nitrogen distribution in water-stable aggregates under two tillage techniques in Fluvisols of Owerri area, southeastern Nigeria. Soil Tillage Res 97:195–206
Peng X, Yan X, Zhou H, Zhang YZ, Sun H (2015) Assessing the contributions of sesquioxides and soil organic matter to aggregation in an Ultisol under long-term fertilization. Soil Tillage Res 146:89–98
Pieri C (1991) Fertility of soils: a future for farming in the West African Savannah. Springer-Verlag, Berlin
Pires LP, Borges JA, Cooper M, Kosa JA, Heck RJ (2017) Soil structure changes induced by tillage systems. Soil Tillage Res 165:66–79
Pizzeghello D, Berti A, Nardi S, Morari F (2011) Phosphorus forms and P-sorption properties in three alkaline soils after long-term mineral and manure applications in North-Eastern Italy. Agric Ecosyst Environ 141:58–66
Pizzeghello D, Berti A, Nardi S, Morari F (2014) Phosphorusrelated properties in the profiles of three Italian soils after long-term mineral and manure applications. Agric Ecosyst Environ 189:216–228
Polláková N, Šimanský V, Kravka M (2018) The influence of soil organic matter fractions on aggregates stabilization in agricultural and forest soils of selected Slovak and Czech hilly lands. J Soils Sediments 18:2790–2800
Rabbi SMF, Wilson BR, Lockwood PV, Daniel H, Young IM (2014) Soil organic carbon mineralization rates in aggregates under contrasting land uses. Geoderma 216:10–18
Rabbi SMF, Wilson BR, Lockwood PV, Daniel H, Young IM (2015) Aggregate hierarchy and carbon mineralization in two Oxisols of New South Wales, Australia. Soil Tillage Res 146:193–203
Rahman MT, Zhu QH, Zhou H, Peng X (2017) The roles of organic amendments and microbial community in the improvement of soil structure of a vertisol. Appl Soil Ecol 111:84–93
Rashid MI, Mujawar LM, Shahzad T, Almeelbi T, Ismail IMI, Oves M (2016) Bacteria and fungi can contribute to nutrients biovailibility and aggregate formation in degraded soils. Microbiol Res 183:26–41
Regelink IC, Stoof CR, Rousseva S, Weng L, Lair GJ, Kram P, Nikolaidis NP, Kercheva M, Banwart S, Comans RNJ (2015) Linkages between aggregate formation, porosity and soil chemical properties. Geoderma 247–248:24–37
Rutkowska A, Pikuła D (2013) Effect of crop rotation and nitrogen fertilization on the quality and quantity of soil organic matter. In: Hernandez Soriano MC (ed) Soil processes and current trends in quality assessment. IntechOpen Limited, London, pp 249–267
Shein E, Milanovskiy E (2014) Soil structure formation: role of the soil amphiphilic organic matter. Biogeosys Tech 2:182–189
Šimanský V, Tobiašová E, Chlpík J (2008) Soil tillage and fertilization of Orthic Luvisol and their influence on chemical properties, soil structure stability and carbon distribution in water-stable macro-aggregates. Soil Tillage Res 100:125–132
Šimanský V, Polláková N, Halmo S (2014) Soil crust in agricultural land. Acta Fytotechn Zootech 17:109–114
Šimanský V, Kravka M, Jonczak J (2017) Stability of soil aggregates in loamy soils of Slovakia. J Elem 22:581–592
Šimanský V, Juriga M, Jonczak J, Uzarowicz L, Stapień W (2019) How relationships between soil organic matter parameters and soil structure characteristics are affected by the long-term fertilization of a sandy soil. Geoderma 342:75–84
Six J, Feller C, Denef K, Ogle SM, Moraes Sa JC, Albrecht A (2002) Soil organic matter, biota and aggregation in temperate and tropical soils-effects of no-tillage. Agronomie 22:755–775
Soil Survey Division Staff (1993) Soil Survey Manual. Soil conservation service. C. Ditzler, K. Scheffe, and H.C. Monger (eds.). U.S. Department of Agriculture Handbook 18. http://www.nrcs.usda.gov/wps/portal/nrcs/detail/soils/ref/?cid=nrcs142p2_054262
Soinne H, Hovi J, Tammeorg P, Turtola E (2016) Effect of biochar on phosphorus sorption and clay soil aggregate stability. Geoderma 219–220:162–167
Suda A, Makino T (2016) Functional effects of manganese and iron oxides on the dynamics of trace elements in soils with a special focus on arsenic and cadmium: a review. Geoderma 270:68–75
Tate RL (1995) Soil microbiology. John Wiley and Sons, New York
Tian K, Zhao Y, Xu X, Hai N, Huang B, Deng W (2015) Effects of long-term fertilization and residue management on soil organic carbon changes in paddy soils of China: a meta-analysis. Agric Ecosyst Environ 204:40–50
Valla M, Kozák J, Ondráček V (2000) Vulnerability of aggregates separated from selected anthorsols developed on reclaimed dumpsites. Rost Vyroba 46:563–568
Van Reeuwijk L (1995) Procedures for soil analysis. Technical Paper 9, International Soil Reference and Information Centre
Wang S, Zheng Z, Li T, Li Y (2013) Effects of age of tea plantations on distribution of exchangeable base cations in soil aggregates. Acta Pedol Sin 50:1014–1021
Wang P, Wang J, Zhang H, Dong Y, Zhang Y (2019) The role of iron oxides in the preservation of soil organic matter under long-term fertilization. J Soils Sediments 19:588–598
Wei X, Wang X, Ma T, Huang L, Pu Q, Hao M, Zhang X (2017) Distribution and mineralization of organic carbon and nitrogen in forest soils of the southern Tibetan Plateau. Catena 156:298–304
Wu X, Cai C, Wang J, Wei Y, Wang S (2016) Spatial variations of aggregate stability in relation to sesquioxides for zonal soils, South-central China. Soil Tillage Res 157:11–22
Young R N, Warkentin B P (1975) Soil properties and behaviour. Dev. in Geotech. Eng. 5, Amsterdam, Oxford, New York
Zhang S, Zhang B, Li X (2002) Evolution of soil fertility and fertilizer benefits under different soil types and cropping systems. Plant Nutr Fert Sci 8:9–15
Zhang JC, Zhang L, Wang P, Huang QW, Yu GH, Li DC, Shen QR, Ran W (2013) The role of non-crystalline Fe in the increase of SOC after long-term organic manure application to the red soil of southern China. Eur J Soil Sci 64:797–804
Zhang L, Chen W, Burger M, Yang L, Gong P, Wu Z (2015) Changes in soil carbon and enzyme activity as a result of different long-term fertilization regimes in a greenhouse field. PLoS One 10:1–13. https://doi.org/10.1371/journal.pone.0118371
Zhu F, Li Y B, Xue S G, Hartley W, Wu H (2016) Effects of iron-aluminium oxides and organic carbon on aggregate stability of bauxite residues. Environ Sci Pollut Res Int 23:9073–9081
Acknowledgements
The authors would like to very much thank Danny Angus (Belfast, Northern Ireland) for improving the English text and also the editor and the reviewers for constructive comments.
Funding
The research was partially supported by the Slovak Research and Development Agency under project no. APVV-15-0160 and the Cultural and Educational Grant Agency MŠVVaŠ SR (KEGA) project no. 013SPU-4/2019.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible editor: Claudio Colombo
Publisher’s note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Šimanský, V., Jonczak, J. Aluminium and iron oxides affect the soil structure in a long-term mineral fertilised soil. J Soils Sediments 20, 2008–2018 (2020). https://doi.org/10.1007/s11368-019-02556-4
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11368-019-02556-4