Soil stabilisation by water repellency under no-till management for soils with contrasting mineralogy and carbon quality

No-till soil management is common around the globe, but the impacts on soil structural quality varies depending on cropping practice and inherent soil properties. This study explored water repellency as a driver of soil stabilization, as affected by soil mineralogy, granulometry and organic carbon quality in three Mollisols and one Vertisol under no-till management and with different levels of cropping intensity. The studied soils were located along a west-east textural gradient in the northern part of the Pampean region of Argentina. Cropping intensity treatments evaluated in each one of the soils were: Poor Agricultural Practices (PAP) close to a monoculture, Good Agricultural Practices (GAP) involving a diverse crop rotation and more targeted inputs, and the soil in the surrounding natural environment (NE) as a reference. NE had the greatest aggregate stability (MWD) of all cropping intensities, with GAP being more stable than PAP for Mollisols and PAP being greater than GAP for the Vertisol. This trend matched the Repellency Index (Rindex), with greater Rindex associated with greater MWD, including the difference between the Mollisols and Vertisol. However, the persistence of water repellency, measured by the Water Drop Penetration Time (WDPT) test followed the trend NE > GAP > PAP regardless of soil type. The increases in Rindex and MWD were related to higher intensification as measured by the Crop Sequence Index, and decreased with greater soybean occurrence in the sequence. Both WDPT and Rindex were closely related to aggregate stability, particularly for Mollisols. These results highlight the importance of considering the inherent soil characteristics texture and mineralogy to understand aggregate stabilization mediated by water repellency. Good correlations between soil water repellency, organic carbon fractions and aggregate stability were found. Under no-till, crop rotations can be altered to increase soil stability by inducing greater water repellency in the soils. The findings suggest that water repellency is a major property influencing soil structure stabilization, thus providing a useful quality indicator

Behrends Kraemer F., P. Hallett, H.J.M. Morrás, L. Garibaldi, D. J. Cosentino, M. Duval, J.A. Galantini. 2019. Soil stabilisation by water repellency under no-till management for soils with contrasting mineralogy and carbon quality. Geoderma 355: 113902. Doi 10.1016/j.geoderma.2019.113902

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Soil organic fractions: Carbon, Nitrogen, Phosphourus and Sulphur

Organic fractions, N, P, and S changes in a semiarid Haplustoll of Argentine under different crop sequences

Crop sequences play an important role in changing soil properties. The knowledge of the chemical composition, turnover, dynamics, and biological effects of different fractions of soil organic carbon (SOC), nitrogen (N), phosphorus (P) and sulfur (S) components will result in a better understanding of soil productivity. The objective of this research was to compare the effects of crop rotation on SOC, N, P, and S evolution in two granulometric fractions of an Entic Haplustoll. Rotations of mixed pasture (5.5 years)-annual crops (4.5 years) (Pa-C), and wheat (Triticum aestivum L.)-sunflower (Heliantus annus L.) (W-S), and a reference (Ref), which was located between them, were studied. Fine (<100 µm, FF) and coarse (100-2000 µm, CF) soil granulometric fractions were separated by wet sieving. In each fraction total N and S, and several SOC and P forms were determined. Similar contents (5.23 to 6.07 Mg ha-1) of humic acid (HA) carbon were found in the three situations. The Pa-C rotation maintained the SOC level at 17.33 Mg ha-1 in the Fine Fraction during a 10-year period. On the contrary, SOC was sharply lower (11.16 Mg ha-1) in the same fraction in the W-S treatment. Losses of SOC, N, P and S were highest in the Coarse Fraction thus showing the dynamics of this soil fraction and its important role in plant nutrient turnover and availability to growing crops.

Soil organic carbon, N, P, S, Semiarid, Entic Haplustoll

Galantini J.A. and R.A. Rosell. 1997. Organic fractions, N, P, and S changes in a semiarid Haplustoll of Argentine under different crop sequences. Soil and Tillage Research 42: 221-228.

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Soil Physical compaction in production systems

Physical properties in no till soils of the southwest of Buenos Aires

Soil physical quality has great importance as a regulator of several processes that affect the functioning of agroecosystems. However, because physical quality problems are complex, persistent, difficult to solve, often its importance is not recognized and its effects are attributed to other causes. Since the large expansion of no tillage (NT) in the southwest of Buenos Aires (SOB), it is needed a more detailed knowledge of the physical condition of soils under NT. In addition, in this chapter there were included some aspects to be considered in the future for the adequate implementation of the NT in the region, which would allow the development of conservation agriculture (CA). Soils under NT in the region showed great variations in the accumulation of surface residues and a large proportion did not have adequate soil cover (> 30%), a necessary requirement of CA. Therefore, in studies that evaluate the effect of NT it is crucial to detail both the amount of residues and the soil cover. In terms of soil porosity, the main limitation was associated with low macroporosity (pores> 30 μm) that would affect soil aeration and root growth. Although it is not possible to attribute the loss of macroporosity to NT management, the way in which it has been implemented in the region (e. g. used in soils with a plow pan, lack of rotations, scarce soil cover) has not been able to reverse the problems of physical degradation. In soils of the SOB under NT it is necessary the development of land management practices that contribute to the biotic regeneration of soil structure (e.g. pasture rotations, inclusion of crops with deep roots) to ensure adequate physical quality. In addition, in the region it would be very important to increase soil cover by residues and to establish crop rotations, to move towards CA.

López, F.M.; M. Duval; J.M. Martínez; J.A. Galantini. 2018. Propiedades físicas en suelos bajo siembra directa del sudoeste bonaerense. En: Compactaciones Naturales y Antrópicas en Suelos Argentinos (Eds. Perla Imbellone y Carina Álvarez) 532-547.

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