Tag Archives: soil penetration resistance

1115–1126 C.A. Alesso, P.A. Cipriotti, M.J. Masola, M.E. Carrizo, S.C. Imhoff, L. Rocha-Meneses and D.L. Antille
Spatial distribution of soil mechanical strength in a controlled traffic farming system as determined by cone index and geostatistical techniques
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Spatial distribution of soil mechanical strength in a controlled traffic farming system as determined by cone index and geostatistical techniques

C.A. Alesso¹*, P.A. Cipriotti², M.J. Masola¹, M.E. Carrizo¹, S.C. Imhoff¹, L. Rocha-Meneses³ and D.L. Antille⁴*

¹ICiAgro Litoral, Universidad Nacional del Litoral-CONICET, Kreder 2805, Esperanza, Santa Fe S3080HOF, Argentina
²IFEVA, Universidad de Buenos Aires-CONICET, Av. San Martín 4453, Buenos Aires C1417DSE, Argentina
³Estonian University of Life Sciences, Institute of Technology, Chair of Biosystems Engineering, Kreutzwaldi 56, EE51006 Tartu, Estonia
⁴CSIRO Agriculture and Food, Black Mountain Science and Innovation Precinct, Clunies Ross street, Canberra ACT 2601, Australia
*Correspondence: calesso@fca.unl.edu.ar, Dio.Antille@csiro.au

Abstract:

Controlled traffic farming (CTF) is a mechanisation system in which all load-bearing wheels are confined to the least possible area of permanent traffic lanes and where crops are grown in permanent, non-trafficked beds. In well-designed systems, the area affected by traffic represents less than 15% of the total field cropped area. The extent and distribution of soil compaction at locations laterally outboard of the permanent traffic lanes may explain the performance of the crop on the rows located either side of the wheeling. This compaction is due to lateral displacement of soil caused by repetitive wheeling, the effect of soil-tyre interaction and the soil conditions (strength) at the time of traffic. The impact of compaction on crop rows adjacent to permanent traffic lanes is also dependent on the seasonal effect of weather, because of changes in soil water availability. This work was conducted to model the spatial distribution of soil mechanical strength under increasing number of tractor passes to simulate the soil conditions that may be encountered in CTF systems at locations near-permanent traffic lanes. The study was conducted on a Typic Argiudoll (26% clay, 72% silt, 2% sand) with four traffic intensities (0, 6, 12 and 18 passes) using a 120 HP tractor (overall mass: 6.3 Mg). Traffic treatments were applied to experimental plots using a completely randomized block design with three replications per treatment. The spatial distribution of soil strength within wheeled and non-wheeled zones was determined using a cone penetrometer (depth range: 0–300 mm) and geostatistical techniques. In all treatments, cone index showed a quadratic response with depth, which explained between 67% and 88% of the variation in soil strength. The number of tractor passes had no effect on the range of spatial dependence of residuals. No differences were observed in the proportion of grid cells where penetration resistance was greater than 2 MPa (considered to be the soil strength limit for root growth of most arable crops) between-traffic treatments, or wheeled and non-wheeled zones, respectively. The overall mean proportion (± 95% confidence interval) of grid cells (4.9 ± 4.5%) suggested that this measure has a relatively high variability and therefore may not be a reliable parameter to be used in the design of future experimental work.

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2438–2444 A.V. Trushkov, M.Y. Odabashyan, K.Sh. Kazeev and S.I. Kolesnikov
Change of physical properties of arable chernozem in the initial period of the after agricultural abandonment regime
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Change of physical properties of arable chernozem in the initial period of the after agricultural abandonment regime

A.V. Trushkov*, M.Y. Odabashyan, K.Sh. Kazeev and S.I. Kolesnikov

Southern Federal University, Academy of Biology and Biotechnology named
after D.I. Ivanovsky, Stachki Ave. 194/1, RU344090 Rostov-on-Don, Russia
*For correspondence: trushkov_tolik@mail.ru

Abstract:

A field experiment was conducted in the botanical garden of the South Federal University (Rostov-on-Don, Russia), which was aimed at converting the old arable land plot to the arable regime. Physical properties of chernozems were studied during the first years of the postagrogenic period in different plots, such as: a virgin steppe plot, an arable plot and an abandoned plot. During the course of the experiment it was revealed that physical properties of postagrogenic soils change due to vegetation development after tillage is discontinued. Within three years of research a biological diversity of the floristic composition in the abandoned plot increased from 9 species (during the first year) up to 38 species of plants (3 years later). Vegetation development served as a cause of changes in physical properties of chernozems. Temperature of the abandoned soils decreased along with soil moisture growth, if compared to the relevant indices of the arable plot of land. Owing to the root development and cessation of the agricultural impact, density of the upper horizon in the abandoned plot dropped by 10% on average. A positive correlation was revealed between the chernozem density and its penetration resistance (r = 0.70) and temperature (r = 0.73), whereas an inverse correlation was detected between the chernozem density and its moisture content (r = -1.0).

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