A field study was carried out to evaluate the effects of tillage practices on soil physical properties in Mwala district, Eastern Kenya, during the long rains (LR) and short rains (SR) of 2012/13. The treatments were disc ploughing (DP), disc ploughing and harrowing (DPH), ox-ploughing (OX), subsoiling-ripping (SSR), hand hoeing with tied ridges (HTR), hand hoeing only (H). These were investigated under three cropping systems of sole maize, sole bean, and maize-bean intercrop in a split-plot design with four replications. Soil physical properties were monitored at different weeks after planting (WAP) throughout the growing seasons. A four-season average shows that soil moisture content was significantly (P<0.05) higher in OX > SSR > DPH > H > HTR > DP with values ranging from 13.1 to 14.1%. Soil surface roughness and crust strength varied significantly (P<0.05) over time within the growing seasons, between the tillage practices, and across the different seasons with values ranging from 26 to 66% and 1.21 to 1.31 MPa, respectively. Tillage practices and cropping systems did not significantly affect bulk density, porosity, or Ksat values. It is apparent that long term tillage experiment (>4 seasons) would be required to detect changes in soil physical properties as a result of the soil management practices.
1. Introduction
Smallholder agriculture in semiarid areas is hampered by accelerated soil erosion, induced soil moisture deficits, soil fertility depletion, and soil crusting and compaction [1]. The soil crusting and compaction problem is attributed to inherent soil properties and poor tillage practices [2]. The semiarid areas of Kenya are characterized by temporal and spatial variability of rainfall which is not suitable for sustainable rainfed agriculture [1, 3]. Thus, resource-poor farmers in these areas who entirely rely on rainfed agriculture are subject to various hydrological constraints. The rainfall occurrence is bimodal with two distinct rainy seasons: the short and long rains. In Kenya’s semiarid areas, the short rains (October to December) are more reliable and are evenly distributed and more often support plant growth [4]. However, very high soil moisture deficits experienced in these areas usually result in significant decreases in crop yields under rainfed conditions. Deficit of soil moisture in these areas is attributed to low infiltration rates caused by surface sealing, crusting, low organic matter content, and subsequent high runoff rates [1, 5, 6]. Soil moisture conservation under such conditions requires appropriate tillage practices that not only improve rainwater infiltration but also conserve adequate soil moisture for plant growth [7].
Soil tillage, as a necessary practice in crop production, can affect the soil physical properties that are important for plant growth [8, 9]. Improvements of root penetration, water infiltration and soil moisture storage, weed control, and supply of nutrients from rapid decomposition of organic matter are considered the most beneficial contributions of tillage to crop production [10–12].
Conventional tillage involves the mechanical soil manipulation of an entire field, by ploughing (inverting the soil) followed by one or more harrowings. The degree of soil disturbance depends on the type of implement used, the number of passes, type of soil, and intended crop type [13]. The most common conventional tillage practiced in Kenya involves the use of hand hoes, ox-drawn mould board ploughs, tractor-drawn disc ploughs, and harrows combined with straw collection and burning during land preparation [2, 14]. During the operation, the soils are cut, inverted, and pulverized burying most of the residues underneath [14]. Consequently, in many areas, especially semiarid areas, conventional agriculture has led to a decline in crop yields and profitability when compared to those realized from areas with higher rainfall [15].
Other sustainable techniques advocated in the semiarid areas for soil and water conservation have included tied ridging, cover cropping, mulching, subsoiling and ripping [16, 17]. These techniques are referred to as conservation tillage and have the potential of soil moisture retention and mitigation of intraseasonal dry spells that often result in low productivity and crop failure, reduce soil evaporation, and enable organic matter build-up which enhances water holding capacity of the soil [18–20].
Conservation tillage practices are particularly important for increasing the productivity of water through reducing runoff and evaporation and improving soil water storage [18]. In Kenya, promotion of animal-drawn conservation tillage tools such as rippers and subsoilers among smallholder farmers has resulted in improved water productivity and crop yields [21, 22]. Although conservation tillage is highly advocated, there is strong evidence that this kind of tillage may not be good with soils prone to surface crusting and sealing, a characteristic of most of the soils in the semiarid areas of Kenya [23–26]. Therefore, the local biophysical conditions in the smallholder farming systems in these semiarid areas need to be considered and deliberate adaptation efforts made.
The success of any tillage practices is directly related to the improvement of the soil physical properties which in turn may affect the growth and yield of crops due to the different soil conditions created. In a review on the effect of soil physical properties on soil moisture, Strudley et al. [27] showed that bulk density, porosity, soil surface sealing and crusting, surface roughness, hydraulic conductivity, and infiltration rates were highly influenced by different tillage. Therefore, the choice of any tillage system is too critical for maintenance of the soil physical properties necessary for crop growth [28]. However, the resulting effect of tillage on selected physical properties depends on the site-specific biophysical environment such as seasonal variability in rainfall, inherent soil fertility status, or the prevailing climatic conditions [29]. Few studies have measured these soil physical properties, especially in semiarid Eastern Kenya, hence the essence for the study reported herein.
Recent efforts have focused on minimum tillage practices as a soil and water conservation measure [30, 31]. Nonetheless, maize-legume cropping systems are popular in improving land use efficiency and economic returns. In order to exploit these practices, there is a need to understand the influence of tillage and cropping systems on selected soil physical properties in dryland cropping systems for sustained productivity. The objective of this study was to investigate the effect of selected tillage practices and cropping systems on selected soil physical properties in semiarid Mwala district, Eastern Kenya. Specifically, their effects on soil moisture, soil surface roughness, crust strength, saturated hydraulic conductivity, bulk density and porosity.
2. Materials and Methods2.1. Study Site Description
The study was conducted in Mbiuni location, Mwala district, Machakos County, Eastern Kenya (1°15′S, 37°25′E). The area is characterized by low, erratic, and poorly distributed bimodal rainfall that makes crop production difficult under rainfed conditions. The long rains commence in mid-March and end in May while short rains start in mid-October and end in late November. The mean annual rainfall for Mwala district is 596.7 mm [32]. Maize and beans dominate household consumption. Pulses are grown in the district and the predominant ones are beans, pigeon peas, cowpeas, green grams, and chickpeas. Soil chemical and physical properties at the site are given in Table 1. The study site was previously under beans and the slope was <2%.
Baseline chemical and physical properties of the experimental site (0–30 cm).
Soil property
Values
pH (H2O)
6.50
pH (0.01 M CaCl2)
5.61
%C
1.10
%N
0.09
K cmol/kg
2.35
Na cmol/kg
0.46
Ca cmol/kg
2.31
Mg cmol/kg
0.39
CEC cmol/kg
6.70
P (mg/kg)
13.50
Sand (%)
22.00
Silt (%)
39.00
Clay (%)
39.00
Textural class
Clay loam
Bulk density (g/cm3)
1.27
Saturated hydraulic conductivity (Ksat) (cm/h)
0.27
Saturation (cm/cm3)
0.664
Field capacity (cm/cm3)
0.508
Wilting point (cm/cm3)
0.480
Plant available water (cm/cm3)
0.028
2.2. Experimental Design and Layout
The trials were established in 2012 and ran for four seasons during the long (LR) (March–May) and short rains (SR) (October–December) (i.e., LR 2012, SR 2012, LR 2013, and SR 2013). The treatments consisted of six tillage practices: disc ploughing (DP), disc ploughing and harrowing (DPH), ox-ploughing (OX), hand hoeing with tied ridges (HTR), hand hoeing only (H) and subsoiling-ripping (SSR). The cropping systems treatments were sole maize, sole bean, and maize-bean intercrop. The treatment factors were arranged in a split-plot design with tillage practices as the main plots and the cropping system as the subplots and replicated four times in plot sizes of 25 m2. Time in weeks after planting (WAP) and season were considered as experimental factors to test the changes within a growing season and across the different cropping seasons.
2.3. Soil Properties Measurements
Soil moisture was monitored from crop emergence to harvesting at depths of 0–20 cm and 20–40 cm using the gravimetric method [33]. Monitoring of soil moisture was done at the 0–40 cm depth due to the concentration of active roots at this level and less below this depth range. Soil surface roughness was measured immediately after the tillage operations and before weeding was done. Readings were taken from three randomly selected positions in each tillage plot. A microrelief meter similar to that described by Kuipers [34] was used to measure surface roughness.
Crust strength (penetration resistance) was measured at the soil surface (0–10 cm depth) using a hand-held penetrometer (Eijkelkamp equipment type 1B) in three seasons (SR 2012, LR 2013, and SR 2013). Ten soil crust strength measurements were taken at randomly selected positions in each plot. The penetrometer springs and cone sizes were adjusted depending on the soil strength. Crust strength was calculated as
(1)CR=I×CsAC,
where CR is the cone resistance (N cm−2), I is the impression on the scale (cm), Cs is the spring constant (N cm−1), and AC is the area of the cone (cm2).
Saturated hydraulic conductivity (Ksat) determinations were done in the laboratory using the constant head method as described by Klute and Dirksen [35]. Undisturbed soil core rings (5 cm depth, volume 98.13 cm3) collected from the field were carefully trimmed to the size of the core ring. A piece of muslin cloth held with a rubber band was used on one side of the core ring to protect the soil from spilling but to allow water to pass through. The samples were then saturated for 24 hours before water percolation tests were done. The volume of water that passed through the soil sample was measured and recorded until a constant average was achieved. The Ksat was then calculated as
(2)Ksat=Q×LA×T×H,
where Q is the discharge or percolate through the soil (cm3 or mL), L is the length of the soil core (cm), A is the cross-sectional area of the soil core (cm3), T is the time taken (hours), and H is the hydraulic head difference (cm).
The bulk density was determined using undisturbed core samples from each plot. Soil core samples were carefully trimmed at both sides to the size of the core ring. The soil core was then oven-dried at 105°C to a constant mass and then weighed. Bulk density was then calculated as the mass of the dry soil divided by the core ring volume. Total porosity was then calculated from the bulk density as
(3)Totalporosity=1-ρbρs,
where ρb is the bulk density and ρs is the average particle density (2.65 Mg/m3). The Ksat, bulk density, and total porosity were determined at one or two intervals in a growing season (the beginning of the season (3 WAP) and at harvest).
2.4. Crop Management
A dryland maize variety (DH 02) and beans (rose coco: GLP 2) were used as the test crops. These crops were planted in rows in 25 m2 plots. The maize was planted at a spacing of 90 × 30 cm in pure stands while the bean plants were planted at a spacing of 45 × 15 cm. In the tied ridging plots, maize and beans were planted in the same row but in alternating hills. Thinning was done to a single plant per hill for maize and two plants for the legume, four weeks after germination.
In analysis of the soil properties, analysis of variance (ANOVA) with repeated measures was used using Genstat 14th Edition statistical software. Mean separation was done using LSD at 5% level of probability where the ANOVA F-values were significant.
3. Results and Discussion3.1. Soil Moisture Content as Affected by Tillage Practices and Cropping Systems between Season and Depth
Tillage practices resulted in significant differences in moisture content in LR 2012 (P=0.019), LR 2013 (P=0.003), and SR 2013 (P=0.001) but not in SR 2012 (P=0.158) (Table 2). However, in SR 2012, higher moisture levels were observed in OX (15.3%) and SSR (14.4%). The OX and SSR plots maintained high moisture levels in the SR 2012 and LR 2013. Subsoiling-ripping (SSR) and ox-ploughing (OX) enhance water penetration into deeper soil layers and allow deeper rooting of crops that benefit from stored water and nutrients as they exploit larger soil volumes. Steiner and Rockstrom [36] made similar observations. In LR 2012, the HTR plots had high moisture levels (15.6%) due to the microbasin formation that traps rainwater and allowed more time for infiltration and storage. In contrast to LR 2012, HTR had the lowest moisture (8.42%) in the LR 2013 season.
Soil moisture content (%) as affected by tillage, cropping systems, and depth (n=4 seasons).
Soil moisture (%)
LR 2012
SR 2012
LR 2013
SR 2013
Mean
Tillage
Hand hoeing only (H)
14.57
13.74
9.63
15.39
13.33
Hand hoeing with tied ridges (HTR)
15.61
13.80
8.42
15.26
13.27
Disc ploughing (DP)
13.68
13.94
8.82
15.89
13.08
Disc ploughing + harrowing (DPH)
15.09
13.66
8.66
16.18
13.40
Ox-ploughing (OX)
14.55
15.33
9.98
16.55
14.10
Subsoiling-ripping (SSR)
—
14.35
9.96
15.98
13.43
Mean
14.70
14.14
9.25
15.87
13.44
Cropping system
Sole bean
14.74
14.19
9.48
15.94
13.59
Sole maize
14.71
14.21
9.05
15.96
13.48
Intercrop
14.65
14.02
9.20
15.72
13.40
Depth
0–20 cm
13.85
13.09
8.04
15.15
12.53
20–40 cm
15.55
15.18
10.44
16.59
14.44
Significance levels
Time (weeks after planting)
<0.001
<0.001
<0.001
<0.001
<0.001
Tillage
0.019
0.158
0.003
<0.001
<0.001
Cropping systems
0.891
0.684
0.547
0.895
0.899
Depth
<0.001
<0.001
<0.001
0.003
<0.001
(—): not measured in that season.
Similar findings are supported by Guzha [37], who found that the higher moisture was stored in ridges and this was associated with higher roughness resulting from ridge configuration. Tied ridges create rectangular basins between ridges, which increase surface retention capacity and decrease runoff, thus improving soil moisture content and ultimately crop growth and yields. Motsi et al. [38] in Zimbabwe found that tied ridges retained significantly higher moisture than conventional tillage (ploughing) especially during the dry months. While Gicheru et al. [39], found that tied ridging conserved the lowest amount of moisture and attributed this to no runoff to impound and high evaporation losses due to increased soil surface area exposure in the semiarid areas of Laikipia district, Kenya. Gürsoy et al. [40] in semiarid Turkey found that ridge tillage accelerated drying of the seed zone; thus, low moisture contents were observed. Some water logging was observed in the LR 2012 season only and could explain the high moisture by HTR (15.61%) noted and hence the lowest moisture contents in the succeeding seasons (Table 2). Therefore, the effectiveness of tied ridges depends on the rainfall received and climatic conditions within a season.
The soil moisture decreased over time (WAP) during the four growing seasons (P<0.05). Across the profile, the soil moisture was higher in the 20–40 cm than in the 0– 20 cm depth and varied among the different tillage practices in all seasons (P<0.05). The changes in profile moisture content could be attributed to a combination of rainfall, soil evaporation, and transpiration or crop water uptake [25, 41, 42]. When the soil moisture content for each tillage method was averaged for the four seasons, a significant seasonal difference was found (P<0.05) (Table 2). Soil moisture content by tillage was higher in OX > SSR > DPH > H > HTR > DP (P<0.05). Fabrizzi et al. [43] reported an increase in soil moisture storage under conservation tillage due to decreases in evaporation, increases in the soil infiltration and the enhanced soil protection from rainfall impact. The average low soil moisture contents observed could be attributed to reduced water infiltration. This is due to the breaking of the large pores while the small pores are clogged by the dislocation of soil particles, which depend on tillage methods [44]. Soil moisture is the single most limiting factor to crop yields and thus tillage techniques that conserve moisture are important for increasing crop yields and limiting the devastating consequences of drought in semiarid areas [45].
There were no significant effects on soil moisture content due to the cropping system for all the seasons (P=0.899) (Table 2). However, in SR 2012 and LR 2013, there were significant (P<0.05) time × cropping systems interactions. From the results, there are inconsistencies observed by the cropping systems for each season on soil moisture contents that can be attributed to the varying crop requirements and climate conditions [46]. Soil water extraction by crops is determined not only by soil water content, evaporative demand and soil physical properties but also by physiological status of the crop [47] and could explain the nonsignificant effects observed.
3.2. Soil Surface Roughness
Soil surface roughness varied significantly (P<0.05) over time in the growing seasons, between the tillage practices and across the different seasons (Table 3). A four-season summary shows a trend of HTR > SSR > DP > OX > DPH > H. Soil surface roughness soon after tillage was significantly higher among the tillage practices (P<0.05) and decreased progressively in each season (Table 3). The HTR, SSR and DP had consistently higher values in all the four seasons with overall average values ranging from 27% to 66%.
Effect of tillage on soil surface roughness (n=4 seasons).
Tillage
Long rains (LR 2012)
Short rains (SR 2012)
Long rains (LR 2013)
Short rains (SR 2013)
At ploughing
Before planting
3 WAP
At ploughing
Before planting
3 WAP
At ploughing
Before planting
3 WAP
At ploughing
Before planting
3 WAP
H
36.8ab
31.8b
27.1b
30.7a
23.0a
16.2a
34.5a
25.5a
13.2a
39.0a
31.3ab
26.8bc
HTR
75.0d
72.5d
65.2d
67.8d
64.9d
58.6c
71.6d
62.6d
55.6c
72.4c
63.9d
56.0d
DP
53.7c
48.5c
40.7c
33.0ab
26.6ab
22.5a
36.8ab
27.8ab
19.5a
57.1b
49.8c
37.6c
DPH
29.8a
17.9a
13.5a
36.9b
33.7b
21.2a
40.7b
31.7b
18.2a
41.2a
28.7a
24.0ab
OX
48.1bc
38.7b
32.1bc
46.7c
32.0b
17.0a
50.5c
41.5c
14.0a
51.1b
42.1bc
14.7a
SSR
—
—
—
50.8c
47.2c
36.6b
54.6c
45.6c
33.6b
55.2b
45.1c
34.3bc
Mean
48.7
41.9
35.7
44.32
37.88
28.7
48.1
39.1
25.7
52.7
43.5
32.2
LSD (5%)
12.09
7.69
10.75
5.212
6.85
8.12
5.2
5.2
8.1
9.05
12.55
11.33
CV %
9.4
6.5
7.7
4.8
6.3
7.8
4.4
5.4
8.7
4.4
3.1
5.7
Tillage: H: hand hoeing only, HTR: hand hoeing with tied ridges, DP: disc ploughing, DPH: disc ploughing + harrowing, OX: ox-ploughing, SSR: subsoiling-ripping, and (—): not measured in that season.
Different letters within the columns indicate significant difference at 5% probability level.
The high surface roughness in HTR can be attributed to the raised ridges and basins created during tied ridging. The SSR plots had also higher surface roughness probably because of the furrows created during ripping. Ripping is usually done to open a narrow slit or furrow in the soil for sowing seeds while leaving unploughed sections between the planting rows [16]. The high values obtained in the DP plots could be attributed to the greater plough depth resulting in higher soil surface roughness which enhances greater infiltration primarily by surface retention of water in the small holes and depression. Soil surface roughness changes considerably with rainfall, wind, and cultivation events as indicated by Guzha [37], Mupangwa et al. [48], and Moreno et al. [49]. Lampurlanés and Cantero-Martínez [6] reviewed that surface roughness produced by tillage increases surface ponding, which allows rainwater to infiltrate into the soil, thus preventing runoff and increasing moisture retention in the soil profile. This explains why HTR had higher moisture levels in the LR 2012 season due to the water logging observed. Therefore, management practices aimed at adjusting the soil surface characteristics can promote soil processes that encourage soil moisture storage within the root zone [49, 50].
3.3. Crust Strength
Crust strength was affected significantly (P<0.05) by the time of measurement, tillage and the growing season. There were also significant interactions of time × season, tillage × season, and time × tillage × season (P<0.05) observed. The cropping systems did not influence the crust strength in the three seasons (P=0.379).
Increase in crust strength as a season progressed was noted (Table 4) and could be attributed to natural formation of crust under raindrop impact since there was minimal human interference, only during weeding and data collection. Most soils in sub-Saharan Africa suffer from poor physical and chemical properties, which, combined with intensive rainfall events, make them particularly sensitive to crust formation [24, 37].
Soil crust strength as influenced by time of measurement, tillage practices, and the cropping systems (n=3 seasons).
Soil crust strength (MPa)
Short rains 2012
Long rains 2013
Short rains 2013
3 WAP
7 WAP
10 WAP
15 WAP
4 WAP
6 WAP
10 WAP
16 WAP
4 WAP
8 WAP
12 WAP
17 WAP
Tillage
H
1.034a
1.001
1.272
1.269
1.187a
1.553
1.574
1.469
1.187a
1.350
1.468
0.747ab
HTR
0.905b
1.007
1.088
1.124
1.133a
1.494
1.680
1.526
1.133b
1.282
1.462
0.672c
DP
1.111a
1.055
1.208
1.193
1.188a
1.475
1.708
1.472
1.188a
1.341
1.415
0.728bc
DPH
1.094a
1.023
1.255
1.217
1.136a
1.460
1.671
1.451
1.136b
1.301
1.417
0.769ab
OX
1.136a
1.025
1.256
1.234
1.175a
1.561
1.673
1.478
1.175ab
1.355
1.453
0.807a
SSR
1.111a
1.067
1.230
1.296
1.209a
1.568
1.705
1.519
1.209a
1.357
1.480
0.815a
LSD 5%
0.111
0.106
0.162
0.088
0.047
0.105
0.108
0.069
0.047
0.067
0.053
0.072
Cropping system
Sole bean
1.026
1.032
1.221
1.241
1.177
1.529
1.617b
1.479
1.177
1.314
1.441
0.756
Sole maize
1.086
1.006
1.208
1.204
1.161
1.530
1.713a
1.482
1.161
1.338
1.462
0.749
Intercrop
1.085
1.051
1.225
1.222
1.176
1.496
1.675a
1.496
1.176
1.340
1.445
0.765
LSD 5%
0.072
0.064
0.052
0.036
0.051
0.046
0.047
0.036
0.051
0.041
0.029
0.048
Significance levels
Tillage
0.005
0.741
0.218
0.012
0.018
0.165
0.160
0.193
0.018
0.129
0.085
0.007
Cropping system
0.171
0.369
0.794
0.131
0.773
0.245
<0.001
0.571
0.773
0.374
0.272
0.798
Tillage × cropping system
0.466
0.493
0.406
0.043
0.672
0.151
0.789
0.576
0.672
0.266
0.278
0.935
CV%
3.2
6.9
5.2
4.2
1.6
5.0
1.7
2.8
1.6
1.5
0.9
10.2
Tillage: H: hand hoeing only, HTR: hand hoeing with tied ridges, DP: disc ploughing, DPH: disc ploughing + harrowing, OX: ox-ploughing, and SSR: subsoiling-ripping.
Different letters within the columns indicate significant difference at 5% probability level.
The average trend of crust strength observed during the SR 2012 season was in the order of SSR > OX > DPH > H > DP > HTR with values ranging from 1.03 to 1.18 MPa (Table 4). The crust formed on the ridges was weaker than other tillage practices as the season progressed. A probable cause of this was the inversion and mixing of top soil when constructing the tied ridges and this could have affected the structure of the top soil. However, at the base of the ridge basins, the crust strength was higher in all the seasons because of the excessive drying of the soil in the basin owing to direct insolation.
The crust strength trend observed during the LR 2013 season was in the decreasing order of SSR > OX > DP > HTR > H > DPH with average values ranging from 1.42 to 1.50 MPa (Table 4). Lower crust strength in H and DPH could be due to the loosening effect of the tillage used.
During the SR 2013 season, a trend of SSR > OX > H > DP > DPH > HTR was observed with values ranging from 1.14 to 1.22 MPa. A three-season average trend shows a decreasing trend of SSR > OX > H > DP > DPH > HTR with values ranging from 1.21 to 1.30 MPa. These results are in line with those reported by Khurshid et al. [51] where soil under conventional tillage (use of rigger in ridge tillage and use of a cultivator in deep tillage plots) had lower penetration resistance than minimum tillage (dibbling) treatments in the semiarid Faisalabad, Pakistan. Therefore, intensive tillage as observed in DP, DPH, and HTR causes a breakdown of soil surface sealing resulting in the weak crust strength observed (Table 4). The high crust strength observed in the SSR plots could be attributed to nonploughing of the soils between the planting rows [16]. This premise is supported by Miriti et al. [52] who observed higher crust in subsoiling-ripping (0.47 MPa) followed by tied ridging (0.40 MPa) and ox-ploughing (0.15 MPa), respectively, working in Makueni district, Eastern Kenya. The cropping systems did not significantly affect (P=0.379) the crust strength but an overall average trend of intercrop (1.263 MPa) > sole maize (1.258 MPa) > sole bean (1.251 MPa) was noted.
Penetration resistance decreased with increases in soil moisture content and vice versa [53]. Penetrometer readings greater than 2 MPa are generally reported to produce a significant root growth reduction [54] which was not observed in this study. According to Lampurlanés and Cantero-Martínez [11], penetration resistance measured with a penetrometer is usually two to eight times greater than that actually undergone by the root tip, owing to the different way in which roots and probes penetrate the soil. However, roots can grow at a speed greater than the penetrometer reading because they can elongate through the biopores and interaggregate spaces [11]. Thus, the crust strength obtained in this study in all treatments and seasons is not expected to limit root penetration and plant growth.
3.4. Bulk Density, Porosity and Saturated Hydraulic Conductivity (Ksat)
The bulk densities of the soils ranged from 1.20 Mg m−3 to 1.42 Mg m−3 across the seasons which are within the acceptable range for a clay loam (Table 1) [55]. The current study shows variation across the seasons (P<0.05) (Table 5). Though not significant (P=0.312), the average bulk density trend observed was DPH > SSR > H > OX > HTR > DP. The cropping systems did not influence the bulk densities in the four seasons (P=0.502).
Effect of tillage practices and cropping systems on soil bulk density, porosity, and saturated hydraulic conductivity (Ksat).
Bulk density (Mg/m3)
Porosity (%)
Ksat (cm/h)
Time/season
LR 2012b
1.43
46.19
0.65
SR 2012a
1.27
51.95
1.79
SR 2012b
1.34
49.32
1.01
LR 2013a
1.42
46.41
0.27
SR 2013a
1.55
41.39
0.36
SR 2013b
1.35
49.15
0.54
Tillage
Hand hoeing only (H)
1.40
47.26
0.69
Hand hoeing with tied ridges (HTR)
1.39
47.75
0.98
Disc ploughing (DP)
1.37
48.46
0.71
Disc ploughing + harrowing (DPH)
1.41
46.71
0.77
Ox-ploughing (OX)
1.39
47.42
0.82
Subsoiling-ripping (SSR)
1.41
46.94
0.66
Mean
1.40
47.42
0.77
Cropping system
Sole bean
1.38
47.77
0.83
Sole maize
0.39
47.45
0.74
Intercrop
1.40
47.09
0.76
Significance levels
Time
<0.001
<0.001
<0.001
Tillage
0.312
0.312
0.408
Cropping system
0.502
0.502
0.744
CV%
9.15
10.14
25.52
aBeginning of season; bat harvest.
In the SR 2012 season, the bulk density increased (1.34 Mg m−3) at the end of the season from 1.27 Mg m−3 at the beginning of that season, while, in the SR 2013, higher bulk density (1.55 Mg m−3) was noted at the beginning of SR 2013 and was lower at the end of that season (1.35 Mg m−3). According to Husnjak et al. [56], tillage at the beginning of the growing season temporarily decreases soil bulk density but subsequent trips in the field for agronomic practices, rainfall events, and other disturbances activities can recompact the soil. Lower bulk density at the end of the growing season could be attributed to the short term loosening effect of the tillage method used.
The high densities in DPH and SSR could be attributed to the second passes of soil manipulation (harrowing and ripping) to the initial tillage method of disc ploughing and subsoiling in the respective plots. Agbede [57] found high bulk densities in the ploughing plus harrowing plots and attributed that to tractor wheel traffic and implement passes and lower macroporosity. The plough layer gets compacted as the tillage implement keeps passing the same depth season after season, thus increasing the bulk density. Eventually, such structural degradation can lead to a formation of a surface seal that further reduces infiltration and hinders seed germination [58]. The increase in bulk density in the SSR plots especially at the beginning of a season could also be attributed to the compacted unploughed sections during the land preparation.
Nonsignificance of tillage effect on bulk density over time has also been observed in other studies by Lampurlanés and Cantero-Martínez [11], Anken et al. [59], Osunbitan et al. [60], and Jabro et al. [61] due to different tillage practices. In contrast, Khan et al. [62, 63] reported higher bulk density with minimum tillage and lower bulk density with deep tillage. McVay et al. [45] reported that bulk density was greater in no-till than conventional tillage in a long term study at Manhattan and Ashland Bottoms sites in Kansas, USA. The bulk density is dependent on soil texture and the densities of soil minerals as well as their packing arrangement [58]. Generally, bulk density is not affected much by tillage practices [60]. Gomez et al. [64] realized that it took five years before changes in some of the soil physical properties (structure and aggregate stability, which are indicators of bulk density) could be detected as a result of the soil management practices. Full effect of tillage is observed after four to five years and this could not be obtained in our short term study.
Total porosity values of the soils varied across the seasons (P<0.05) and ranged from 42 to 52% in all the seasons (Table 5). Though not significant, the tillage trend (P=0.312) showed that conventional tillage plots had numerically greater porosity due to the lower bulk density achieved by the tillage method used. Soils with <40% total pore space are liable to restrict root growth due to excessive strength [58]. However, in this study, soil strength measured is not expected to restrict root growth. According to Gardner et al. [10], conventional tillage improved soil porosity by increasing the macroporosity. Since porosity is calculated from the relation between bulk density and particle density of soil, it is very much influenced by the soil bulk density as the particle density is not greatly altered by agricultural manipulations [65]. For any given soil, the higher the bulk densities, the more compacted the soil and the less the pore space as also observed in this study. This also affects the soil water transmission properties [66, 67].
Cropping system did not show a significant influence on the porosity (P=0.502) but sole bean and maize showed higher porosity values than the intercrop (Table 5). This contrasts with results by Cheng and Coleman [68] and Fan et al. [69] who found an increase in porosity after intercropping and attributed that to increased root biomass and the stimulatory effects of the living roots on microbial activities that enhance soil organic matter decomposition. The distribution of roots in the profile thus determines the plants ability to absorb soil moisture.
The Ksat values varied across the season (P<0.05) and were very slow (<0.8 cm/h) in LR 2012, slow (0.8–2.0 cm/h) in SR 2012, and very slow (<0.8 cm/h) in LR 2013 and SR 2013 [55] (Table 5). Tillage did not significantly affect Ksat values (P=0.408) but an average trend of Ksat among tillage treatments was HTR > OX > DPH > DP > H > SSR with values ranging from 0.66 cm/h to 0.98 cm/h. There were no significant interactions observed among the cropping systems (P=0.744). The low Ksat values in SSR plots have been reported elsewhere by Miriti et al. [52] in Makueni district, Kenya, who attributed it to the restricted lateral movement of water due to the low porosity in the unploughed sections.
Non-significant results on saturated hydraulic conductivity (Ksat) over time have also been observed by Chang and Lindwall [70] after 20 years of tillage in a clay loam soil in Alberta. Furthermore, inversion tillage (ploughing) makes the aggregates unstable during wetting which could cause lower Ksat. Pikul Jr and Aase [71] demonstrated that continuous tillage for 11 years in a dryland site in Eastern Montana, USA, resulted in low Ksat due to a compacted 10–15 cm layer that impeded water movement. A soil profile description done at this study site showed a high bulk density of 1.54 Mg/m3 in the Ap horizon (0–10 cm depth) that impeded water infiltration as indicated by the low Ksat value of 0.37 cm/h obtained.
Green et al. [72] also reported that the effects of tillage on the soil hydraulic properties under different tillage treatments are not always consistent across locations, soils and experiment designs. The overall low Ksat values observed imply low infiltration rates and thus low rainwater intake by the soil [58]. The low Ksat values could also be influenced by the soil particle size which is reflected in the texture of the soil [57]. This soil has a clay loam texture (39% clay), which has smaller grains and thus lower hydraulic conductivity [67]. These low values observed in this study also indicate the presence of a hardpan and thus deep subsoiling is required to improve the soil water uptake [55, 71].
4. Conclusion
Soil moisture conservation is important during land preparation and crop growth due to climate change, which affects the amount of rainfall and the rainfall seasons. The soil moisture trends by tillage and cropping systems were inconsistent in each cropping season. However, on average, the OX, SSR, and the DPH conserved the highest moisture. Nonsignificant results by tillage and cropping systems were also observed on bulk density, porosity and Ksat values. The DP, HTR, and OX plots had numerically greater porosity (>45%) due to the lower bulk density achieved by the tillage method used. Based on the soil physical properties measured in this study, there was no significant advantage of a tillage practice over the other as the soil physical properties developed slowly after initiation of tillage practices. This suggests that long term tillage experiments (>4 seasons) under similar environmental and soil conditions are required to detect changes in soil physical properties as a result of the soil management practices. The long term studies will thus provide site-specific recommendations of the appropriate tillage practices for adoption in these semiarid areas.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
This study was supported by the Regional Universities Forum for Capacity Building in Agriculture (RUFORUM) and International Development Research Centre (IDRC) through Sokoine University of Agriculture (SUA), Tanzania. The authors thank Mrs. Josephine Mutuku for providing her farm for conducting this study and Stanley Kisamuli for the technical support in the field.
NjeruP. N. M.MugweJ.MainaI.Mucheru-MunaM.MugendiD.LekasiJ. K.KimaniS. K.MiritiJ.EsilabaA. O.MuriithiF.Integrating scientific and farmers’ perceptions towards evaluation of rainfed agricultural technologies for sorghum and cowpea productivity in Central Kenya201347123131BiamahE. K.Coping with drought: options for soil and water management in semi-arid Kenya200558Wageningen, The NetherlandsWageningen University and Research CentreWamariJ. O.SijaliV. I.KhengL. H.MiritiJ. M.EsilabaA. O.Use of Aquacrop model to predict maize yields under varying rainfall and temperature in a semi-arid environment in Kenya201262332JaetzoldR.SchmdtH.HornetzB.ShisanyaC. A.2006112ndMinistry of Agriculture/GIZNairobi, KenyaRockstromJ.BarronJ.FoxP.2003Wallingford, UKCABI, IWMILampurlanésJ.Cantero-MartínezC.Hydraulic conductivity, residue cover and soil surface roughness under different tillage systems in semiarid conditions2006851-2132610.1016/j.still.2004.11.0062-s2.0-28444437426CornelisW. M.ArayaT.WildermeerschJ.Mloza-BandaM. K.WaweruG.ObiaA.VerbistK.BoeverD.De BoeverM.KhlosiM.DelbecqueN.Building resilience against drought: the soil-water perspective2013Brussels, BelgiumUNESCO Chair of Eremology, Ghent University115RashidiM.KeshavarzpourF.Effect of different tillage methods on soil physical properties and crop yield of melon (Cucumis melo)2008324146AikinsS.HM.AfuakwaJ. J.OwusuO.Owusu-AkuokoO.Effect of four different tillage practices on maize performance under rainfed conditions2012312530GardnerC.LaryeaK. B.UngerP. W.1999Rome, ItalyFAO Land and Water Development Division, FAOAGL/MISC/24/99LampurlanésJ.Cantero-MartínezC.Soil bulk density and penetration resistance under different tillage and crop management systems and their relationship with barley root growth20039535265362-s2.0-0037871605SpeddingT. A.HamelC.MehuysG. R.MadramootooC. A.Soil microbial dynamics in maize-growing soil under different tillage and residue management systems20043634995122-s2.0-124234476510.1016/j.soilbio.2003.10.026Food and Agriculture Organization2000Rome, ItalyFood and Agriculture Organization of the United NationsFAO Land and Water Bulletin No. 8GacheneC. K. K.KimaruG.2003Nairobi, KenyaRegional Land Management Unit (RELMA), Swedish International Development Cooperation Agency (SIDA)RELMA Technical Handout Series 30MurunguF. S.Conservation agriculture for smallholder farmers in the Eastern Cape Province of South Africa: recent developments and future prospects201273852785284WOCAT2007Bern, SwitzerlandCTA, FAO, UNEP and CDE, University of Bernedited by Hanspeter Liniger and William CritchleyLinigerH. P.Mekdaschi StuderR.HauertC.GurtnerM.Sustainable Land Management in Practice—Guidelines and Best Practices for Sub-Saharan Africa. TerrAfrica, World Overview of Conservation Approaches and Technologies (WOCAT) and Food and Agriculture Organization of the United Nations (FAO)LalR.Enhancing crop yields in the developing countries through restoration of the soil organic carbon pool in agricultural lands200617219720910.1002/ldr.6962-s2.0-33646052865NyamadzawoG.ChikowoR.NyamugafataP.NyamangaraJ.GillerK. E.Soil organic carbon dynamics of improved fallow-maize rotation systems under conventional and no-tillage in Central Zimbabwe2008811859310.1007/s10705-007-9154-y2-s2.0-42149085124ManyatsiA. M.MhazoN.MkhatshwaM.MasarirambiM. T.The effect of different in-situ water conservation tillage methods on growth and development of Taro (Colocasia esculenta L.)2011311118KaumbuthoP.KienzleJ.Conservation Agriculture as practiced in Kenya: Two case studies. African Conservation Tillage, Centre de Cooperation Internationale de Recherché Agronomique pour le Developpement , Food and Agriculture Organisation of the United NationsKathuliP.ItabariP. K.NguluuS. N.GichangiE. M.Farmers perception on subsoiling/ripping technology for rainwater harvesting in mixed dryland farming areas in Eastern KenyaProceedings of the 12th KARI Biennial Scientific Conference2010Nairobi, Kenya12351240UngerP. W.StewartB. A.ParrJ. F.SinghR. P.Crop residue management and tillage methods for conserving soil and water in semi-arid regions1991202-42192402-s2.0-0026270876GitauA. N.GumbeL. O.BiamahE. K.Influence of soil water on stress-strain behaviour of a compacting soil in semi-arid Kenya20068921441542-s2.0-3374706385110.1016/j.still.2005.07.008MujdeciM.KaraB.IşiIdarA. A.The effects of different soil tillage methods on soil water dynamic2010521334533502-s2.0-79251494098GillerK. E.CorbeelsM.NyamangaraJ.TriompheB.AffholderF.ScopelE.TittonellP.A research agenda to explore the role of conservation agriculture in African smallholder farming systems2011124346847210.1016/j.fcr.2011.04.0102-s2.0-80052792954StrudleyM. W.GreenT. R.AscoughJ. C.IITillage effects on soil hydraulic properties in space and time: state of the science200899144810.1016/j.still.2008.01.0072-s2.0-40949125213LalR.Long-term tillage and maize monoculture effects on a tropical alfisol in western Nigeria. I. Crop yield and soil physical properties199742314516010.1016/S0167-1987(97)00006-82-s2.0-0030617195Abbaspour-GilandehY.SharabianiV. R.KhalilianA.Effects of tillage methods on soil fragmentation in loamy-clay soils20094213113610.3844/ajabssp.2009.131.1362-s2.0-69449091558GicheruP.GacheneC.MbuviJ.MareE.Effects of soil management practices and tillage systems on surface soil water conservation and crust formation on a sandy loam in semi-arid Kenya200475217318410.1016/S0167-1987(03)00161-22-s2.0-1242322432NgigiS. N.RockströmJ.SavenijeH. H. G.Assessment of rainwater retention in agricultural land and crop yield increase due to conservation tillage in Ewaso Ng'iro river basin, Kenya20063115-1691091810.1016/j.pce.2006.08.0062-s2.0-33748897322NgugiR. K.MureithiS. M.KamandeP. N.Climate forecast information: the status, needs and expectations among smallholder agro-pastoralists in Machakos District, Kenya2011311612OkaleboJ. R.GathuaK. W.WoomerP. L.20022ndNairobi, KenyaTSBF-CIAT and Sacred AfricaKuipersH.A relief meter for soil cultivation studies19575255262KluteA.DirksenC.KluteA.Hydraulic conductivity and diffusivity1982Madison, Wis, USAAmerican Society of Agronomy. ASA, SSSA687734SteinerK.RockstromJ.2003Harare, ZimbabweACTAfrican Conservation Tillage Network Information Series No. 5GuzhaA. C.Effects of tillage on soil microrelief, surface depression storage and soil water storage20047621051142-s2.0-124227733110.1016/j.still.2003.09.002MotsiK. E.ChumaE.MukamuriB. B.Rainwater harvesting for sustainable agriculture in communal lands of Zimbabwe20042915-18106910732-s2.0-514422203710.1016/j.pce.2004.08.008GicheruP. T.GacheneC. K. K.BiamahE. K.Effects of tillage and mulching on soil moisture conservation and crop production199812159GürsoyS.SessizA.KarademirE.KarademirÇ.KolayB.UrǧunM.MalhiS. S.Effects of ridge and conventional tillage systems on soil properties and cotton growth2011532272362-s2.0-84055212350HobbsP. R.SayreK.GuptaR.The role of conservation agriculture in sustainable agriculture2008363149154355510.1098/rstb.2007.21692-s2.0-40949150208KarumaA.GacheneC. K. K.GicheruP. T.Mwang'ombeA. W.MwangiH. W.ClavelD.VerhagenJ.Von KaufmannR.FrancisJ.EkayaW.Effects of legume cover crop and sub-soiling on soil properties and maize (Zea mays L) growth in semi arid area of machakos District, Kenya20111412372432-s2.0-84859489117FabrizziK. P.GarcíaF. O.CostaJ. L.PiconeL. I.Soil water dynamics, physical properties and corn and wheat responses to minimum and no-tillage systems in the southern Pampas of Argentina2005811576910.1016/j.still.2004.05.0012-s2.0-14744271588KabirM. A.RahimM. A.MajumderD. A. N.IqbalT. M. T.Effect of mulching and tillage on yield and keeping quality of Garlic (Allium Sativum L.)2013381115125McVayK. A.BuddeJ. A.FabrizziK.MikhaM. M.RiceC. W.SchlegelA. J.PetersonD. E.SweeneyD. W.ThompsonC.Management effects on soil physical properties in long-term tillage studies in Kansas20067024344382-s2.0-3364509369010.2136/sssaj2005.0249GillerK. E.WitterE.CorbeelsM.TittonellP.Conservation agriculture and smallholder farming in Africa: the heretics' view20091141233410.1016/j.fcr.2009.06.0172-s2.0-69449101358PassiouraJ. B.AngusJ. F.Improving productivity of crops in water-limited environments20101063775MupangwaW.TwomlowS.WalkerS.The influence of conservation tillage methods on soil water regimes in semi-arid southern Zimbabwe2008338-1376276710.1016/j.pce.2008.06.0492-s2.0-48949101160MorenoR. G.ÁlvarezM. C. D.AlonsoA. T.BarringtonS.RequejoA. S.Tillage and soil type effects on soil surface roughness at semiarid climatic conditions2008981354410.1016/j.still.2007.10.0062-s2.0-38149015437LipiecJ.KuśJ.NosalewiczA.TurskiM.Tillage system effects on stability and sorptivity of soil aggregates20062031891932-s2.0-33750206391KhurshidK.IqbalM.ArifM. S.NawazA.Effect of tillage and mulch on soil physical properties and growth of maize200685593596MiritiJ. M.KironchiG.EsilabaA. O.GacheneC. K. K.HengL. K.MwangiD. M.The effects of tillage systems on soil physical properties and water conservation in a sandy loam soil in Eastern Kenya20134714615410.5897/JSSEM2013.0395VazC. M. P.BassoiL. H.HopmansJ. W.Contribution of water content and bulk density to field soil penetration resistance as measured by a combined cone penetrometer-TDR probe2001601-235422-s2.0-003500064610.1016/S0167-1987(01)00173-8AtwellB. J.Response of roots to mechanical impedance199333127402-s2.0-38249004705LandonJ. R.1991Essex, UKLongman Scientific & Technical PublishersHusnjakS.FilipovićD.KošutićS.Influence of different tillage systems on soil physical properties and crop yield20024862492542-s2.0-0036017583AgbedeT. M.Effect of tillage on soil properties and yam yield on an Alfisol in southwestern Nigeria20068611810.1016/j.still.2005.01.0122-s2.0-31044441766BradyN. C.WeilR. R.200813thPearson EducationAnkenT.WeisskopfP.ZihlmannU.ForrerH.JansaJ.PerhacovaK.Long-term tillage system effects under moist cool conditions in Switzerland200478217118310.1016/j.still.2004.02.0052-s2.0-3042808642OsunbitanJ. A.OyedeleD. J.AdekaluK. O.Tillage effects on bulk density, hydraulic conductivity and strength of a loamy sand soil in southwestern Nigeria2005821576410.1016/j.still.2004.05.0072-s2.0-17544383447JabroJ. D.StevensW. B.EvansR. G.IversenW. M.Tillage effects on physical properties in two soils of the Northern Great Plains20092533773822-s2.0-67651121980KhanF. U. H.TahirA. R.YuleI. J.Impact of different tillage practices and temporal, factor on soil moisture content and soil bulk density19993163166KhanF. U. H.TahirA. R.YuleI. J.Intrinsic implication of different tillage practices on soil penetration resistance and crop growth200112326GomezE.FerrerasL.ToresaniS.AusilioA.BisaroV.Changes in some soil properties in a Vertic Argiudoll under short-term conservation tillage2001613-417918610.1016/S0167-1987(01)00193-32-s2.0-0034921219LalR.ShuklaM. K.2004New York, NY, USAMarcel DekkerAbu-HamdehN. H.Soil compaction and root distribution for okra as affected by tillage and vehicle parameters2003741253510.1016/S0167-1987(03)00122-32-s2.0-0242569296KarukuG. N.GacheneC. K. K.KaranjaN.CornelisW.VerplanckeH.KironchiG.Soil hydraulic properties of a nitisol in kabete, Kenya20121535956092-s2.0-84879017595ChengW.ColemanD. C.Effect of living roots on soil organic matter decomposition19902267817872-s2.0-0025639652FanA.ChenX.LiZ.Effects of intercropping system of trees with soyabean on soil physico-chemical properties in juvenile plantation200617226230ChangC.LindwallC. W.Effect of long-term minimum tillage practices on some physical properties of a Chernozemic clay loam19896934434492-s2.0-0024850061PikulJ. L.Jr.AaseJ. K.Water infiltration and storage affected by subsoiling and subsequent tillage20036738598662-s2.0-0037718454GreenT. R.AhujaL. R.BenjaminJ. G.Advances and challenges in predicting agricultural management effects on soil hydraulic properties20031161-232710.1016/S0016-7061(03)00091-02-s2.0-0037930214