1. Introduction
Water is essential for agricultural production and the food security of the world population. In the coming decades, a growing number of regions will face increasing water scarcity [
1] while, due to the expectation that the global population will reach more than 9 billion people by 2050, demand for food is expected to surge by more than 50% [
2]. Considering that about 70% of global freshwater withdrawals are directly used in agriculture [
3], accurate management of agricultural water resources to increase crop water use efficiency (WUE) is one of the main targets in research on plant–soil–water relations. Different strategies are available to predict soil water availability for plants and maximize crop WUE, including wireless soil moisture sensors [
4]. However, novel irrigation technologies need to be adapted to local environmental conditions and available technical solutions, particularly in simplified growing systems that are generally found in developing countries [
5]. Proper management of irrigation water can be beneficial for farmers since it enables both an improvement and stabilization of the yield in areas of water shortages [
6]. Furthermore, it can lower the competition for water use among domestic, industrial, and agricultural sectors [
2]. In this context, reference evapotranspiration (ET
0) allows an effective definition of the precise water requirements for crops and irrigation scheduling [
7]. Various models/approaches are available for estimating ET
0, including the Class A Pan, FAO (Food and Agriculture Organization) Penman–Monteith (PM), and Hargreaves–Samani (HS) equations [
7]. Different studies have focused on the definition of appropriate water management through the estimation of evapotranspiration [
8,
9,
10,
11], suggesting the superiority of the HS as compared with the PM, by analyzing data over a study period of 9 years [
12]. Trajkovic [
13] observed ET
0 estimates by HS to be in close agreement with FAO PM forecasts in different experimental locations, with the average overestimation limited to about 1%. Traikovic’s study strongly supports the use of the HS when only temperature data are available [
13].
In the Central Dry Zone (CDZ) of Myanmar, water is scarce, vegetation cover is thin, and soils are mostly luvisol, sandy, degraded, and infertile [
14] with a low water holding capacity [
15]. Annual rainfall ranges 300 to 800 mm per year, and is characterized by an uneven distribution and high variability across years. Moreover, rain events are recently showing a shorter duration and increased intensity [
16]. In the coming decades, current trends of drought and water scarcity in the CDZ are expected to intensify in response to climate change [
17]. The combination of relatively low and erratic rainfall with land features that include sloped fields with mainly infertile sandy and sandy loam soils have led to low agricultural productivity in the region [
17]. Furthermore, the limited water resources are also poorly managed, especially regarding irrigated agriculture, despite the reported potential for creating small-, medium-, and large-scale irrigation systems [
17]. For these reasons, both irrigated and dryland cropping areas in the region will have to be developed or improved in the future. In such conditions, raising the awareness of efficient agricultural water use and developing small-scale irrigation schemes at the family level is therefore crucial. Hence, given the limited water availability, the application of water-saving methods to improve WUE is urgent.
Lettuce (
Lactuca sativa L.) is a major fresh vegetable extensively grown all over the world, particularly in temperate regions [
18,
19]. Despite lettuce being a C3 plant that requires adequate irrigation management to ensure satisfactory production, it is also widely cultivated in tropical areas due to its capacity to ensure adequate production and reasonable water use efficiency [
20].
World lettuce production was extended over 1 million ha and estimated to reach approximately 24 million metric tons in 2009 [
21], with about two-thirds of the total area devoted to lettuce production found in Asia [
22]. From a nutritional perspective, lettuce belongs to the so-called green leafy vegetables, whose relevance in the diet is associated with their contributions in terms of fibers, vitamins, and minerals (including calcium, iron, and phosphorous) [
23]. Under field conditions, Araújo et al. [
18] assessed the effect of different water levels on the productive behavior of lettuce. The highest WUE values (12 g L
−1) were obtained when 40% of ET
0 was restored, as compared with other treatments respectively restoring 60%, 80%, 100%, and 120% of ET
0. The experiment showed that WUE decreased linearly with the increase in the water level applied [
18]. This may be achieved by minimizing leaf water loss while preserving crop productivity [
19]. In the CDZ, the combination of drip irrigation techniques together with sustainable cropping practices is expected to increase in the near future in order to guarantee sustainable vegetable production and food security [
14]. Among cropping practices, soil coverage (e.g., with plastic mulching) has been shown to preserve soil moisture content by reducing both water evaporation and drainage, avoid soil crusting [
4], prevent soil erosion, and increase crop productivity [
24]. Moreover, organic mulching contributes to the soil organic matter content, improving the nitrogen balance and soil biological activity [
25]. Results obtained in Bangladesh by Asaduzzaman et al. (2010) indicate that soil organic mulching increases lettuce yield as compared with no-mulched lettuce [
26]. In a difficult context, such as CDZ of Myanmar, adequate irrigation management must be matched with all crop practices able to enhance water use efficiency and allow high yield. Therefore, the present study aimed to investigate the effect of different irrigation strategies and the use of soil organic mulching on the water use efficiency and yield of lettuce grown in the semi-arid areas of CDZ, Myanmar.
2. Materials and Methods
2.1. Location
The experiments were conducted in open field conditions at Soil and Water Research Station of Yezin Agriculture University located in the University Campus, Central dry Zone of Myanmar, 16 km away from the capital NayPyiTaw. The geographic coordinates are 19°83′ N and 96°27′ E, with an altitude of 122 m a.s.l. The local climate, according to Köppen’s classification, is Aw type, which is tropical rainy with a dry summer and the rainy season concentrated between June and October.
The soil presented a loamy sand texture with 82% sand, 9.3% silt, and 8.7% clay; a wilting point of 6.1% v:v; and field capacity of 13.0% v:v. The soil chemical characteristics in the 0–0.20 m layer were as follows: pH (H2O) 6.2; EC 0.13 dS m−1; 0.38% organic matter; 54 mg kg−1 of total N; 10.9 mg kg−1 of available P; and 25 mg kg−1 of exchangeable K.
2.2. Treatments and Experimental Design
Three independent experiments were carried out on a commercial variety of lettuce (Lactuca sativa cv. Green wave, Evergreen seeds, Sunnyvale, CA, USA) commonly sold in the local market.
Experiment 1: Four irrigation strategies were applied, three based on crop evapotranspiration (ETc), respectively restoring 25%, 50%, and 100% of crop ETc (details on the ETc calculation are included in the following sections) measured by using the Hargreaves–Samani equation (HS), and one guided by soil moisture sensors. In the sensor-guided treatment, the irrigation schedule was based on the real soil moisture content, restoring water up to the field capacity whenever the soil moisture level fell below 50% of the available water (AW). The experimental design was a completely randomized block design with 4 treatments and three replicates.
Experiment 2: A factorial combination was carried out, combining four irrigation strategies, based on crop evapotranspiration (ETc) combined with two soil mulching (M) treatments, namely soil without mulch (bare soil, BS), and soil mulched with dried rice straw residues (straw mulching, SM). The irrigation strategies provided restoration of 75%, 100%, and 125% of ETc estimated by using the HS equation and 100% of crop ETc estimated by using the Penman–Monteith (PM) equation. In this experiment, for the calculation of ETo, the Penman–Monteith method was included with the main purpose of validating the more straightforward method, such as the Hargreaves–Samani formula.
Experiment 3: Six strategies of irrigation (based on crop evapotranspiration, ETc), respectively restoring 25%, 50%, and 100% of crop ETc measured by using either the HS or PM equations, were factorially combined with two soil mulching (M) treatments, namely soil without mulch (bare soil, BS), and soil mulched with dried rice straw residues (straw mulching, SM). Again, PM was included to check HS. However, as crops respond to the water supply and not to the method to estimate ET0, the HS and PM methods were not considered as different factors but as different levels of the same factor (irrigation strategy). The restitution of different percentage of ET0, estimated either with HS or PM, represents different irrigation depths. The experimental design was a completely randomized block, with 12 treatments and 3 replicates.
For the three experiments, the experimental unit consisted of a 5.4-m2 plot, including 72 plants.
2.3. Plant Material and Crop Management
In all experiments, lettuce was sown manually in 105-cell plastic seedling trays, and the seedlings were transplanted 21 days after sowing (DAS), on 28 December 2018 for the first experiment, on 7 January 2019 for the second experiment, and on 14 February 2019 for the third experiment. Plants spacing was 0.25 m between rows and 0.3 m within rows, resulting in a plant density of 13.3 plant m−2, according to the habits of the local farmers. Harvest was carried out 31 days after transplanting (DAT) in all experiments.
Before the first experiment, the soil was amended with 1.5 kg m−2 of mature cattle manure, mainly to improve the soil structure and water holding capacity. Soil fertilization was managed as normal for the area, supplying 0.025 kg m−2 of NPK fertilizer 15-15-15 (corresponding to 37.5 kg ha−1 of N, P2O5, and K2O), which was applied in each experiment 3 days before transplanting. Both organic and mineral fertilizers were broadcasted manually. No additional fertilizer was applied across the growing season. During the experiments, no diseases or pests were detected; therefore, no pest control products were applied.
In experiments 2 and 3, soil mulching treatments consisted in the application of around 0.75 kg m−2 of dry rice straw, assuring a mulching height of about 0.15 m.
2.4. Irrigation Management
The irrigation management, except for the sensor-guided treatment, was based on crop evapotranspiration (ET
c), calculated by using the following equation (Equation (1)):
where ET
c (mm day
−1) is the calculated crop evapotranspiration, ET
0 (mm day
−1) is the reference evapotranspiration, and K
c is the FAO crop coefficient for lettuce [
13].
For the estimation of the reference evapotranspiration (ET
0), two different methods were used. The first one utilized the Hargreaves–Samani (HS) equation (Equation (2)):
where ET
0 (mm day
−1) is the reference evapotranspiration rate; R
a (W m
−2 day
−1) is the extraterrestrial solar radiation; and T
mean, T
max, and T
min are the mean, maximum, and minimum temperature (°C) of the day, respectively [
21].
The second method applied the Penman–Monteith (PM) equation (Equation (3)) [
27]:
where ET
0 (mm day
−1) is the reference evapotranspiration, R
n (MJ m
−2 day
−1) is the net radiation at the crop surface, G (MJ m
−2 day
−1) is the soil heat flux density, T (°C) is the mean daily air temperature at a 2 m height, u
2 (m s
−1) is the wind speed at a 2 m height, e
s (kPa) is the saturation vapor pressure, e
a (kPa) is the actual vapor pressure, e
s − e
a (kPa) is the saturation vapor pressure deficit, Δ (kPa °C
−1) is the slope vapor pressure curve, and γ (kPa °C
−1) is the psychrometric constant.
The meteorological data for the determination of the reference evapotranspiration were daily downloaded from the website of the Agro-Meteorological Department of Yezin Agriculture University (
http://www.yau.edu.mm/), located inside the University Campus, excluding extraterrestrial radiation R
a for the HS equation, which was calculated according to Duffie and Beckman [
28]. The ET
0 estimated by the PM equation was obtained using the FAO CropWat 8.0 software.
The amount of water to be used for each irrigation was calculated based on the plant water balance in conjunction with the soil property, root depth, and climate data also considering the occurred rainfall, if any. Daily ETc was estimated considering the FAO crop coefficient for the lettuce crop growth stages. In all experiments, lettuce cycles were divided into three growth stages, and the Kc used was 0.7, 1.0, and 0.95, respectively. The time of irrigation was determined when readily available soil water (50% available soil water) was depleted.
In the sensor-guided treatment of experiment 1, CropX sensors (CropX, Tel Aviv-Yafo, Israel) were used. These sensors measured the soil water content at a 20-cm and 46-cm depth by estimating the soil bulk permittivity (or dielectric constant), which determines the velocity of an electromagnetic wave or pulse through the soil. The sensors have a wireless connection to a system that collects and analyses the data. The insights produced by the system share information (through a smartphone application) on when and how much irrigation is actually needed. In this treatment, the irrigation schedule was based on the real soil moisture content, restoring water to the field capacity whenever the soil moisture level reached 50% of the water actually available.
In all experiments, 16-mm-diameter drip pipes were used. Drippers had a flow rate of approximately 1.3 L h
−1, and each plant was supplied with a single dripper. A flow rate test and calculation of distribution uniformity (DU) were carried out before transplanting. The DU was calculated following the indications from Baum et al. [
29].
The irrigation management (time and rate) was performed manually, through individual records for each treatment.
2.5. Measurements
At harvest (31 DAT), plants were cut at the base of the head, which was weighed to determine the fresh weight (g plant
−1). The marketable yield (kg m
−2) was assessed, excluding the external leaves, which appeared damaged or wilted. Plants’ dry weight was quantified after drying the samples at 70 °C for 72 h. Dry matter was calculated as the ratio between the leaf dry weight and leaf fresh weight and expressed as a percent value. Leaf number and leaf size (length and width) were also recorded. Water use fficiency (WUE) was determined as the ratio between the fresh weight and the volume of water used and expressed as g FW L
−1 H
2O, as generally done for lettuce crops [
30].
Stomatal conductance was measured using a handheld photosynthesis measurement system model CI-340 (Camas, WA, USA), equipped with 6.25-cm−2 cuvette. The infrared thermometer model FLUKE 61 (Fluke Corporation, Everett, WA, USA) was used to measure leaf temperature, and leaf greenness was estimated by using SPAD 502 (Minolta, Osaka, Japan). Measurements were made at 27 DAT on the upper surface of the canopy on 3 leaves for each plant from 10:00 a.m. to 14:00 p.m. h, taking approximately 1 h to complete each replication. All plants were measured on a single day. The cuvette conditions were as follows: PAR, 1258 ± 130 µm m−2 s−1, 1460 ± 150 µm m−2 s−1, 1533 ± 101 µm m−2 s−1; air temperature 39.8 ± 0.46 °C, 41.8 ± 0.47 °C, 39.4 ± 1.39 °C; relative humidity 27.4 ± 0.51%, 28.4 ± 0.97%, 26.4 ± 2.66% RH; CO2 concentration 337 ± 6.2 ppm, 332 ± 10.1 ppm, 271.8 ± 5.8 ppm (experiments 1, 2, and 3, respectively).
2.6. Statistical Analysis
The physiological measurements were taken on three plants per plot, while the harvest considered 12 plants collected from the central part of each plot. Data from experiment 1 were analyzed by using one-way ANOVA, while data from experiments 2 and 3 were analyzed by using two-way ANOVA (irrigation strategies x mulching). Means were separated using the Tukey HSD test [
31] at
p ≤ 0.05. Before the analysis, all data were checked for normality and homogeneity of the variance. Averages and standard errors (SE) were calculated. Statistical analysis was carried out using R statistical software (version 3.3.2, package “emmeans” and “car”).
4. Discussion
The application of different irrigation strategies significantly affected the growth (including fresh and dry weight, leaf morphology), yield (marketable yield), and some physiological parameters (stomatal conductance, leaf temperature, SPAD units) of lettuce grown in Central Dry Zone, Myanmar.
The main outcome of these three experiments is that it is possible to obtain a high yield of lettuce by restoring with irrigation only a fraction of the estimated crop evapotranspiration. Accordingly, the reduction of irrigation water allowed either the highest yield or a yield comparable to the restitution of 100% ETc to be obtained in all the experiments.
In the first experiment, the highest yield was associated with the HS
50 treatment (146 g plant
−1, corresponding to a 1.90 kg m
−2 marketable yield) (
Table 3 and
Figure 1a). No significant differences were observed by comparing it with the HS
100 and sensor treatments, which produced 137 and 141 g plant
−1, respectively (1.68 and 1.83 kg m
−2 marketable yield) (
Table 3 and
Figure 1). The use of the wireless sensors, although easy to use and showing some advantages, such as diminishing excessive water usage, as compared to HS
100, appears to still be unaffordable for farmers in the Central Dry Zone of Myanmar due to their cost. In the second experiment, when soil was covered with straw mulching, both the HS
100 and HS
75 treatment gave the best results, producing 2.59 and 2.36 kg m
−2, respectively (
Table 7). Even in the third experiment, the highest production was observed in mulched soil in all water treatments excluding PM
25 (with a mean marketable yield of 2.09 kg m
−2) (
Table 11).
The second experiment also pointed out that over-irrigation is not recommended since lettuce production did not benefit from the HS
125 treatment (
Table 7). Nevertheless, when soil was mulched with rice straw, the excess humidity caused a 22% reduction in yield as compared to the HS
100 treatment (
Figure 2a). This is a relevant aspect to consider when training growers on the benefits of rational use of irrigation water and to minimize the negative impact of water overuse in agriculture.
An important aspect that the second and the third experiments have underlined is that there is an effect on lettuce behavior, although not always significant, which is related to the method used for estimation of ETc and, consequently, with the time and amount of water restored by irrigation. Generally, the Hargraves–Samani method (HS) overestimated ET
0, as compared with Penman–Monteith (PM), being 14% and 8% higher in the second and third experiment, respectively (
Table 5 and
Table 7). In addition to a 10%–15% higher irrigation volume, this overestimation entailed more frequent water supplies during the crop cycle (18 waterings every 1.6 days in the HS treatments, and 15 waterings every 2 days in the PM treatments). This probably led to a more uniform hydration of the root zone, which combined with the mulching of the soil allowed adequate control of the soil temperature, better use of nutrients, negligible infestation of weeds, and finally a higher yield. Therefore, the Hargraves–Samani formula can be suggested as a method for estimating ET
0, particularly where the availability and access of climate data are limited, such as the Central Dry Zone of Myanmar. Under such circumstances, the HS equation, actually based on the maximum and minimum air temperature, could easily be used to estimate ET
0, contrarily to the Penman–Monteith equation, which, although being the recommended system as a standard for calculating the reference evapotranspiration, requires a large number of parameters that are not always easily available locally.
In all experiments, the lower the irrigation water level, the higher the water use efficiency (WUE) (
Figure 1b,
Figure 2b and
Figure 3b). In the first experiment, WUE was around 40 g L
−1 H
2O in the HS
25 treatment followed by the HS
50, sensor, and HS
100 treatments, where values of around 30, 22, and 14 g L
−1 H
2O were observed, respectively (
Figure 1b). The same trend was observed in the second and third experiments, where the use of rice straw as soil mulching allowed a further increase of WUE, as shown by the higher values compared with the treatments without mulching (
Figure 2b and
Figure 3b). As commonly experienced, the greater WUE was associated with the lowest irrigation treatments, but despite the limited water availability, the lettuce plants were able to extract the soil solution and to guarantee a satisfactory production as well. A similar WUE trend was observed by Dagdelen et al. [
6] in cotton crops grown with a drip irrigation system. An increase in WUE was observed when 25% of ETc was applied, reaching 1.46 g L
−1, while in irrigation with 100% ETc, the WUE was 0.81 g L
−1. Furthermore, Singh et al. [
32], experiencing a water deficit for cotton in a semi-arid region, found a significant relationship between WUE and the different irrigation depths studied. The treatment for which the irrigation was returned to 100% of the ETc obtained a value of 0.54 g L
−1, while the 50% ETc obtained a value of 0.64 g L
−1. Related to lettuce production, Barbosa et al. [
33], comparing lettuce growth with a drip irrigation system in a conventional field and a hydroponic system, found a value of WUE of 4 and 50 g L
−1, respectively. Moreover, Maraseni et al. [
34] detected a WUE of 19 g L
−1 in lettuce growth with a drip irrigation system in eastern Australia.
The irrigation strategy also significantly affected the stomatal conductance and leaf temperature (
Table 2,
Table 5 and
Table 9). Plants that experienced water stress (due to either a reduced water supply or the absence of straw mulching) showed decreased stomatal conductance and a higher leaf temperature. According to Turner [
35], stress conditions can influence the stomatal action as well as the pressure deficit of water vapor. Under the hereby described experimental conditions, stomatal conductance and leaf temperature status were shown to efficiently allow for the detection of a water deficiency.
In both experiments where the soil mulching was tested, it significantly affected the lettuce behavior, influencing the plants’ fresh and dry weight, marketable yield, and water use efficiency, Furthermore, it also affected the stomatal conductance in experiment 2 and both the dry matter percentage and SPAD units in experiment 3. On average, the use of straw mulching on the lettuce crop increased the fresh weight from 19% (third experiment) to 30% (second experiment) and the WUE from 21% (second experiment) to 22% (third experiment) as compared to lettuce cultivated on bare soil. It is therefore possible to state that the use of mulching for lettuce vegetable production in semi-arid environmental conditions is crucial in order to improve the soil microenvironment around the root zone and to promote the conservation of soil moisture, which can contribute to increasing both the quantitative and qualitative parameters of production.