Rice straw decomposition in paddy surface water potentially reduces soil methane (CH₄) emission

Experimental site and materials

This study was conducted in an experimental screen house at Can Tho University (Cantho City, Vietnam) from April to August 2019. The screen house consisted of a translucent white roof and rat-proof wire screens on the side. The inner humidity in the screen house was relatively similar to that outdoors.

We used plastic containers (38 cm in length × 58 cm in width × 30 cm in height) to carry out the microcosm experiment. Each container was filled with paddy soil up to 20 cm. The soil was collected from a farmer's field in Cantho city (10°18′N, 105°54′E). The soil was classified as Thionic Glycesol (Dong et al., 2012). The rice cultivar used for the experiment was a short-duration variety (IR50404, 85–90 days) provided by the Cuu Long Delta Rice Research Center. The IR50404 cultivar is popularly used in the VMD.

Experimental design

The examination of RS waterlogging and RS incorporation into the soil on CH₄ emissions were followed by a conventional rice cultivation experiment (first crop: Jan-6 to Mar-31). The first experiment was conducted to set essential conditions (rice straw, soil) for implementing the second experiment. In the first crop, pre-germinated seeds were sown at an equivalent rate of 250 kg ha^-1 on wet-levelled soil. The seeding rate was based on common application by the majority of farmers in VMD. Water irrigation was managed as alternative wetting and drying (AWD) technology which reflood 5 cm when the surface water level naturally declined to 10 cm below the soil surface. The technology is known as multiple aerations, developed by International Rice Research Institute (IRRI) to reduce water consumption for rice cultivation (Tran et al., 2018). In the second crop, we used RS and soil from each container in the first crop correspondingly to experiment with the effects of RS waterlogging and RS incorporation on CH₄ emissions.

There were two treatments, comprising (i) RS waterlogging on the soil surface and (ii) RS incorporation into the soil. Each treatment was set up in triplicate. Fresh RS (above-surface biomass) in the first crop was collected and cut into 5 cm in length. In the waterlogging treatment, RS was scattered on the soil surface and irrigated to 10 cm in-depth. Then, the RS was gently pressed into water. It was left for a 20-day stage without disturbing (off-sowing period). The timing was followed by a field demonstration recommended by Thao et al. (2019) that RS was well-fermented in the surface water within 20 days, which was suitable conditions for broadcasting rice seeds. In the RS incorporation treatment, RS was well incorporated into the soil by a shovel. The soil depth was mixed at approximately 20 cm in depth. Then, it was immediately irrigated to 2 cm in-depth for a 5-day period (off-sowing period). RS incorporation into the soil treated for 5 days was a typical treatment pattern for a triple-cropping rice production system in the VMD. The amount of RS applied for all treatments was the exact amount collected in the container of the first crop, correspondingly. On average, applied RS for the treatments of waterlogging and incorporation was 0.72 kg (dry weight) m^-2 and 0.59 kg (dry weight) m^-2, respectively. The term off-sowing used throughout the paper indicates a period that RS treated before sowing, which was 20 days for the RS waterlogging treatment and 5 days for the RS incorporation treatment.

A total of six microcosms were laid out closely in an array of the screen house with two columns and three rows. RS treatments were performed one day after harvesting the first crop. On the sowing day, we drained the field and leveled it by hand. The soil was not reincorporated. Pregerminated seeds of the IR50404 variety were also sown at a rate equivalent to 250 kg ha^-1. Water irrigation was managed as a continuously flooding management method during the rice-growing period. Tap water was directly irrigated for each rice container. We started irrigation on day 7 with 3–5 cm of water and maintained the water level during the rice-growing period. The water level was drained seven days before harvesting. Fertilizers were not applied for either experiment because fertilization could change the CH₄ emission patterns.

Measurements

The closed chamber method was used to measure CH₄ following the guidelines recommended by Minamikawa et al. (2015). The chamber (58 cm in length × 38 cm in wide and 90 cm in height) was equipped with a vent to allow equilibration of the pressure, a thermometer, a sampling port, and a fan to ensure well-mixed air inside the chamber while taking the gas sample. Gas sampling was flushed five times with chamber air before collecting. Gas samples were collected with a propylene syringe 50 mL at 3 and 23 mins after the chamber placement, and each gas sample was immediately injected to 15 mL in vacuumed vials. During the off-sowing period, gas sampling was taken on days 3, 6, and 13 for the rice straw waterlogging treatment, while RS incorporation treatment was sampled on day 3. The difference in the number of gas sampling times during off-sowing was due to a more prolonged RS treatment in the water logging period. After sowing, sampling frequently intensified every three days during the first 21 days when the high fluxes were characteristically observed. Then, the process was carried out once a week until the day of harvest. All gas samples were taken between 07:00, and 10:00 am. The CH₄ concentration was analyzed by gas chromatography (Shimadzu GC2014, Japan) equipped with a flame ionization detector, using 60/80 Carboxen® 1000 column at the temperature of 180 °C. Nitrogen (99.99%) as a carrier gas at a flow rate of 30 mL min⁻¹.

Water levels were checked by a 50-cm ruler (1-mm scale). Grain yield was detected by harvesting all rice in each pot at physiological maturity and removing all unfilled grains using tap water. Then it was sundried at ambient temperature. The presented grain yield was adjusted to 14% of moisture by a grain moisture tester (Riceter f2, Kett Electric Laboratory, Tokyo, Japan).

Data processing

The cumulative CH₄ emissions were calculated using a trapezoidal integration method with linear interpolation and numerical integration between sampling times. The calculation was done as follows: (i) calculate the daily gas flux by multiplying the daily mean hourly gas flux by 24, (ii) calculate the emission between every two consecutive measurements using the trapezoidal rule, and (iii) sum up the areas of all the trapezoids. Detailed guidance can be found at Minamikawa et al. (2015). Yield-scale CH₄ emissions was calculated by dividing total CH₄ emissions by grain yield. All measurements were carried out with three repetitions. Data processes were performed using Microsoft Excel 2019.

Statistical analysis

Data analysis was performed using IBM SPSS Statistics 22.0 (RRID:SCR_016479). The independent sample t-test comparison was used to compare the CH₄ emission in rice-growing and off-sowing periods, rice yield and yield-scaled CH₄ emissions between treatments. The statistical significance was done with a confident level of 95%.

Accumulative emissions

We assessed the effects of rice straw management via waterlogging and incorporation on CH₄ emissions using a microcosm experiment. The results showed that the CH₄ emission from waterlogging accounted for 36% of the incorporation treatment during the rice-growing period (Figure 1a) (Oda et al., 2020). However, high emissions were found in the off-sowing stage of the treatment by waterlogging (Figure 1b). The total CH₄ emissions from the waterlogging and incorporation treatments were 502 ± 111.4 kg CH₄ ha^-1 crop^-1 and 604 ± 41.9 kg CH₄ ha^-1 crop^-1, respectively. In general, the magnitude of seasonal CH₄ emissions observed in our study was lower than what was found in previous studies on triple-cropping in VMD, which ranged between 710 and 1,789 kg CH₄ ha^-1 crop^-1 (Oda & Nguyen, 2019; Vo et al., 2018). The CH₄ emission for the decomposing RS subject to waterlogging was 16.9% lower than that of the straw in the incorporation approach, even though the total timing of the off-sowing and rice-growing period was 30% longer. The yield recorded between treatments was no significant difference (P>0.05) (Figure 2a). For the yield-scaled CH₄ emissions, the waterlogging and incorporation treatment were 0.21 ± 0.02 kg CH₄ kg-grain^-1 and 0.30 ± 0.08 kg CH₄ kg-grain^-1, respectively. The difference between yield-scaled CH₄ emissions was insignificant (P>0.05) (Figure 2b).

Figure 1.

CH₄ emissions accumulation of rice strawy (RS) waterlogging and RS incorporation in the periods of rice-growing (a), and off-sowing (b).

Figure 2.

Grain yields (a) and yield-scaled CH₄ emissions (b) of RS waterlogging and RS incorporation.

Emission pattern

CH₄ emissions peaked one week after the prior crop's harvest. The peak of waterlogging was 3.82 times higher than the peak of the incorporation approach (Figure 3). After sowing, the CH₄ emission of the RS incorporation approach was always higher than that of waterlogging treatment. The peak was in line with a previous study (Oda & Nguyen, 2019). The emission patterns displayed a gradual reducing tendency to the end of the rice-growing period.

Figure 3. CH₄ emission rate of rice straw (RS) waterlogging and RS incorporation.

Underlying data

Figshare: Methane emission in waterlogging double cropping. https://doi.org/10.6084/m9.figshare.11987628.v1 (Oda et al., 2020).

This project contains the following underlying data:

Data are available under the terms of the Creative Commons Zero "No rights reserved" data waiver (CC0 1.0 Public domain dedication).