1. Introduction
Technology of carbon sequestration (C seq.) and mitigation of carbon dioxide equivalency (CO
2-
equiv.) emissions need to be developed by using by-products of agricultural biomass through carbon-recycle systems in cropland. By-products from agricultural biomass consist of carbonaceous materials such as rice hulls, crop residues, trimming branches, animal waste, and bio-waste from fruit and vegetable markets. In Korea’s agricultural sector, the total potential biomass production is estimated at 58,010 Gg yr
−1 [
1], which can be converted into a less non-degradable form through biomass conversion technology.
Biochar, a porous and carbonaceous material obtained from biomass conversion with thermal treatment under limited oxygen, is one practical option for soil carbon sequestration. It contains a non-degradable structural carbon with double bonds and an aromatic ring that cannot be broken down by microbial organism activities [
2]. The produced biochar could be utilized for several purposes [
3] However, in its application, 30% is lost due to wind, while 25% is lost during spreading in cropland [
4]. On the other hand, one disadvantage of biochar application in the field is the presence of fine dust caused by wind during the spreading of biochar, which could affect farmer’s respiratory organs.
The application of 5% biochar produced at 700 °C had the most significant C seq. during rice and leaf beet cultivation [
5]. For cropland C seq., Shin et al. [
6] reported that C seq. is highest at 2.3 tons ha
−1 in corn fields incorporated with biochar and cow manure compost. The mitigation of CO
2-
equiv. emission is estimated at 7.3 to 8.4 T ha
−1 and profits ranged from
$57 to
$163 when incorporated with 2600 kg ha
−1 of biochar in corn fields.
Biochar’s effects in agro-ecology have been suggested to come from the plant’s sorption and retention abilities of available nutrients [
7]. Biochar from holm oak tree (
Quercus ilex) increased ammonium nitrogen (NH
4-N) adsorption in sandy acrisol associated with humid and tropical climates, but had no effect on nitrate nitrogen (NO
3-N) sorption in the column experiment [
8]. However, the largest amount of sorption of NH
4-N and binding strength, constant for biochar derived from rice husks, have been calculated as 0.5 mg L
−1 and 0.03 mg L
−1, respectively [
9]. Shin [
10] reported that rates of nitrogen (N) mineralization and nitrification are low in corn fields incorporated with biochar, compared to plots with different organic composts alone. These could be attributed to the sorption capacity of NH
4-N to biochar.
Phosphorous (P) and potassium (K) are essential elements for both crop growth and the maintenance of crop productivity [
11,
12]. The maximum sorption amount and binding strength constant of PO
4-P are estimated at 0.1 mg L
−1 and 0.06 mg L
−1, respectively, for biochar derived from oak tree [
13]. K deficiency in soil is mainly due to presence of 90% to 98% of insoluble K forms or due to the high soluble form of the available K [
14,
15,
16,
17]. Crop residues of rice and sugarcane contain applicable amounts of silicon (Si) [
18,
19]. Si plays an important role in plant cell wall strength and insect defense, as well as nutrient uptake improvement [
20,
21,
22]. Plant silicon is thought to be a recycling Si pool that can be accumulated in surface soil after litter fall and recovered from plant decomposition [
23].
A biochar pellet is one option to reduce fine dust and biochar loss by strong wind and intensive rainfall, thus decreasing handling and storage costs [
24]. For soil incorporation, poultry litter was mixed, pelletized, and slowly pyrolyzed to produce biochar pellets [
25]. Shin et al. [
26] indicated that biochar pellets mixed with organic compost could be a promising option for soil C seq. and control of major plant nutrients during crop cultivation. Biochar pellets mixed with various ratios of pig manure compost was induced, and its sorption capacity and kinetic models have already been investigated [
26]. For sorption test of NH
4-N with various loading rates, it has been shown that the maximum sorption of NH
4-N in the biochar pellet is 2.94 mg g
−1 where lettuce yield increased at approximately 13% relative to the control. However, there is little information on major plant releasing nutrient from the biochar pellet during leaching periods.
For the releasing model, Loney and Tabatabaie presented the leaching behavior of heavy metals from solidified and stabilized forms of biofilms using Michaelis–Menten kinetics [
27]. The used model predictions confirmed that Michaelis–Meten-type kinetics is probably the most dominant mechanism for the leaching of heavy metals from cement based waste forms. Furthermore, Michaelis–Menten kinetics has been used to explore the nitrogen deposition and climate change with laboratory manipulations [
28].
It is hypothesized that (1) blended biochar pellets could prolong the nutrient releasing period, and could be affected by their nutrient releasing characteristics. In addition, (2) tests should be conducted to see whether biochar pellets fit a modified Hyperbola model.
Therefore, this experiment was conducted to investigate the plant nutrient releasing characteristics, and to determine an optimum blended rate of biochar for the production of biochar pellets using a modified Hyperbola model.
2. Materials and Methods
2.1. Biochar Pellet Production
Biochar from rice hull was collected from a local farming cooperative society in Go-Chang, JenBok, Korea. The pig manure compost was purchased from the company (NOUSBO Co., Suwon, Korea) having a nationwide distribution network. The biochar was produced from a pyrolysis system and applied with “top to bottom method”. This pyrolysis system consisted of rice hull burning from the upper part, thus almost excluded oxygen from outside of the system. The loading volume of rice hull was 1.5 m
3, and the temperature of pyrolysis process ranged from 400 to 500 °C during 4 h. The produced biochar was ground in a grinder and roller to pass through a 2 mm sieve before analysis. Physiochemical properties of biochar and pig manure compost used are presented in
Table 1. The biochar was generally alkaline in nature (pH 9.8) and low in total nitrogen (TN) (2.0 g kg
−1). The content of total hydrogen (T-H) and H: C ratios were 17.6 g kg
−1 and 0.031, respectively.
Prior to pelletizing, biochar was sieved using a series of sieves (0.5 mm to 5 mm) to measure the particle distribution. It was then blended with pig manure compost as a binder to produce a biochar pellet. The combination ratios of biochar and pig manure compost were 9:1, 8:2, 6:4, and 2:8 (w/w), and the size of biochar pellet was Ø 0.51 cm × 0.78 cm. The blended materials (total weight = 2.5 kg) were thoroughly mixed using an agitator (SungChang Co., KyungGi, Korea) for 5 min. Then, while continuously mixing, the combination was sprayed with 1000 mL of deionized water for 10 min. The biochar pellet produced through the pellet machine (7.5 KW, 10 HP, KumKang Engineering Pellet Mill Co., DaeGu, Korea) with the combination of biochar and pig manure compost is described in the
Figure 1.
2.2. Batch Experiment for Nutrient Leaching Test
The treatments consisted of pig manure compost (PMC) as a control, pig manure compost pellet (PMCP), and various ratios of biochar pellets (BCP) blended with 2:8, 4:6, 8:2, and 9:1 of biochar/pig manure compost (w/w) in order to test the feasibility of developing a slow-release fertilizer.
For the nutrient releasing experiment, the size of the glass column was Ø 24 mm × 40 cm with each column filled with 5 g of PMC, PMCP and different blended BCP, respectively. The column was poured into 50 mL of deionized water, completely drained, and then immediately refilled after certain retention time. The water samples were collected at 50 mL of drained water through the column until 84 days of leaching periods.
2.3. Chemical Analysis
The biochar and pig manure compost was taken to the National Institute of Agricultural Sciences (NIAS) to analyze the chemical properties. The pH and EC (electrical conductivity) of the biochar and pig manure compost was measured using a pH/EC meter (Orion 4 star, Thermo scientific, Singapore) at a 1:20 solid/water ratio (biochar:de-ionized H2O) after shaking for 30 min in a water bath (P/NTS-3000, Eyela, Kyoto, Japan) at 140 rpm. The analytical chemical properties, such as total carbon (TC) and total organic carbon (TOC), were analyzed by a TOC analyzer (Elementar Vario EL II, Hanau, Germany) for biochar and pig manure compost. Total hydrogen was analyzed by Elemental Analyzer (Vario MACRO cube, Elementar, Langenselbold, Germany). Total P, K, and Si in the biochar and pig manure compost were measured by inductively coupled plasma atomic emission spectrometry (ICP-AES, IntegraXL, GBC LTd., Braeside, Australia) after samples were digested with nitric and hydrochloric acids.
The collected water samples were filtered using Whatman #2 filter paper, and then analyzed for NH
4-N, PO
4-P, K, and SiO
2 by using a UV spectrophotometer (C-Mac Co., Jenmin Dong, Dae-Jen, Korea) [
26] through whole leaching periods.
2.4. Releasing Models
Michaelis–Menten, a general used model of substrate based kinetics, describes a saturating function of substrate concentration with parameters V
max, the maximum reaction velocity, and kM, the half saturation constant, which corresponds to the substrate concentration [S] when V
max/2. This model was used to predict the accumulated amounts of released material as a function of leaching periods. Therefore, a modified Hyperbola model from Michaelis–Menten equation used is shown below;
Y: accumulated concentration (mg L
−1); Amax: maximum accumulated concentration (mg L
−1); t1/2
(Amax): required time to reach 1/2 Amax; t: leaching periods (days).
2.5. Statistical Analysis
The statistical analyses for total water-soluble amounts of NH4-N, PO4-P, K, and SiO2 were performed using a one-way ANOVA with 6 levels, using SAS version 9.0 (SAS Institute, Carry, NC, USA). Duncan multiple range test was used for accessing significant differences (p < 0.0001) among treatment means during leaching periods. Means of variables were compared with parameters among treatments by using the above equation according to p-values < 0.0001 after analysis of variances (ANOVA). The validity of a modified Hyperbola model for each parameter was assured for normal distribution by Shapiro–Wilk test (p < 0.05). The releasing model for each nutrient was established by data analysis using SigmaPlot 12 (Systat Software, Inc., San Jose, CA, USA). The model used was calculated using the equation based on correlation coefficient values (R2).
3. Results
It was observed that the more biochar contained within the biochar pellet, the greater sorption of NH
4-N. For accumulated NH
4-N releasing amount, the order was PMC > PMCP ≥ BCP (2:8) > BCP (4:6) > BCP (8:2) > BCP (9:1) ratios, and the highest accumulated amount in the PMC was 397 mg L
−1 (
Figure 2).
The estimation parameters for an accumulated NH
4-N releasing amount from different types of biochar pellets are presented in
Table 2. The model was significantly correlated with the
R2 values between the observed and estimated values. The maximum accumulated NH
4-N releasing amount was observed in PMC even if same amount of pig manure compost between PMC and PMCP was used in the leaching column. This might be due to the increase mass of pig manure compost. However, the required time to reach half of the maximum accumulated amount in PMC was taken only 16 at days, but was 41 days in PMCP. Therefore, pelletization could reduce the releasing rates of NH
4-N even if the same loading amount of material was used. The greater accumulated amount and longer leaching periods were observed in the BCP (2:8 and 4:6). The estimated releasing model was significantly fitted with all treatments (
Table 2).
The accumulated amount of PO
4-P was not significantly different with biochar pellets which contained 0 to 40% of biochar during leaching periods. It was shown that the highest accumulated amount of PO
4-P in the PMC was 1953 mg L
−1 and the lowest in the BCP (9:1 ratio) was 223 mg L
−1 (
Figure 3). This could be attributed to the high concentration of PO
4-P in the PMC. However, this could also result in the slower release of PO
4-P in the PMCP than that found in the PMC because of the change in the physical characteristics in pelletization of pig manure compost.
The curves fit was derived from the estimation model calculated by a modified equation based on correlation coefficient values (
R2). The estimation models for accumulated PO
4-P releasing amount from different ratios of biochar pellets showed that estimation values from a modified equation were significantly correlated with the observed values for accumulated PO
4-P releasing amount in all treatments (
Table 3). The required time of 1/2 maximum accumulated PO
4-P amount was taken 21 days in the PMCP and BCP (4:6). Similar patterns for the estimation model were observed in the accumulated NH
4-N releasing models (
Table 2 and
Table 3). The estimated releasing model has significantly fit with all the treatments (
Table 3).
The highest accumulated amount of K in the PMCP was 1917 mg L
−1 and the lowest in the BCP (9:1) was 1078 mg L
−1. It appeared that accumulated amounts of K abruptly increased at the early leaching stage, and gradually increased at later stages (
Figure 4).
The estimation model for K accumulated amount from different types of biochar pellets is presented in
Table 4. The estimation values calculated from the modified equation were significantly correlated with the observed values for K releasing, regardless of combinations of biochar pellets. Most of K was released within 2 days of leaching periods. The estimated releasing model for the modified equation significantly fits with all the treatments (
Table 4).
It has appeared that the highest accumulated amount of SiO
2 in the PMCP was 1259 mg L
−1, but the lowest in the PMC was 634 mg L
−1 at 20 days of leaching periods (
Figure 5). Following this, it then decreased after that period even if it did not contain biochar from rice hull. The estimation model for accumulated SiO
2 releasing amount from different BCP is presented in
Table 5. The estimation values calculated from a modified equation were significantly correlated with the observed values for accumulated SiO
2 releasing amount regardless of combination rates of biochar pellets. The estimated releasing model equation was had a highly significant fit with whole treatments (
Table 5).
It was observed that the estimation model for accumulated NH4-N, PO4-P, and SiO2 releasing amounts in the biochar pellet was a significantly fit with this modified equation regardless of combination ratios of biochar and pig manure compost. In aspect of 1/2 releasing amount, the BCP (8:2) could be better for crop uptake and reduced application amount of Si fertilizer.
The total water soluble amounts of NH
4-N, PO
4-P in PMC were significantly higher than those of PMCP, but soluble amounts of K and SiO
2 in PMC were significantly lower than those of PMCP during leaching period (
Table 6). However, it is observed that accumulated amounts of water soluble NH
4-N, PO
4-P, K and SiO
2 were usually greater in the BCP (2:8 and 4:6) compared to the PMC (
Table 6).
5. Conclusions
This experiment was conducted to investigate the nutrient releasing characteristics, and to determine an optimum ratio for processing biochar pellets based on a modified Hyperbola model in terms of potential mitigation of greenhouse gas emissions and carbon sequestration. For accumulation amount of NH4-N releasing, the order was PMC > PMCP > BCP (2:8) > BCP (4:6) > BCP (8:2) > BCP (9:1) ratios, and the highest accumulated amount in the PMC treatment was 397 mg L−1. For the accumulation amount of NH4-N in the BCP during leaching periods, it was shown that the greater the amount of biochar contained the greater accumulated amount except for BCP (2:8). The highest accumulated amounts of PO4-P and K in the PMC were 1953 and 1727 mg L−1, and the lowest in BCP (9:1) were 223 and 1078 mg L−1, respectively. The highest accumulated amount of SiO2 in the BCP (8:2) was 1307 mg L−1, but the lowest in the PMC was 704 mg L−1 at 30 days of leaching periods.
For releasing model for pellets, the releasing patterns of major plant nutrients could be proposed as Shin’s principal releasing law that NH4-N and PO4-P releasing accumulated amounts in the PMCP are decreased, but SiO2 in the PMCP significantly increased compared to the PMC as control. The optimum blended rate was estimated to be BCP (2:8) for major releasing plant nutrients based on a modified Hyperbola model.
Therefore, the biochar pellet might be used for further research on slow-release fertilizer for sustainable agriculture.