1. Introduction
Soil quality is “the capacity of a specific kind of soil to function, within natural or managed ecosystem boundaries, to sustain plant and animal productivity, maintain or enhance water and air quality, and support human health and habitation” [
1]. Generally, arid soils have poor quality due to very low levels of soil organic matter [
2]. Organic matter is very central to the quality of any soil [
3]. The organic matter levels of arid soils, particularly in New Mexico where this study was conducted, are often less than 1% [
4]; to improve the soil organic matter, considerable efforts are needed to add organic materials to the soil. Traditional ways for improving soil organic matter, such as cover cropping, leaving crop residues after harvest, and applying manure, are often difficult to achieve in arid soils due to water availability and salinity [
5]. For example, cover cropping has been very challenging for farmers in the arid desert southwest of the United States due to the reduced amounts of available water for agriculture [
6]. This region has suffered severe drought over several years and using scarce water for raising cover crops is perceived by many growers as uneconomical.
In order to improve soil organic matter of arid soils, innovative methods that will not compete with water for crop production need to be developed. One such innovative method is to convert locally available waste biomass materials into biochar for soil application. Biochar is a predominantly recalcitrant organic carbon (C) material, created when biomass is heated to temperatures between 300 °C and 1000 °C under low oxygen concentrations (
i.e., pyrolysis) [
7]. Since the organic carbon produced in biochar is very stable, addition of biochar to the soil has the potential to both improve soil quality and sequester carbon, which is important for mitigation of excessive carbon dioxide in the atmosphere [
8]. Biochar application to the soil has been shown by different studies to have significant impacts on several soil quality parameters [
9,
10,
11,
12]. Positive impacts of biochar amendment on soils include:
- (i)
increasing soil capacity to sorb plant nutrients, consequently reducing leaching losses of nutrients [
13,
14];
- (ii)
decreasing soil bulk density, leading to less-compacted soil conditions favorable for root growth and water permeability [
15];
- (iii)
increasing the soil cation exchange capacity [
16];
- (iv)
increasing soil microbial activity and diversity [
17,
18];
- (v)
increasing plant available water retention [
15,
19]; and
- (vi)
increasing crop yields [
20,
21].
From a biomass systems engineering perspective, using available biomass resources to meet the community’s needs is critical to ecological sustainability. In arid agricultural communities, crop residues are often the primary available biomass feedstock and fresh water is often the primary need. Biomass can be used to help meet water needs in several ways, including providing the energy needed for water treatment. A way in which biomass for water treatment and biomass for soil amendments can be combined is to use slow pyrolysis to produce thermal energy for brackish groundwater desalination and biochars for application to agricultural soils.
New Mexico state usually ranks 3rd for pecan production in the United States with >17,000 pecan orchards covering more than 15,800 ha. Doña Ana County is New Mexico’s highest pecan producing county at approximately 19,500 Mg·year
−1 [
22]. Pecan production creates two residual biomass streams: pecan shells and pecan orchard prunings (leaves, branches,
etc.). Estimates of the amount of pecan shells available from the New Mexico/western Texas pecan industries range from 14,000 to 26,000 Mg·year
−1; some of these shells have been used in horticulture as mulch and alternative potting media [
23]. Estimates of orchard pruning residues available from the Mesilla Valley region of New Mexico range from 11,000–37,000 Mg·year
−1 on a dry basis. Air quality restrictions have caused pecan farmers to look for alternatives to conventional open-air pruning residue burning [
24].
After harvest and prior to textile production, cotton bolls must be ginned to remove the seeds (used to make cottonseed oil and cottonseed meal) and other non-lint materials. The non-seed, non-lint materials, such as stems, leaves and dirt, are collectively referred to as cotton gin trash. An average of 68 kg of gin trash is generated for each 218 kg bale of cotton. In 2013, approximately 12,000 ha of cotton were grown in New Mexico at an average yield of 0.89 bales/ha, resulting in over 725,000 Mg of cotton gin trash [
25].
Many municipalities collect tree branches, grass clippings, garden residues, and other yard wastes from residential and commercial properties for composting, mulching, and other uses. The City of Las Cruces, New Mexico (population approximately 100,000) receives 1800–2700 Mg·year−1 of wet green waste for processing into compost (Lisa LaRocque, City of Las Cruces Sustainability Officer, 23 September 2013). This represents a significant source of biomass that could be used for pyrolysis, especially for municipalities that are looking for alternative, higher-value uses for yard waste.
Pyrolysis of locally available waste biomass can help produce energy that can potentially be used for desalination of increasingly salty well waters used for irrigation and, at the same time, improve soil quality through the application of biochars. Exploration of the water desalination potential is the topic of another study. The objectives of the current study were to:
- (i)
Evaluate the yields and properties of biochars from four different local feedstocks (pecan shells, pecan orchard prunings, urban yard waste, and cotton gin trash).
- (ii)
Assess the impacts of biochar amendments on multiple soil quality indicators in two different soil textures (sandy loam and clay loam).
2. Experimental Section
2.1. Biomass Feedstocks
Four feedstocks were selected to represent underutilized biomass available locally. All feedstocks were air dried and stored in sealed buckets prior to pyrolysis.
Pecan (Carya illinoinensis (Wangenh.) K. Koch) orchard prunings (PP) were collected from the NMSU Leyendecker Plant Science Center in Las Cruces, NM, USA. Prunings consisted primarily of small branches and twigs, with some leaf material. Prunings were allowed to dry in the field, then were collected and chipped in a standard yard waste chipper. Pecan shells (PS) were collected from a local pecan processing facility and were used as received.
Cotton (Gossypium hirsutum L.) gin trash (CGT) was collected from Mesa Farmers Coop Cotton Gin in Vado, NM, USA. The gin trash contained mostly cotton leaf and stem pieces, with noticeable amounts of lint and seed residues, and dust particles.
Yard waste (YW) was collected from the NMSU green waste yard on 17 April 2014. The waste consisted primarily of freshly cut and chipped wood waste from tree pruning around campus, with a small amount of mixed leaves, shrubs, and grasses collected from maintenance of xeriscaped areas.
2.2. Biochar Preparation
Biochars were produced from the four biomass feedstocks using a custom-built, lab-scale slow pyrolysis system. The system consists of a GHA 12/450 single zone horizontal tube furnace (Carbolite, Hope Valley, UK) sized to fit a 5.5 inch (14 cm) O.D. 304 stainless steel reaction tube with a 1/4 inch (6 mm) wall thickness. The programmable furnace provided an 18 inch (46 cm) heated zone. Inside the reaction tube, two circular 303 stainless steel plates with large holes were held in place with screws; 304 stainless steel 40-mesh wire cloth was placed between the plates on the biomass side to contain the biomass particles while allowing for gas flow. End caps for the reaction tube, with high temperature glass-mica ceramic O-rings, were held in place by clamps. One end cap contained openings for a thermocouple (Super OMEGACLAD XL, Omega Engineering Inc., Stamford, CT, USA) and a nitrogen gas inlet. A handheld data logger (OM-EL-ENVIROPAD-TC, Omega Engineering Inc., Stamford, CT, USA) was connected to the thermocouple to record the temperature of the biomass every 5 min. Pyrolysis vapors exited through the other end cap into a 0.95 cm O.D. tube maintained at 300 °C by heat tape (XtremeFLEX BWH, BriskHeat Corp, Columbus, OH, USA) with a temperature controller (SDC Digital Benchtop, BriskHeat Corp., Columbus, OH, USA) to prevent early vapor condensation and clogs. Vapors were bubbled through approximately 700 mL of distilled water in a large, glass Erlenmeyer flask set in an ice bath. The entire pyrolysis system was operated within a fume hood.
Biomass (200–250 g) was loaded into the reaction tube between the perforated plates. The furnace was heated at a rate of 5 °C·min−1 to 450 °C and maintained at 450 °C for 60 min, after which the furnace and heat tape were turned off and the system allowed to cool overnight. An inert atmosphere was maintained by flowing nitrogen gas through the reactor at a rate of 1.0 L·min−1. Once the biochar had cooled to room temperature, the reactor was disassembled and the biochar removed, weighed, and stored in sealed containers. Bio-oil yields were estimated from the change in mass in the water condenser; this yield did not include the non-trivial amounts of tar that had condensed inside the pyrolyzer and exit tubing. Non-condensable gas (plus tar) yield was estimated by difference. The reactor was cleaned by placing the reaction tube in the tube furnace without the end caps and heating the tube to 600 °C for an hour to burn off tar residues.
2.3. Biomass and Biochar Characterization
Moisture content of the biomass feedstocks and biochars was measured by heating ground samples in an oven at 105 °C for 2 h. Ash content was measured by heating 0.5 g of sample in a muffle furnace to 575 °C and 750 °C for 6 h for biomass and biochar, respectively. Ash measurements were done in duplicate. Methods were based on ASTM E1755-01(2007) [
26] and ASTM D1762-84(2007) [
27]; 0.5 g samples were used instead of 1.0 g due to limited amounts of sample. Higher heating values (HHV) of the biomass feedstocks and biochars were determined in duplicate using a Model 6725 semi-micro bomb calorimeter (Parr Instrument Co., Moline, IL, USA). Mineral oil of known energy content was used as a spike for samples which did not easily ignite in order to ensure complete combustion. Elemental content of the biochars was measured in triplicate using a 2400 Series II CHNS Elemental Analyzer (Perkin Elmer, Waltham, MA, USA).
2.4. Biochar-Amended Soil Incubation
Two local arid soils used for agriculture, a sandy loam and a clay loam, were amended with the biochars at a rate of 45 Mg·ha
−1 and incubated for three weeks in a growth chamber. The sandy loam soil (a Thermic Typic Torrifluvents [
28]) was collected from the NMSU Fabian Garcia Agriculture Experiment Station in Las Cruces, NM, USA (32°27′998″ N; 106°77′163″ W). The clay loam soil (a Thermic Vertic Torrifluvents [
28]) was collected from the NMSU Leyendecker Plant Science Center in Las Cruces, NM, USA (32°20′238″ N, 106°74′277″ W). Las Cruces, NM has an arid climate with mean annual rainfall of about 160 mm. The average high temperature is 25 °C and the average low temperature is 8.5 °C. Soil properties of the soils are shown in
Table 1.
Biochars were ground to pass a 2 mm sieve prior to addition to the soil. Soil samples were thoroughly mixed then packed into pots. Soils were first slowly saturated with water then allowed to drain for 24 h, after which they were placed into a growth chamber for 3 weeks. About 100 cm3 of water was added twice a week to prevent the soil from drying out. The temperature of the growth chamber was set at a day temperature of 28 °C and a night temperature of 20 °C.
2.5. Soil Quality Assessments
Soil chemical analyses were conducted on the biochars and the biochar-amended soils after incubation using standard procedures. The pH, electrical conductivity, calcium, magnesium, sodium, and sodium adsorption ratio of the soils were measured using the filtered solution from a saturated paste preparation [
29]. Soil organic matter (SOM) was measured using the Walkley-Black method [
30]. Sodium bicarbonate-extractable phosphorus (Olsen P) [
31] and potassium were measured by inductively coupled plasma (ICP) spectroscopy [
32]. Nitrate-N concentration was measured by water extract using a cadmium reduction column [
33]. Copper, iron, manganese and zinc micronutrients were measured by DTPA extract and analyzed by ICP [
33]. These soil measurements are all important to crop growth and production of the study region.
2.6. Statistical Data Analysis
The experimental design for the biochar soil amendment trial was a randomized complete block design, with treatment combinations replicated four times. Experimental treatments consisted of biochars from the four feedstocks (pecan shells (PS), pecan prunings (PP), yard waste (YW) and cotton gin trash (CGT)) and a control treatment with no biochar addition, tested in two soil types (sandy loam and clay loam), for a total of 10 treatment combinations. Analysis of variance was performed on soil measurements and the means of the treatment values were separated using the Student Newman Keuls test after a significant F-ratio.
4. Conclusions
Biochar yields for 450 °C slow pyrolysis of pecan shells, pecan orchard prunings, yard waste and cotton gin trash ranged from 28% to 42% by weight, which was within the range expected for these conditions. The cotton gin trash had the highest ash content of all the feedstocks, which will likely impact its suitability for pH-, EC-, and ash-sensitive applications.
Amending clay loam and sandy loam agricultural soils with biochars from pecan shells, pecan orchard prunings, and yard waste had few significant impacts, positive or negative, on the soil quality indicators measured in this study after a short soil incubation. Biochar effects were different for the two different soil textures. Cotton gin trash biochar showed the greatest potential to increase soil organic matter and plant nutrients, however, the increases in salinity for both soils is a serious concern.
The biochar application rate in this trial was very high (45 Mg·ha−1) and the biochar materials were ground to pass through 2-mm sieve before application to the soil in order to accelerate the biochar’s interactions within the soil system. It is possible that the effects seen in this trial, such as biochar’s impact on soil salinity, may not be as severe if biochars are applied as larger fragments and at lower rates.
More research is needed on the effects of different biochar amendments on soil quality and plant available water retention in arid agricultural soils. Trials involving impacts of different sizes and rates of biochar are needed in arid regions, to help balance the utility of this potential soil organic matter source without delivering any negative side effect such as increased soil salinity.