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Research Article
Open Access Peer-reviewed

Bioethanol Production from Switchgrass Grown on Coal Fly Ash-amended Soil

Olushola M. Awoyemi , Ekundayo O. Adeleke
World Journal of Agricultural Research. 2017, 5(3), 147-155. DOI: 10.12691/wjar-5-3-4
Received March 29, 2017; Revised April 29, 2017; Accepted May 22, 2017

Abstract

Potentially toxic concentrations of certain mineral elements may be taken up in plant biomass produced on coal fly ash (CFA) contaminated soil. This raises concerns about efficiencies of downstream processes, such as hydrolysis and fermentation involved in biomass conversions to bioethanol. A greenhouse pot experiment was conducted to assess bioethanol yield from switchgrass biomass produced on CFA-amended soil (0, 7.5 and 15 %, w/w CFA/soil). Separate aliquots of the CFA-amended soils were either inoculated with isolate of arbuscular mycorrhizal fungi (AMF), Rhizophagus clarus, or fortified with reduced glutathione (GSH). Mineral elements in the CFA-amended soils and plant tissues were determined using ICP-OES. Shoot samples of harvested biomass were subjected to microwave-assisted acid pretreatment, enzymatic hydrolysis and fermentation. The reducing sugar (glucose) and bioethanol in the biomass hydrolysate were determined by spectrophotometry. Results showed that CFA had a concentration-dependent increase on the levels of the mineral elements in soils that were amended. Subsequent uptake of the mineral elements in switchgrass tissues was modulated by CFA-soil amendment, AMF inoculation, and GSH fortification. The glucose concentrations in biomasss hyzrolysate of switchgrass grown on 7.5 and 15% CFA-amended soils were significantly higher (p < 0.05) than the unamended (control) soil without significant adverse effect on the bioethanol yield. The bioethanol concentration (µg/mg DW) in the fermented hydrolysate of switchgrass grown on 15% CFA-amended soil (26.63) was higher than the control soil (24.46). Likewise, AMF and GSH enhanced bioethanol yield from hydrolysate of switchgrass biomass grown on the CFA-amended soil. Our results indicated that coupling CFA-amended soil with either AMF or GSH can enhance bioethanol yield.

1. Introduction

Coal Fly ash (CFA), a byproduct of coal combustion processes consists essentially of SiO2, Al2O3, and various micro and macro mineral elements 1, 2. CFA mineral element compositions along with other properties make it suitable as soil amendment to supplement deficient elements in marginal soils for cultivating bioenergy crops 3. However, the concentration of these mineral elements may exceed their normal levels in agricultural. Depending on the levels of these mineral elements in soils amended or contaminated with CFA, lignocellulosic biomass and downstream bioethanol production may be affected 4, 5, 6. Biomass can be converted to bioethanol by enzymatic hydrolysis and sugar fermentation processes 7, 8.

The importance of biofuel as a sustainable approach in mitigating the increasing price and negative environmental and human impacts of fossil fuels is increasingly recognized 9, 10, 11. Unlike fossil fuels, biofuel is a renewable energy source and more eco-friendly 12. The principal biofuel commercially used in many countries as a petrol substitute or in addition to petrol/gasoline is bioethanol 13, 14. Despite US been the current world’s largest producer of ethanol, with an output more than double that of the next-largest producer, Brazil, there is still an increasing demand for more bioethanol 15, 16.

Lignocellulosic feedstocks such as switchgrass (Panicum virgatum L.), have been proposed to offer energy and environmental, and economic advantages over current biofuel sources (corn and sugarcane). This is because switchgrass is a perennial crop which requires fewer agricultural inputs than compared to annual crops and can be grown on marginal lands 17. Studies have shown switchgrass to be a viable bioenergy crop because it produces high yields on marginal lands under low water and nutrient conditions 17, 18, 19, 20, 21.

It has been noted that the presence of mineral elements including heavy metals might or might not affect yield of ethanol from biomass 6, 18, 22, 23, 24, 25, 26. It remains unclear whether the elevated levels of mineral elements in CFA could affect fermentation processes and direct tests for fermentation of switchgrass grown on CFA-contaminated/amended soils are lacking. In this study, we present experimental results to address this issue.

The main objective of the present work was to assess at laboratory scale the bioethanol production path of switchgrass biomass grown on CFA-amended soils with emphasis on distribution of mineral elements. This study examined the effects of coal fly ash (CFA) used as soil amendment on the multitasking capability of lignocellulosic species switchgrass (Panicum virgatum). These include mineral elements uptake (including bioaccumulation, enrichment, and translocation), glucose and bioethanol yield from enzymatic hydrolysis (saccharification) and hydrolysate fermentation respectively. The effects of arbuscular mycorrhizal fungi (AMF, Rhizophagus clarus) and exogenous glutathione (GSH) in modulating the switchgrass capabilities were also investigated.

2. Materials and Methods

2.1. Materials

All chemicals were reagent grade. Sodium acetate trihydrate, and acetic acid (glacial) were obtained from Fisher Scientific (Pittsburgh, PA). Cycloheximide, tetracycline (Fluka), d-glucose standard, microcrystalline cellulose, glucose (HK) assay kit and ethanol assay kit were obtained from Sigma–Aldrich (St. Louis, MO). Accellerase 1500 enzyme was provided by Genencor (Rochester, NY). Ethanol TT yeast was provided by SPL International (Cheshire, United Kingdom). Yeast extract was obtained from Acros Organics (Geel, Belgium) and molecular biology grade peptone was obtained from U.S. Biological (Swampscott, MA). AMF (R. clarus, WV234) was obtained from INVAM, the International Culture Collection of Vesicular Arbuscular Mycorrhizal Fungi, Morgantown, WV and GSH was purchased from obtained from Acros Organic, New Jersey, USA. All solutions were prepared using sterilized deionized (DI) water.

2.2. Soil Preparation, Switchgrass Culture and Determination of Harvested Biomass

Armor silt loam (ASL) soil collected from obtained from Tennessee State University Agricultural Research, Education Center, Nashville TN was sieved through 2 mm sieve, and appropriate amounts of CFA were added to separate portions of the soil to provide CFA-soil admixtures (0, 7.5 and 15% w/w CFA/soil). Exactly 1.5 kg of each portion of CFA-soil admixture was introduced into plastic pots (5-inch deep). Seeds of ‘Alamo’ variety of switchgrass (P. virgatum L.) obtained from Star Seeds Inc., Osborne, Kansas, were started in germination trays containing potting mix (Farfard #2 mix) and 2-leaf stage seedlings (4 weeks old) of the switchgrass were transplanted in the pots containing different treatments of CFA-soil admixtures. Treatments in four replicates consisted of: a) CFA-soil admixtures only; b) CFA-soil admixtures fortified with 0.4 mg/kg GSH; and c) CFA-soil admixtures inoculated with 3% turface containing AMF, R. clarus. Transplanted switchgrass seedlings were allowed to grow for a period of 90 days and then harvested. Harvested plants were oven dried at 70 °C to constant weight.

2.3. Determination of the Concentrations of Selected Mineral Elements in Samples (CFA-soil Admixtures and Plant Tissues)

Air-dried soil samples (0.25 g) at days 0 and 90 were digested with 10 ml of concentrated HNO3 27. Oven dried and milled samples (0.25 g) of switchgrass root and shoot biomass were digested with concentrated H2O2/HNO3 (1:3) 28. Digestion was carried out in a microwave assisted accelerated reaction system (MARS5 v194A08; CEM corporation) at 170°C for 10 min. The concentrations of mineral elements (K, P, Mg, Ca, Na, S, Si, B, Al, Fe, Mn, and Co) in the digests were determined using ICP-OE Spectrometer (iCAP 7000 series, Thermo Scientific).

2.4. Microwave-assisted Acid Pretreatment (MAAP) of Biomass

Dried and milled samples of switchgrass shoot biomass (0.25 g) were pretreated with 10 mL dilute HNO3 acid (5.0%) using a microwave heating unit (MARS5 v194A08; CEM corporation) at 170 °C for 10 min. The hydrolysate of the pretreated switchgrass biomass was made up to 50 mL with DI H2O and pH was adjusted to 5.5 using KOH (1.0 M and 1.0 mM). The hydrolysate was stored in 50 mL tubes at 4°C for enzymatic hydrolysis.

2.5. Enzymatic Hydrolysis Reactions

Enzymatic hydrolysis reactions were carried out with 1.0 M sodium acetate buffer (pH 4.8), with addition of antibiotics to prevent microbial growth 29, 30. For the cellulose reaction, approximately 0.5 g cellulose was placed in a 25 mL Erlenmeyer flask followed by the addition of 23.5 mL sterilized DI H2O, 0.25 mL Accellerase 1500, 150 μL cycloheximide, 100 μL tetracycline (10 g/L in 70% ethanol) and 1.25 mL acetate buffer. For the biomass reaction, approximately 23.5 mL pretreated hydrolysate containing switchgrass biomass was placed in a 25-mL Erlenmeyer flask followed by the addition of 0.25 mL Accellerase 1500 enzyme, 150 μL cycloheximide, 100 μL tetracycline and 1.25 mL acetate buffer. Flasks were capped and placed in an incubated shaker at 50 °C, 250 rpm for 48 h. The mixtures were heated to 60 °C to terminate the enzymatic reaction at the end of the incubation period. Samples were then centrifuged at approximately 6200 ×g for 20 min and the supernatants were filtered using a 0.22 μm filter. The concentrations of glucose in the hydrolysate were determined by spectrophotometry with absorbance read at 340 nm.

2.6. Fermentation Reactions

A 10× YP medium was prepared by dissolving 10.0 g yeast extract and 20.0 g peptone in 100 mL deionized water followed by autoclaving at 121 °C for 30 min. For the glucose fermentation, a mixture of 1.0 mL acetate buffer (pH 4.8), 1.0 mL of 10× YP, 3.0 mL glucose solution, 0.02 g of ethanol TT yeast, and 5.0 mL autoclaved water was added to the 25 mL Erlenmeyer flask. For the fermentation of hydrolysate, a mixture of 1.0 mL pH 4.8 acetate buffer, 1.0 mL of 10× YP, 10.0 mL hydrolysate, 0.02 g of ethanol TT yeast, and 2.0 mL autoclaved water was added to the 25 mL Erlenmeyer flask. Each flask was capped with an airlock containing 1% H2SO4 to allow CO2 to escape while maintaining an anaerobic environment. The entire assembly was then placed in an incubated shaker set at 32 °C, 130 rpm for 48h 29. Concentrations of ethanol in the fermented solution were determined by spectrophotometry with absorbance read at 570 nm.

3. Results

3.1. Mineral Elements Status (µg/g) of the ASL Soil, CFA and CFA-soil Admixtures

The concentrations of mineral elements in the control soil, CFA-soil admixtures and CFA at the initial preparation of the admixtures are presented in Table 1. The concentrations of K, Mg, Ca, Na, S, B, Al, and Fe were higher in the CFA compared to the control soil while P, Si, Mn, and Co were lower in the CFA than the soil. The variations in the concentrations of the mineral elements between the CFA and ASL soil were significant at (p < 0.05) for Mg, Ca, Na, S, Si, B, Al, Mn, and Co. The concentrations of P, Mg, Ca, Na, S, B, and Co increased in the CFA-soil admixtures while K, Al, Fe, and Mn decreased with increased concentrations of CFA in the admixtures compared to the control.

3.2. Mineral Elements Status (µg/g) of the CFA-soil Admixtures after 90 Days Pot Study

The concentrations of mineral elements in the CFA-soil admixtures at the end of the greenhouse pot study are presented in Table 2. The concentrations of the mineral elements in the CFA-soil admixtures ranged from 9.48 µg/g for Co to 18869.11 µg/g for Fe. The concentrations of K, P, Mg, Ca, Na, S, B, Al, Fe, and Co were higher in the 7.5 and 15% CFA-soil admixtures compared to the control while Si and Mn were lower (Table 2). The concentrations of K, P, Mg, Si, and Al were higher in control soil inoculated with AMF compared to uninoculated. Likewise, K, P, and Mg in 7.5% CFA-soil admixture, and P and Ca in 15% CFA-soil admixture were higher with AMF inoculation compared to uninoculated admixtures (Table 2). The concentrations of P, S, and Si were higher in control soil fortified with GSH compared to unfortified soil. Likewise, P, Mg, Ca, Na, S, Si, and B in 7.5% CFA-soil admixture and P, Mg, Ca, and S in 15% CFA-soil admixture were higher with GSH fortification compared to unfortified admixtures (Table 2).

3.3. Mineral Elements Uptake (µg/g) by Switchgrass after 90 Days Pot Study

The concentrations of mineral elements in the roots and shoots of switchgrass after 90 days of greenhouse pot exposure to different treatments of CFA-soil admixtures are presented in Table 3 and Table 4 respectively. The concentrations of the mineral elements in the plant roots ranged from 0.75 µg/g for Co to 47685.64 µg/g for K. The concentrations of the mineral elements in the plant shoots ranged from 0.27 µg/g for Co to 52590.14 µg/g for K. The concentrations of Mg, Ca, Na, S, B, and Co were higher in the CFA exposed roots while P, Si, Al, and Fe were lower compared to the control (Table 3). Likewise, P, Mg, Ca, Na, S, B, Al, and Co were higher in the CFA-exposed shoots while Fe was lower compared to the control (Table 4). K and Mn were higher in plant roots and shoots exposed to 7.5% CFA-soil and lower at 15% CFA-soil compared to the control. Si in plant shoot was lower at 7.5% CFA and higher at 15% CFA compared to the control.

The plant tissues mineral elements uptake in the CFA-soil admixtures were also varied with AMF inoculation or fortification with GSH. Concentrations of P, Mg, Ca, and S were higher in plant roots exposed to AMF-inoculated CFA-soil admixtures compared to the uninoculated (Table 3) while P and Mg were also higher in plant shoots exposed to AMF (Table 4). Conversely, Si in both plant roots and shoots exposed to AMF-inoculated CFA-soil admixtures were lower than the uninoculated. S in plant roots and shoots, and P in plant shoots exposed to GSH fortified CFA-soil admixtures were higher compared to the admixtures without GSH. Conversely, Al, Fe, and Co in plant roots, and B in plant shoots exposed to GSH fortified CFA-soil admixtures were lower than the admixtures without GSH. All other mineral elements in the plant roots and shoots exposed to either AMF or GSH were either higher or lower at different levels of the CFA-soil admixtures.

The bioaccumulation (BAF), enrichment (EF), and translocation (TF) factors for each mineral element taken up by the plant tissues are presented in Table 5, Table 6 and Table 7 respectively. BAF was greater than 1 unit for K, P (except in 7.5% CFA-soil admixture inoculated with AMF and in 15% CFA-soil admixtures), Mg, Na, S, and Si in all CFA-soil admixtures with or without AMF or GSH (Table 5). Similarly, EF was greater than 1 unit for K, P, Mg, Ca (except in control soil), Na, S, Si, and B (Table 6). TF was greater than 1 unit for K (except in 0% CFA-soil containing GSH), P (except in control soil), Mg, Ca, S (except in 7.5% CFA-soil containing AMF and 15% CFA-soil), B, and Si (except in 15% CFA) (Table 7).

The concentrations of glucose from the enzymatic hydrolysis of MAA pretreated biomass, and bioethanol concentrations in the fermented hydrolysate are presented in Table 8. Glucose concentration ranged from 217.59 - 401.76 µg/mg DW. Glucose concentrations in biomass hydrolysate increased significantly (p < 0.05) in 7.5% and 15% CFA-soil admixtures compared to the control. The presence of AMF inoculum in the admixtures enhanced glucose production from switchgrass biomass grown on control soil and 15% CFA soil-admixture. Likewise, GSH enhanced glucose production from biomass grown on control soil (Table 8). Bioethanol concentration ranged from 23.27 - 35.98 µg/mg DW. Bioethanol concentration was highest in fermented hydrolysate obtained from switchgrass grown on 15% CFA-amended soil. AMF and GSH enhanced bioethanol concentration in CFA-amended soils and the unamended soil (Table 8). However, relative to the glucose concentration in the hydrolysate, bioethanol yield ranged from 14.54 – 29.50%. Bioethanol yield was lower in the CFA-amended soils compared to the control soil. Meanwhile, the bioethanol yield was enhanced in the fermented hydrolysate of switchgrass grown on CFA-amended soils that were inoculated with AMF or fortified with GSH.

4. Discussion

The presence of essential plant nutrient elements including K, Ca, Mg, S, P, Fe, Mn, B, and Co in CFA 31, 32, 33, 34 made CFA a suitable source of nutrient supply to soils where there is nutrient deficiency. The CFA used in this study had higher levels of K, Mg, Ca, Na, S, B, Al, and Fe, and lower levels of P, Si, Mn, and Co compared to the ASL soil. The differences in the levels of these mineral elements between the CFA and ASL soil were significant for Mg, Ca, Na, S, Si, B, Al, Mn, and Co. The application of CFA to ASL soil at rates 7.5 and 15% increased the levels P, Mg, Ca, Na, S, B, and Co, and decreased the levels of K, Al, Fe, and Mn in the resulting CFA-soil admixtures (Table 1). Roy and Joy 35 in their study on the dose-related effect of CFA on edaphic properties in laterite cropland soil reported that Ca and Na increased with CFA dose and time, but K decreased. Dash et al. 36 also reported decreased levels of P and K, and increased level of Fe with increased CFA amendment rate.

After 90 days of cultivating switchgrass on the CFA-soil admixtures, the levels of K, P, Mg, Ca, Na, S, B, Al, Fe, and Co were still higher in the soils amended with CFA compared to the unamended (Table 2). AMF inoculation increased the levels of K, P, Mg, Si, and Al in the control soil increased K, P, and Mg in the 7.5% CFA-soil admixture, and increased P and Ca in the 15% CFA-soil admixture compared to the uninoculated admixtures (Table 2). Likewise, GSH fortification increased the levels of P, S, and Si in the control soil, increased P, Mg, Ca, Na, S, Si, and B in the 7.5% CFA-soil admixture and increased P, Mg, Ca, and S in the 15% CFA-soil admixture compared to unfortified admixtures (Table 2). Significant positive and negative interrelationships between the mineral elements in the CFA-soil admixtures varied with the rates of CFA-amendment and with time.

CFA increased the uptake of Mg, Ca, Na, S, B, and Co in the plant roots and decreased P, Si, Al, and Fe (Table 3). Likewise, CFA increased the uptake of P, Mg, Ca, Na, S, B, Al, and Co in the plant shoots and decreased the Fe uptake. The uptake of K and Mn in the plant roots and shoots were increased and decreased at 7.5 and 15% CFA-soil admixtures respectively, while the uptake of Si in the plant shoot decreased and increased at 7.5 and 15% CFA rates respectively. Nass et al. 37 reported higher uptake of Al, B, Co, and Fe in grasses grown on unweathered CFA-contaminated soils. Swamy et al. 38 also reported increased uptake of K, P, Fe, Mn, and Co in Onion bulbs (Allium cepa L) grown on CFA-amended soils at rates beyond 5% CFA.

AMF have been reported to assist various plants in assimilating mineral elements especially phosphorus (P) 39, 40, 41, 42, 43. In this study, AMF enhanced the uptake of P, Mg, Ca, and S in the plant roots (Table 3), enhanced the uptake of P and Mg in the plant shoots (Table 4), and reduced the uptake of Si in both the plant roots and shoots. Similarly, GSH enhanced the uptake of S in plant roots and shoots, and P in plant shoots while it reduced the uptake of Al, Fe, and Co in plant roots, and B in plant shoots. The AMF or GSH either enhanced or decreased the uptake of all other mineral elements in the plant roots and shoots at different exposure levels to CFA in the admixtures.

BAF is the ratio of mineral element concentration in plant roots to soil 44, 45. EF is the ratio of mineral element concentration in plant shoot to soil 45, 46, 47. TF is the ratio of mineral element in plant shoots to roots 45, 48, 49, 50. BAF, EF, and TF have been used in environmental toxicology and risk assessment as essential indices to assess plant tolerance and to determine plants efficiency for potential mineral element uptake 45, 51. The switchgrass BAF was highest for K (16.05 – 49.34) and least for Fe and Al (< 0.06) (Table 5), the EF was highest for K (20.10 – 54.41) and least for Al (< 0.01) (Table 6), and the TF was highest for B (3.30 – 7.93) and least for Al (< 0.15) (Table 7). The BAF, EF, and TF were varied with CFA amendment rates, AMF inoculation and GSH fortification. The high-efficiency translocation of a potentially toxic trace element such as B may pose a threat to the growth of plants 52, 53 when exposed CFA 54, 55, 56.

Various studies have been conducted to determine reducing sugar (glucose) and ethanol yield from lignocellulosic biomass 30, 57, 58, 59. Typically, most of the lignocellulosic biomass from agriculture consists of about 40%-50% cellulose, 20%-30% hemicellulose, and 10%-25% lignin 60. Cellulose is an unbranched linear polymer of β-(1→4)-D-glucopyranose units. Hemicellulose is a branched linear polymer derived from anhydrides of various sugars with low degree of polymerization, low mechanical and chemical resistance, and always accompanied by cellulose and lignin. Lignin is a complex cross-linked, 3-dimensional non-carbohydrate polymer formed from phenolic units. Lignin provides strength and structure to the plant cell walls and it acts as a barrier for solutions or enzymes by linking to both hemicelluloses and cellulose 60. To optimize glucose yield from switchgrass, shoot biomass were subjected to microwave-assisted nitric acid pretreatment 57 followed by enzymatic hydrolysis with Accelerase 1500 (Endoglucanase Activity: 2200 – 2800 CMC U/g; Beta-Glucosidase Activity: 450 – 775 pNPG U/g).

Glucose concentration in hydrolysate varied between CFA amendments, AMF inoculation, and GSH fortification (Table 8). Glucose concentration in biomass hydrolysate of switchgrass grown on CFA-amended soils was significantly increased compared to the unamended soil. The differences in the glucose concentration may be due to the relative differences in their elemental uptake. The concentrations of certain mineral elements in biomass may enhance or inhibit the activities of the accelerase (or cellulase) enzyme 61, 62, 63, 64, 65. Both AMF and GSH enhanced glucose yield in unamended soils. Tutt et al. 57 achieved the highest cellulose-to-glucose conversion rate of 316.7 g/kg from wheat straw biomass pretreated with nitric acid. Xie et al. 6 also reported an increase in sugar yield from sugarcane grown in metal-contaminated soils.

Bioethanol concentration in fermented hydrolysate varied between CFA amendments, AMF inoculation, and GSH fortification (Table 8). The concentration of bioethanol was higher in the fermented hydrolysate of switchgrass grown in 15% CFA-amended soil compared to the unamended soil. However, the bioethanol yield relative to the glucose concentration was lower in the CFA-amended soils compared to the control, AMF enhanced the bioethanol yield from switchgrass biomass grown on the CFA-amended soils. Likewise, GSH enhanced bioethanol yield from switchgrass biomass grown on the CFA-amended and unamended soils. Studies conducted by Xie et al. 6 and Balsamo et al. 65 have also shown no significant adverse effect on bioethanol production from biomass grown on contaminated soils.

5. Conclusion

CFA contains mineral elements that could supplement soils that are lacking in specific nutrients for bioenergy crop production. However, the amount of CFA needed in amending the soil is crucial to the downstream production of glucose and bioethanol. The co-application of CFA with either AMF or GSH as soil amendment would serve to better enhance bioethanol production from biomass that may be impacted by the CFA.

Acknowledgements

This research was financially supported in part by Golden Key International Honours Society Research Grant (Awarded to Olushola M. Awoyemi). The grant body had no role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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[27]  United States Environmental Protection Agency, Microwave assisted acid digestion of sediments, sludges, soils, and oils, USEPA method 3051A, 2007. https://www.epa.gov/osw/hazard/testmethods/sw846/pdfs/3051a.pdf. Accessed 14th March, 2015.
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[29]  C. Shih, Determination of saccharides and ethanol from biomass conversion using Raman spectroscopy: effects of pretreatment and enzyme composition, Graduate Theses and Dissertation, 2010, Paper 11596.
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[30]  M. Brodeur-Campbell, J. Klinger, D. Shonnard, Feedstock mixture effects on sugar monomer recovery following dilute acid pretreatment and enzymatic hydrolysis, Bioresour. Technol. 116 (2012) (2012) 320-326.
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[31]  I.A.M. Yunusa, P. Loganathan, S.P. Nissanka, V. Manoharan, M.D. Burchett, C.G. Skilbeck, D. Eamus, Application of Coal Fly Ash in Agriculture: A Strategic Perspective, Crit. Rev. Environ. Sci. Technol. 42 (6) (2012) 559-600.
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[32]  C.R. Lal, S.K. Jha, R.C. Tripathi, R.E. Masto, V.A. Selvi, Remediation of fly ash landfills through plantation, in: Remediation Autumn, Wiley Periodicals, Inc. 2008, p. 71-90.
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[33]  M. Basu, M. Pande, P.B.S. Bhadoria, S.C. Mahapatra, Potential fly-ash utilisation in agriculture: A global review, Prog. Nat. Sci. 19 (2009) 1173-1186.
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[34]  C.D. Tsadilas, Agricultural use of fly ash: Expected benefits and consequences. WACAU-2014, Israel International Workshop on Agricultural Coal Ash Uses, 27 – 29th May 2014. https://coal-ash.co.il/sadna14/Tsadilas_FlyAshUse.pdf. Accessed 3rd March 2015.
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[35]  G. Roy, V.C. Joy, Dose-related effect of fly ash on edaphic properties in laterite cropland soil, Ecotoxicol. Environ. Saf. 74 (2011) 769-775.
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[36]  A. Dash, A. Pradhan, S. Das, S. Mohanty, Fly ash as a potential source of soil amendment in agriculture and a component of integrated plant nutrient supply system, J. Ind. Pollut. Contr. 31(2) (2015) 249-257.
In article      View Article
 
[37]  M.M. Nass, T.M. Lexmond, M.L. van Beusichem, M. Janssen‐Jurkovíc, Long‐term supply and uptake by plants of elements from coal fly ash, Commun. Soil Sci. Plant Anal. 24 (9-10) (2008) 899-913.
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[38]  T. Swamy, N. Dash, G. Nahak, B. Deo, R. Sahu, Effect of Coal Fly Ash on Growth, Biochemistry, Cytology and Heavy Metal Content of Allium cepa L, NY Sci. J. 3 (5) (2010) 10-16.
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[39]  J.J. Brejda, D.H. Yocom, L.E. Moser, S.S. Waller, Dependence of 3 Nebraska Sandhills Warm-Season Grasses on Vesicular-Arbuscular Mycorrhizae, J. Range Manage. 46 (1) (1993) 14-20.
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[42]  A. Balliu, G. Sallaku, B. Rewald, AMF Inoculation Enhances Growth and Improves the Nutrient Uptake Rates of Transplanted, Salt-Stressed Tomato Seedlings, Sustainability 7 (12) (2015) 15967-15981.
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[44]  N. Badr, M. Fawzy, K.M. Al-Qahtani, Phytoremediation: An Ecological Solution to Heavy-Metal-Polluted Soil and Evaluation of Plant Removal Ability, World Appl. Sci. J. 16 (9) (2012) 1292-1301.
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[45]  S.N. Majid, A.I. Khwakaram, G.A. Mam-Rasul, Z.H. Ahmed, Bioaccumulation, Enrichment and Translocation Factors of some Heavy Metals in Typha Angustifolia and Phragmites Australis Species Growing along Qalyasan Stream in Sulaimani City /IKR, J. Zankoy Sulaimani 16A (4) (2014) 93-109.
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[46]  R.A. Sutherland, C.A. Tolosa, F.M.G. Tack, M.G. Verloo, Characterization of selected element concentration and enrichment ratios in background and anthropogenically impacted roadside areas, Arch. Environ. Contam. Toxicol. 38 (2000) 428-438.
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[47]  K.B. Mmolawa, A.S. Likuku, G.K. Gaboutloeloe, Assessment of heavy metal pollution in soils along major roadside areas in Botswana, Afric. J. Environ. Sci. Technol. 5 (2011) 186-196.
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  • Table 1. Concentrations (mean ± SD) of mineral elements in the CFA-soil admixtures at the start of greenhouse pot study
  • Table 2. Average values of mineral elements in the CFA-soil admixtures after 90 days of greenhouse pot study
  • Table 3. Average values of mineral elements uptake by switchgrass roots after 90 days of greenhouse pot study
  • Table 4. Average values of mineral elements uptake by switchgrass shoots after 90 days of greenhouse pot study
  • Table 5. Bioaccumulation factor (BAF) of mineral elements by switchgrass roots after 90 days of greenhouse pot study
  • Table 6. Enrichment factor (EF) of mineral elements by switchgrass shoots after 90 days of greenhouse pot study
  • Table 7. Translocation factor (TF) of mineral elements by switchgrass shoots after 90 days of greenhouse pot study
[1]  D.C. Adriano, A.L. Page, A.A. Elseewi, A.C. Chang, I.A. Satraughan, Utilisation and disposal of fly ash and other coal residues in terrestrial ecosystems: a review, J. Environ. Qual. 9 (1980) 333-345.
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[26]  B.S. Dien, H.G. Jung, K.P. Vogel, M.D. Casler, J.F.S. Lamb, P.J. Weimer, L. Iten, R.B. Mitchell, G. Sarath, Chemical composition and response to dilute-acid pretreatment and enzymatic saccharification of alfalfa, reed canarygrass, and switchgrass, Biomass Bioenerg. 30 (2006) 880-891.
In article      View Article
 
[27]  United States Environmental Protection Agency, Microwave assisted acid digestion of sediments, sludges, soils, and oils, USEPA method 3051A, 2007. https://www.epa.gov/osw/hazard/testmethods/sw846/pdfs/3051a.pdf. Accessed 14th March, 2015.
In article      View Article
 
[28]  United States Environmental Protection Agency, Microwave Assisted Digestion of Siliceous and Organically Based Matrices, USEPA method 3052, 3rd ed., U.S. EPA, Office of Solid Waste and Emergency Response, Washington, D.C. 1996. https://www.epa.gov/epaoswer/hazwaste/test/pdfs/3052.pdf. Accessed 15 December 2014.
In article      View Article
 
[29]  C. Shih, Determination of saccharides and ethanol from biomass conversion using Raman spectroscopy: effects of pretreatment and enzyme composition, Graduate Theses and Dissertation, 2010, Paper 11596.
In article      View Article
 
[30]  M. Brodeur-Campbell, J. Klinger, D. Shonnard, Feedstock mixture effects on sugar monomer recovery following dilute acid pretreatment and enzymatic hydrolysis, Bioresour. Technol. 116 (2012) (2012) 320-326.
In article      View Article
 
[31]  I.A.M. Yunusa, P. Loganathan, S.P. Nissanka, V. Manoharan, M.D. Burchett, C.G. Skilbeck, D. Eamus, Application of Coal Fly Ash in Agriculture: A Strategic Perspective, Crit. Rev. Environ. Sci. Technol. 42 (6) (2012) 559-600.
In article      View Article
 
[32]  C.R. Lal, S.K. Jha, R.C. Tripathi, R.E. Masto, V.A. Selvi, Remediation of fly ash landfills through plantation, in: Remediation Autumn, Wiley Periodicals, Inc. 2008, p. 71-90.
In article      PubMed
 
[33]  M. Basu, M. Pande, P.B.S. Bhadoria, S.C. Mahapatra, Potential fly-ash utilisation in agriculture: A global review, Prog. Nat. Sci. 19 (2009) 1173-1186.
In article      View Article
 
[34]  C.D. Tsadilas, Agricultural use of fly ash: Expected benefits and consequences. WACAU-2014, Israel International Workshop on Agricultural Coal Ash Uses, 27 – 29th May 2014. https://coal-ash.co.il/sadna14/Tsadilas_FlyAshUse.pdf. Accessed 3rd March 2015.
In article      View Article
 
[35]  G. Roy, V.C. Joy, Dose-related effect of fly ash on edaphic properties in laterite cropland soil, Ecotoxicol. Environ. Saf. 74 (2011) 769-775.
In article      View Article  PubMed
 
[36]  A. Dash, A. Pradhan, S. Das, S. Mohanty, Fly ash as a potential source of soil amendment in agriculture and a component of integrated plant nutrient supply system, J. Ind. Pollut. Contr. 31(2) (2015) 249-257.
In article      View Article
 
[37]  M.M. Nass, T.M. Lexmond, M.L. van Beusichem, M. Janssen‐Jurkovíc, Long‐term supply and uptake by plants of elements from coal fly ash, Commun. Soil Sci. Plant Anal. 24 (9-10) (2008) 899-913.
In article      View Article
 
[38]  T. Swamy, N. Dash, G. Nahak, B. Deo, R. Sahu, Effect of Coal Fly Ash on Growth, Biochemistry, Cytology and Heavy Metal Content of Allium cepa L, NY Sci. J. 3 (5) (2010) 10-16.
In article      View Article
 
[39]  J.J. Brejda, D.H. Yocom, L.E. Moser, S.S. Waller, Dependence of 3 Nebraska Sandhills Warm-Season Grasses on Vesicular-Arbuscular Mycorrhizae, J. Range Manage. 46 (1) (1993) 14-20.
In article      View Article
 
[40]  R.B. Clark, Differences among mycorrhizal fungi for mineral uptake per root length of switchgrass grown in acidic soil, J. Plant Nutr. 25 (8) (2002) 1753-1772.
In article      View Article
 
[41]  D.J. Parrish, J.H. Fike, The Biology and Agronomy of Switchgrass for Biofuels, Crit. Rev. Plant Sci. 24 (5-6) (2005) 423-459.
In article      View Article
 
[42]  A. Balliu, G. Sallaku, B. Rewald, AMF Inoculation Enhances Growth and Improves the Nutrient Uptake Rates of Transplanted, Salt-Stressed Tomato Seedlings, Sustainability 7 (12) (2015) 15967-15981.
In article      View Article
 
[43]  A. Hashem, E.F. Abdul-Allah, A.A. Alqarawi, A.A. Al-Huqail, S. Wirth, D. Egamberdieva, The Interaction between Arbuscular Mycorrhizal Fungi and Endophytic Bacteria Enhances Plant Growth of Acacia gerrardii under Salt Stress, Front. Microbiol. 7 (2016) 1089, p. 15.
In article      View Article  PubMed
 
[44]  N. Badr, M. Fawzy, K.M. Al-Qahtani, Phytoremediation: An Ecological Solution to Heavy-Metal-Polluted Soil and Evaluation of Plant Removal Ability, World Appl. Sci. J. 16 (9) (2012) 1292-1301.
In article      View Article
 
[45]  S.N. Majid, A.I. Khwakaram, G.A. Mam-Rasul, Z.H. Ahmed, Bioaccumulation, Enrichment and Translocation Factors of some Heavy Metals in Typha Angustifolia and Phragmites Australis Species Growing along Qalyasan Stream in Sulaimani City /IKR, J. Zankoy Sulaimani 16A (4) (2014) 93-109.
In article      View Article
 
[46]  R.A. Sutherland, C.A. Tolosa, F.M.G. Tack, M.G. Verloo, Characterization of selected element concentration and enrichment ratios in background and anthropogenically impacted roadside areas, Arch. Environ. Contam. Toxicol. 38 (2000) 428-438.
In article      View Article  PubMed
 
[47]  K.B. Mmolawa, A.S. Likuku, G.K. Gaboutloeloe, Assessment of heavy metal pollution in soils along major roadside areas in Botswana, Afric. J. Environ. Sci. Technol. 5 (2011) 186-196.
In article      View Article
 
[48]  M. Srivastava, L.Q. Ma, J.A.G. Santos, Three new arsenic hyperaccumulating ferns, Sci. Total Environ. 364 (2006) 24-31.
In article      View Article  PubMed
 
[49]  J. Yoon, X. Cao, Q. Zhou, L.Q. Ma, Accumulation of Pb, Cu, and Zn in native plants growing on a contaminated Florida site. Sci. Total Environ. 368 (2006) 456-464.
In article      View Article  PubMed
 
[50]  A.R. Usman, H.M. Mohamed, Effect of microbial inoculation and EDTA on the uptake and translocation of heavy metal by corn and sunflower, Chemosphere 76 (2009) 893-899.
In article      View Article  PubMed
 
[51]  M. Ghosh, S.P. Singh, A comparative study of cadmium phytoextraction by accumulator and weed species, Environ. Pollut. 133 (2005) 365-371.
In article      View Article  PubMed
 
[52]  L.M. Cervilla, B. Blasco, J.J. Rios, L. Romero, J.M. Ruiz, Oxidative Stress and Antioxidants in Tomato (Solanum lycopersicum) Plants Subjected to Boron Toxicity, Ann. Bot. 100 (2007) 747-756.
In article      View Article  PubMed
 
[53]  M. Ayvaz, M.K. Avci, C. Yamaner, M. Koyuncu, A. Guven, K. Fagerstedt, Does excess boron affect the malondialdehyde levels of potato cultivars? Eurasia. J. Biosci. 7 (2013) 47-53.
In article      View Article
 
[54]  R.O. Nable, G.S. Bañuelos, J.G. Paull, Boron toxicity, Plant Soil 193 (1997) 181-198.
In article      View Article
 
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