Assessment of Physicochemical and Nutritional Characteristics of Waste Mushroom Substrate Biochar under Various Pyrolysis Temperatures and Times

Sarfraz, Rubab; Li, Siwei; Yang, Wenhao; Zhou, Biqing; Xing, Shihe

doi:10.3390/su11010277

Cited by 27 publications

(27 citation statements)

References 44 publications

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“…In crop residue biochars (wheat straw, rice straw, maize straw, and rice husk), the N content ranged from 8.47 g kg −1 to 16.1 g kg −1 , the P content ranged from 1.67 g kg −1 to 4.43 g kg −1 , and the K content ranged from 12.9 g kg −1 to 32.0 g kg −1 (Bian et al 2016). Similar ranges had been reported in spent mushroom substrate biochars (Sarfraz et al 2019;Zhao et al 2019). A meta-analysis by Ippolito et al (2015) reported an average total concentration of 0.9 g kg −1 to 32.8 g kg −1 for N, an average total concentration of 0.32 g kg −1 to 60.8 g kg −1 for P, and an average total concentration of 0.7 g kg −1 to 116 g kg −1 for K, for a wide range of biochar materials.…”

Section: Physicochemical Properties Of the Biochar Samplessupporting

confidence: 79%

“…The decrease in total biochar yield as the pyrolysis temperature and holding time were increased could be attributed to the breakdown of the basic primary structure of the biochar during pyrolysis. A decrease in the total biochar yield as the temperature increased had also been reported in oak, pine, sugarcane, and peanut shell biochar (Zhang et al 2015); spent mushroom substrates biochar (Sarfraz et al 2019;Zhao et al 2019); pig manure (Gasco et al 2018); and straw and lignosulfonate (Zhang et al 2015). Previous reports had also shown that feedstock was partially combusted at lower pyrolysis temperatures, which resulted in a higher yield; while a higher temperature resulted in the complete combustion of the biomass (Angin 2013;Ghanim et al 2016) as well as increased gasification (Colantoni et al 2016;, which resulted in a decrease in the total yield.…”

Section: Physicochemical Properties Of the Biochar Samplesmentioning

confidence: 59%

“…Those with different letters are significantly different (p-value was less than 0.05) heavy metal concentrations were well below the thresholds required for the safe usage of the biochar in the environment, and therefore, could be applied to the soil without environmental concerns. Previous studies have shown that the concentration of heavy metals can be greater in the biochar than in the feedstock (Sarfraz et al 2019;Zhao et al 2019). However, biochar is able to effectively bind and immobilize heavy metals for a long period of time, but the length of time is yet to be determined (EBF 2017).…”

Section: Physicochemical Properties Of the Biochar Samplesmentioning

confidence: 98%

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Influence of pyrolysis conditions on the properties and Pb2+ and Cd2+ adsorption potential of tobacco stem biochar

Wang

Ibrahim

Tong

et al. 2020

BioRes

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Converting biomass into biochar is a smart recycling strategy. Biochar was produced from tobacco stems at temperatures of 400 °C, 500 °C, 600 °C, and 700 °C and holding times of 1.5 h, 2 h, 2.5 h, and 3 h. Its properties and adsorption capacities for Pb2+ and Cd2+ were evaluated. While the yield decreased, pH, phosphorus, potassium, ash, and surface area increased with increasing pyrolysis temperature and holding time. Nitrogen, volatile matter, and pore diameter decreased as the temperature increased, with an irregular effect of the holding time. A peak C content (652 g/kg) was recorded at 600 °C (2 h). The highest values obtained for the N, P, and K content were 25.6 g/kg (400 °C and 2 h), 7.82 g/kg and 168 g/kg (600 °C and 3 h), respectively. The heavy metal contents were within tolerable limits. The highest surface and micropore areas of 50.6 and 57.1 m2g-1, respectively, were obtained at 700 °C (3 h). The biochar had a wide range of aliphatic and aromatic C functional groups. The highest adsorption percentages of Pb2+ and Cd2+ (44.5 % and 38.3 %, respectively) by biochar produced at 700 °C (3 h) signified its suitability for heavy metal adsorption. These properties made the biochar a suitable soil amendment.

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Section: Physicochemical Properties Of the Biochar Samplessupporting

confidence: 79%

Section: Physicochemical Properties Of the Biochar Samplesmentioning

confidence: 59%

Section: Physicochemical Properties Of the Biochar Samplesmentioning

confidence: 98%

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Influence of pyrolysis conditions on the properties and Pb2+ and Cd2+ adsorption potential of tobacco stem biochar

Wang

Ibrahim

Tong

et al. 2020

BioRes

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“…The physical and chemical properties of biochar determine the changes in soil properties. Some experimental results show that the yield and characteristics of biochar mainly depend on its pyrolysis temperature and raw materials [18,19].…”

Section: Introductionmentioning

confidence: 99%

Effects of Two Types of Straw Biochar on the Mineralization of Soil Organic Carbon in Farmland

et al. 2020

Sustainability

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To investigate the effects of biochar on soil carbon composition and transformation, the effects of 1%, 2%, and 5% mass ratios of banana and cassava straw biochar on carbon dioxide release, total organic carbon (TOC), soluble organic carbon (SOC), and enzyme activity in soil were studied in incubation experiments at a constant temperature in the laboratory. The results showed that the cumulative CO2 emissions from cassava straw were 15.82 (1% addition ratio) and 28.14 μg·kg−1 (2%), which were lower than those from banana straw, i.e., 46.77 (1%) and 59.26 μg·kg−1 (2%). After culture, the total organic carbon contents of cassava straw were 8.55 (5%), 5.27 (2%), and 3.98 μg·kg−1 (1%), which were higher than those of banana straw, i.e., 6.31 (5%), 4.23 (2%), and 3.16 μg·kg−1 (1%). The organic carbon mineralization rate in each treatment showed a trend of increasing first, then decreasing, and finally stabilizing. There was a very significant positive correlation between catalase and urease activity in soil with cassava straw biochar and between catalase activity and SOC mineralization with banana straw biochar. It plays an important role in the transformation and decomposition of organic carbon. These results show that the application of biomass carbon can significantly improve the organic carbon content and enzyme activity of farmland soil, increase the cumulative mineralization amount and mineralization rate of SOC, and thus increase the carbon sequestration capacity of soil.

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“…The highest values of 8.38 mg g -1 K content, 16.2 mg g -1 Ca content, 4.21 mg g -1 Mg content, 14.8 % H content and 0.28 % S content at the lowest temperature of 300 o C were found in CD, CC, CC, PL and CC, respectively, with their lowest values found in the highest temperature of 600 o C. The findings is similar to Nwajiaku et al [25] where increase in pyrolysis temperature decreased K and Mg. However, Sarfraz et al [26]; Naeem et al [23] and Gaskin et al [30] reported increase in temperature with increase in K, Ca and Mg contents. Nelissen et al [31] and Al-Wabel et al [32], differently reported decrease in H content and H and S contents respectively with increase in temperature.…”

Section: Effects Of Pyrolysis Temperature On the Physicochemical Properties Of Biocharmentioning

confidence: 99%

Comparative analysis of nutrients composition in biochar produced from different feedstocks at varying pyrolysis temperature

Omotade

Momoh

Oluwafemi

et al. 2020

Environmental Research and Technology

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Biochar has proved to be effective in improving soil fertility and it is important to know its nutrients variability as influenced by pyrolysis temperature and feedstock type for optimum agricultural productivity. In this experiment four different feedstocks from animal and plant sources were selected and pyrolysed at four different temperatures of 300, 400, 500 and 600 ˚C for 3 hours at a heating rate of 10 ˚C min -1 . The feedstocks were Corn cob (CC), Poultry litter (PL), Cow dung (CD) and Peanut shell (PS). The results showed that increase in pyrolysis temperature led to decrease in the concentration of many of the parameters analysed in the biochar. At the lowest temperature of 300 ˚C the highest contents of (0.62 %) N in CD, (66.4 mg g -1 ) P in CC, (8.38 mg g -1 ) K in CD, (16.2 mg g -1 ) Ca in CC, (4 21 mg g -1 ) Mg in CC, (0.28 %) S in CC, were observed. On the other hand, increase in temperature resulted to increase in C, pH, Ash content and the highest pH value of 10.17 was found in CD. From this study, it can be deduced that feedstocks from animal source shows a high range of nutrient when compared to feedstocks from plant source and likewise increase in temperatures led to decrease in some essential nutrient needed by plant for growth and stability in the soil.

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Assessment of Physicochemical and Nutritional Characteristics of Waste Mushroom Substrate Biochar under Various Pyrolysis Temperatures and Times

Cited by 27 publications

References 44 publications

Influence of pyrolysis conditions on the properties and Pb2+ and Cd2+ adsorption potential of tobacco stem biochar

Influence of pyrolysis conditions on the properties and Pb2+ and Cd2+ adsorption potential of tobacco stem biochar

Effects of Two Types of Straw Biochar on the Mineralization of Soil Organic Carbon in Farmland

Comparative analysis of nutrients composition in biochar produced from different feedstocks at varying pyrolysis temperature

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