Do All Carbonized Charcoals Have the Same Chemical Structure? 2. A Model of the Chemical Structure of Carbonized Charcoal

Bourke, Jared; Manley‐Harris, Merilyn; Fushimi, Chihiro; Dowaki, Kiyoshi; Nunoura, Takuro; Antal, Michael Jerry

doi:10.1021/ie070415u

Cited by 257 publications

(185 citation statements)

References 43 publications

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“…Bourke et al (23) found that the lack of atomic pore space within the crystallite carbon layers as well as recondensation and trapping of VM in pores reduces the SA.…”

Section: Composite Char -Turbostratic Crystallites Embedded In a Low-mentioning

confidence: 99%

Dynamic Molecular Structure of Plant Biomass-Derived Black Carbon (Biochar)

Keiluweit

Nico

Johnson

et al. 2010

Environ. Sci. Technol.

2,430

124

1,222

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“…Bourke et al (23) found that the lack of atomic pore space within the crystallite carbon layers as well as recondensation and trapping of VM in pores reduces the SA.…”

Section: Composite Char -Turbostratic Crystallites Embedded In a Low-mentioning

confidence: 99%

Dynamic Molecular Structure of Plant Biomass-Derived Black Carbon (Biochar)

Keiluweit

Nico

Johnson

et al. 2010

Environ. Sci. Technol.

2,430

124

1,222

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show abstract

“…In the process of pyrolysis, the biochar surface forms many free radicals [16] that are generated by oxygen atoms and inorganic impurities of the feedstock [36]. The free radical content varies with pyrolytic temperature.…”

Section: The Degradation Products Of Cp In Soil and Biocharmentioning

confidence: 99%

Effects of Biochar Amendment on Chloropicrin Adsorption and Degradation in Soil

Liu¹,

Wang

Yan

et al. 2016

Energies

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Abstract:The characteristics of biochar vary with pyrolysis temperature. Chloropicrin (CP) is an effective fumigant for controlling soil-borne pests. This study investigated the characteristics of biochars prepared at 300, 500, and 700 • C by michelia alba (Magnolia denudata) wood and evaluated their capacity to adsorb CP. The study also determined the potential influence of biochar, which was added to sterilized and unsterilized soils at rates of 0%, 1%, 5%, and 100%, on CP degradation. The specific surface area, pore volume, and micropores increased considerably with an increase in the pyrolytic temperature. The adsorption rate of biochar for CP increased with increasing pyrolytic temperature. The maximum adsorption amounts of CP were similar for the three biochars. Next, the study examined the degradation ability of the biochar for CP. The degradation rate constant (k) of CP increased when biochar was added to the soil, and k increased with increased amendment rate and pyrolysis temperature. The results indicate that biochar can accelerate CP degradation in soil. The findings will be instructive in using biochar as a new fertilizer in fumigating soil with CP.

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“…Thermogravimetric studies show that during the carbonization of a lignocellulosic material, carboxyl groups are the most thermolabile oxygen groups, as they can be decomposed as CD 2 at temperatures in the range of 100 to 400 °C, while carboxylic anhydrides and lactones decompose in the range of 430 660 °C. The other types of oxygen groups (phenols, ethers, carbonyls and quinones) are decomposed thermally as either CD or CD 2 at temperatures above 600 °C, the pyrone structures being the most thermally stable (decomposing at 900 to 1,200 °C) (Bourke et al, 2007). Thus, to control the acidic or basic nature of the activated carbon produced, except for the intrinsic properties of the precursor material, the temperature and heating rates must be carefully controlled in the carbonization and activation process (Dliveira & França, 2008).…”

Section: Adsorbent Characterizationmentioning

confidence: 99%

Extraction of hydrocolloids from Pereskia Aculeata Miller: reuse of process residue as activated carbon for the pigment-removal phase

et al. 2018

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Hydrocolloids of Pereskia aculeata Miller (DPNH) are potential ingredients in food industry as emulsifiers and stabilizers. The extraction process of DPNH requires the removal of pigments with activated carbon. Because this step is critical to the quality of the ingredient and has an impact on costs, a new activated carbon has been developed with residues from the same process. Residues activated with NaDH and H 3 PD 4 (300 °C, 1 h) were subjected to batch adsorption tests in model solutions of malachite green (MG), carbohydrate and protein. Residue treated with 85% H 3 PD 4 (DPNAC) had higher productivity and MG adsorption capacity, displaying a predominantly microporous surface (MEV/BET) with chemical activation confirmed by TG/FTOR. DPNAC showed higher MG and protein adsorption capacity than the commercial activated carbon (CAC) did. Results for MG-adsorption capacity by DPNAC did not show significant differences in the presence of protein and carbohydrate, presenting the higher affinity of the adsorbent for the dye. Adsorption isotherms showed DPNAC to be more favorable to MG adsorption than CAC, and to have a good fit to Langmuir-Freundlich model. DPNAC made it possible to reduce costs and allowed the sustainability of the process, leading to increased efficiency in selective pigment removal compared with CAC.Keywords: adsorption; carbohydrate; malachite green; protein; sustainable process.Practical Application: The activated carbon obtained using solid residues of the extraction process of hydrocolloids from Pereskia aculeata Miller proved to be more effective in protein and pigment adsorptions and less effective in carbohydrate adsorption when compared to using a commercial activated carbon. The potential use is waste treatment systems and clarification process.

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Do All Carbonized Charcoals Have the Same Chemical Structure? 2. A Model of the Chemical Structure of Carbonized Charcoal

Cited by 257 publications

References 43 publications

Dynamic Molecular Structure of Plant Biomass-Derived Black Carbon (Biochar)

Dynamic Molecular Structure of Plant Biomass-Derived Black Carbon (Biochar)

Effects of Biochar Amendment on Chloropicrin Adsorption and Degradation in Soil

Extraction of hydrocolloids from Pereskia Aculeata Miller: reuse of process residue as activated carbon for the pigment-removal phase

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