Sequential Production of Levulinic Acid and Porous Carbon Material from Cellulose

Kang, Shimin; Pan, J. S.; Gu, Guoting; Wang, Chong; Wang, Zepan; Tan, Jionghao; Liu, Guiheng

doi:10.3390/ma11081408

Cited by 7 publications

(6 citation statements)

References 38 publications

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“…The SSAs obtained for BCs and PHCs from cellulose correspond well with literature, since similar SSAs were obtained by Kang et al [81] on pyrolyzed cellulosic hydrochar. The type IV isotherms observed for PHCs from cellulose (Figure 7B) indicate the presence of macropores.…”

Section: Discussionsupporting

confidence: 89%

Conductive Carbon Materials from the Hydrothermal Carbonization of Vineyard Residues for the Application in Electrochemical Double-Layer Capacitors (EDLCs) and Direct Carbon Fuel Cells (DCFCs)

et al. 2019

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This study investigates the production of bio-based carbon materials for energy storage and conversion devices based on two different vineyard residues (pruning, pomace) and cellulose as a model biomass. Three different char categories were produced via pyrolysis at 900 °C for 2 h (biochars, BC), hydrothermal carbonization (HTC) (at 220, 240 or 260 °C) with different reaction times (60, 120 or 300 min) (hydrochars, HC), or HTC plus pyrolysis (pyrolyzed hydrochars, PHC). Physicochemical, structural, and electrical properties of the chars were assessed by elemental and proximate analysis, gas adsorption surface analysis with N2 and CO2, compression ratio, bulk density, and electrical conductivity (EC) measurements. Thermogravimetric analysis allowed conclusions to be made about the thermochemical conversion processes. Taking into consideration the required material properties for the application in electrochemical double-layer capacitors (EDLC) or in a direct carbon fuel cell (DCFC), the suitability of the obtained materials for each application is discussed. Promising materials with surface areas up to 711 m2 g−1 and presence of microporosity have been produced. It is shown that HTC plus pyrolysis from cellulose and pruning leads to better properties regarding aromatic carbon structures, carbon content (>90 wt.%), EC (up to 179 S m−1), and porosity compared to one-step treatments, resulting in suitable materials for an EDLC application. The one-step pyrolysis process and the resulting chars with lower carbon contents and low EC values between 51 and 56 S m−1 are preferred for DCFC applications. To conclude, biomass potentials can be exploited by producing tailored biomass-derived carbon materials via different carbonization processes for a wide range of applications in the field of energy storage and conversion.

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Section: Discussionsupporting

confidence: 89%

Conductive Carbon Materials from the Hydrothermal Carbonization of Vineyard Residues for the Application in Electrochemical Double-Layer Capacitors (EDLCs) and Direct Carbon Fuel Cells (DCFCs)

et al. 2019

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“…Moreover, sub-micropore and mesopore architectures within a porous structure provide interconnected channels throughout the fast charge/discharge route, leading to a high rate capability and enhanced charge storage capacity. Macropores also deliver ion buffering reservoirs, which shorten ion diffusion pathways into internal porosity assuring decrease in the electric resistance. − According to the International Union of Pure and Applied Chemistry, a micropore is categorized as a pore with a diameter of less than 2 nm, while a pore with size ranging between 2 and 50 mm is considered to be a mesopore, and the pore size of a macropore is larger than 50 nm …”

Section: Introductionmentioning

confidence: 99%

Beyond Conventional Activating Methods, a Green Approach for the Synthesis of Biocarbon and Its Supercapacitor Electrode Performance

Altıncı

Demir

2020

Energy Fuels

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The development of cost-effective and renewable carbon electrodes by using a green production approach is of significant importance for supercapacitors (SCs). Herein, we present an effective synthetic method that utilizes pistachio shells and Na2S2O3 as a carbon precursor and activating agent, respectively, to prepare porous carbon by hydrothermal carbonization and subsequent chemical activating processes. The NCNaK-1 (optimum sample, N/S doped carbon prepared by Na2S2O3 and KCl at 800 °C) exhibits sponge-like morphology, a relatively high specific surface area of 775 m2 g–1 along with interconnected hierarchical porosity, and high nitrogen/sulfur doping into the carbon framework. The specific capacity of the NCNaK-1 electrode is as high as 166 F g–1 at a current density of 0.5 A g–1 in 1 M KOH electrolyte and ∼96% capacitance retention over 5000 cycles. Moreover, a SC assembled with NCNaK-1 electrodes has an energy density of 2.7 W h kg–1 at a power density of 250 W kg–1. This research introduces a sustainable, environmentally benign, economic, high production yield, and efficient porous carbon production strategy.

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“…Preliminary investigations are being made and forwarded to the valuation of HUs approaching the structure and its formation mechanism [14,46]. Recently, it was demonstrated that HUs generally contained a carbon content of 60-80 wt% [55], which indicated that more than 30% of the initial carbon in cellulose was wasted as solid carbonaceous residue. As a material with high carbon content, Kang et al [55], showed that about 74.4% of the initial carbon of cellulose was transferred into value-added products, (47% carbon in LA), and also 16.1% in carbon adsorbents, especially for wastewater treatment.…”

Section: The Challenge Of the Current Circular Economy In Valuing Husmentioning

confidence: 99%

“…Recently, it was demonstrated that HUs generally contained a carbon content of 60-80 wt% [55], which indicated that more than 30% of the initial carbon in cellulose was wasted as solid carbonaceous residue. As a material with high carbon content, Kang et al [55], showed that about 74.4% of the initial carbon of cellulose was transferred into value-added products, (47% carbon in LA), and also 16.1% in carbon adsorbents, especially for wastewater treatment. HUs represent a matrix rich in carbon and furanic structures with hydroxyl and carbonyl functional groups.…”

Section: The Challenge Of the Current Circular Economy In Valuing Husmentioning

confidence: 99%

Challenges to Levulinic Acid and Humins Valuation in the Sugarcane Bagasse Biorefinery Concept

et al. 2020

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Levulinic acid (LA) is currently one of the most promising chemicals derived from biomass. However, its large-scale production is hampered by the challenges in biomass hydrolysis and the poor selectivity due to the formation of humins (HUs). This study addresses these challenges using the biorefinery concept of biomass fractionation. A three-step process (pretreatment, delignification, and acid-catalyzed conversion) was optimized to produce LA from SCB considering the yield (Y LA ), efficiency (E LA ), and concentration of LA (C LA ) as functions of temperature, reaction time, acid concentration, and solids loading. By means of a multi-response optimization, values of Y LA (20.9 ± 1.25 g/100g ISF-D ), E LA (37.5 ± 2.24 mol%), and C LA (25.1 ± 1.50 g/L) were obtained at 180°C, 75 min, 7.0% w/v H 2 SO 4 , and 12.0% w/v of solids loading. Six scenarios for production of LA were analyzed in terms of yields of LA, HUs, lignin, and other sugar-derived products considering one-, two-, or three-step processes. The economic analysis indicated that the three-step scenario delivers better economic figures given that other valuable biomass fractions (hemicellulosic sugars and lignin) are better used and contribute to the overall economic performance of the process. The results also demonstrate the burden of HUs in the economics of the process because it was shown that the largest production of LA is also linked to the largest formation of HUs, which does not necessarily yield the best economic results. These findings indicate the importance of added value by-products for the profitable production of LA in biorefineries.

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Sequential Production of Levulinic Acid and Porous Carbon Material from Cellulose

Cited by 7 publications

References 38 publications

Conductive Carbon Materials from the Hydrothermal Carbonization of Vineyard Residues for the Application in Electrochemical Double-Layer Capacitors (EDLCs) and Direct Carbon Fuel Cells (DCFCs)

Conductive Carbon Materials from the Hydrothermal Carbonization of Vineyard Residues for the Application in Electrochemical Double-Layer Capacitors (EDLCs) and Direct Carbon Fuel Cells (DCFCs)

Beyond Conventional Activating Methods, a Green Approach for the Synthesis of Biocarbon and Its Supercapacitor Electrode Performance

Challenges to Levulinic Acid and Humins Valuation in the Sugarcane Bagasse Biorefinery Concept

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