Jute-derived microporous/mesoporous carbon with ultra-high surface area using a chemical activation process

Thapa

et al. 2019

Self Cite

Iodine and methylene blue adsorption properties of the high surface area nanoporous carbon materials derived from agro-waste and rice husk is reported. Rice husk was pre-carbonized at 300 °C in air followed by leaching out the silica nanoparticles by extraction with sodium hydroxide solution. The silica-free rice husk char was mixed with chemical activating agents sodium hydroxide (NaOH), zinc chloride (ZnCl2), and potassium hydroxide (KOH) separately at a mixing ratio of 1:1 (wt%) and carbonized at 900 °C under a constant flow of nitrogen. The prepared carbon materials were characterized by scanning electron microscopy (SEM), Fourier transformed-infrared spectroscopy (FT-IR), powder X-ray diffraction (pXRD), and Raman scattering. Due to the presence of bimodal micro- and mesopore structures, KOH activated samples showed high specific surface area ca. 2342 m2/g and large pore volume ca. 2.94 cm3/g. Oxygenated surface functional groups (hydroxyl, carbonyl, and carboxyl) were commonly observed in all of the samples and were essentially non-crystalline porous particle size of different sizes (<200 μm). Adsorption study revealed that KOH activated samples could be excellent material for the iodine and methylene blue adsorption from aqueous phase. Iodine and methylene blue number were ca. 1726 mg/g and 608 mg/g, respectively. The observed excellent iodine and methylene blue adsorption properties can be attributed to the well-developed micro- and mesopore structure in the carbon material. This study demonstrates that the agricultural waste, rice husk, and derived nanoporous carbon materials would be excellent adsorbent materials in water purifications.

Section: Introductionmentioning

confidence: 99%

Rice Husk-Derived High Surface Area Nanoporous Carbon Materials with Excellent Iodine and Methylene Blue Adsorption Properties

Thapa

et al. 2019

Self Cite

“…prepared JDAC with high SSA using a chemical activation method. [37] Initially, the jute fibers with a height of � 190 cm were cut Figure 10. FESEM micrographs of a) raw jute sticks, b) charcoal, c) JDAC by physical activation (steam), and d) JDAC by chemical activation.…”

Section: P E R S O N a L A C C O U N T T H E C H E M I C A L R E C O R Dmentioning

confidence: 99%

“…[35,36] In addition, the jute stick is an agricultural byproduct (Figure 1), which yields~2.5 times higher than jute fiber by weight and is frequently used as a raw material to generate fire for cooking purposes. [29,36] According to a previous report, [37] each year the world generates 2.8 and 7 million metric tons of jute fibers and jute sticks, respectively. Still, jute fiber products are becoming less popular with the times due to the presence of fashionable and long-lasting synthetic fiber products in the market.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Utilization of Jute‐Derived Carbon: A Short Review

Aziz

Shah

Kashem³

2020

The Chemical Record

This article summarizes the preparation and applications of carbon derived from jute sticks and fibers that are low‐cost, widely available, renewable, and environmentally friendly. Both the fibers and sticks are considered ideal candidates of carbon preparation because they are composed of cellulose, hemicelluloses, and lignin, and contain negligible ash content. Various carbon preparation methods including simple pyrolysis, pyrolysis with chemical and physical activations are discussed. The impacts of several parameters including types of activating agents, impregnation ratio, and temperature on their morphology, surface area, pore size, crystallinity, and surface functional groups are also emphasized. Various treatments to endow functionalization for increasing the practical applicability, such as chemical, physical, and physico‐chemical methods, are discussed. In addition, applications of jute‐derived carbon in various practical areas, including energy storage, water treatment, and sensors, are also highlighted in this report. Due to the porous fine structure and a large specific surface area, the jute‐derived carbon could be considered as a powerful candidate material for various industrial applications. Finally, possible future prospects of jute‐derived carbon for various applications are pointed out.

Chemistry An Asian Journal

“…To date, various carbon materials with different pore sizes, from micropores to macropores, have been extensively studied. Many carbon materials have been produced in a series of carbonization and activation processes with controllable pore structures, such as activated carbon and templated NPCs . Templated carbon materials have been prepared by various approaches, such as direct carbonization from carbon precursors and soft‐ and hard‐templating methods .…”

Section: Introductionmentioning

confidence: 99%

“…Many carbon materials have been produced in as eries of carbonization and activation processes with controllable pore structures, such as activated carbon and templated NPCs. [6,7] Templated carbon materials have been prepared by variousa pproaches, such as direct carbonization from carbon precursors and soft-and hard-templating methods. [8] To enhance the electrochemical performance of electrode materials, heteroatoms (e.g.,n itrogen (N), sulfur (S), and boron (B)) have been doped into porous carbons.…”

Section: Introductionmentioning

confidence: 99%

Metal–Organic Framework (MOF)‐Derived Nanoporous Carbon Materials

Marpaung

Kim

Khan

et al. 2019

Self Cite

125

Metal–organic framework (MOF)‐derived nanoporous carbon materials have attracted significant interest due to their advantages of controllable porosity, good thermal/chemical stability, high electrical conductivity, catalytic activity, easy modification with other elements and materials, etc. Thus, MOF‐derived carbons have been used in numerous applications, such as environmental remediations, energy storage systems (i.e. batteries, supercapacitors), and catalysts. To date, many strategies have been developed to enhance the properties and performance of MOF‐derived carbons. Herein, we introduce and summarize recent important approaches for advanced MOF‐derived carbon structures with a focus on precursor control, heteroatom doping, shape/orientation control, and hybridization with other functional materials.