Your search keyword '"Boehm titration"' showing total 2 results

1. Production of activated carbons from Quercus cerris acorn shell under various experiment conditions, and their characterizations.

Author

Çesko, Cengiz, Geçgel, Ünal, Koraqi, Hyrije, Üner, Osman, Nuha, Demokrat, Durmishi, Berat, Daci, Roland, Elshani, Diellëza, and Palüzar, Hatice

Abstract

Due to the high porosities, large surface areas, insolubilities in solutions, and unique structural and morphological structures, porous materials are utilized in various application areas such as energy conversion and storage, wastewater treatment, adsorption, catalysis and photocatalysis. In this study, activated carbons (QCACs), one type of porous materials, were synthesized from Quercus cerris acorn shells by using ZnCl2 chemical activation under various production conditions. The effects of carbonization temperature, carbonization period, and impregnation ratios on the yields, surface areas, pore developments, and N2 adsorption–desorption isotherms of activated carbons obtained were investigated in detail. The highest surface area (1751.61 m2/g) was reached when utilized at the impregnation ratio of 2.0 at 500 ℃ for 90 min. The total pore volume of QCAC increased with increasing impregnation ratio, however the micropore volume of QCAC reduced. It was found from the pore distribution data that QCACs contained mostly narrow mesopores and a little amount of micropores. Also, N2 adsorption–desorption isotherm data revealed that QCACs produced under different conditions were usually mesopore structures, and the pores were narrow slit-shaped. Moreover, the data provided from SEM, FTIR, Boehm titration, and elemental analysis gave more characterization information about QCACs synthesized. [ABSTRACT FROM AUTHOR]

Published

2024

2. Evolution of oxygen-containing functional groups on coal char surface during gasification in H2O/CO2.

Author

Zhang, Meng, Bai, Yonghui, Men, Xiaoyong, Song, Xudong, Lv, Peng, Wang, Jiaofei, Su, Weiguang, Lu, Guanghua, and Yu, Guangsuo

Subjects

COAL gasification, FUNCTIONAL groups, CHAR, FIXED bed reactors, COAL, CARBON dioxide

Abstract

Gasification converts coal into syngas (CO and H 2) for downstream utilization. The most important reaction in an autothermal gasifier is the char−H 2 O/CO 2 reaction. The evolution of C(O) complexes on the coal char surface directly determines the pathways and rates of CO and H 2 generation. This study mainly used a fixed bed reactor to prepare Zhundong coal char with different reaction levels in H 2 O and CO 2 , and its surface carboxyl, lactone, phenolic hydroxyl, and hydroxyl functional groups were systematically analyzed by using Boehm titration, FT-IR, and XPS. The results show that the contents of the four oxygen-containing groups in raw coal are in the order of carboxyl＞lactone＞phenol hydroxyl＞hydroxyl. In H 2 O gasification, the lactone groups were more susceptible to H 2 O resulting in a significant increase in carboxyl content at the early stage of the reaction. The hydroxyl, as a very active group in the reaction, and the amount of its generation and consumption was very obvious. The phenolic hydroxyl−the least thermally stable group among these four types of groups, was unable to participate in the inter-transformation between oxygen-containing functional groups during the gasification. During CO 2 gasification, the hydroxyl was rapidly consumed at the initial stage of the reaction and then shown a slow growth trend, and the newly generated hydroxyl would continue to undergo dehydrogenation to form new functional groups. At the end of the reaction, the transformation of other oxygen-containing functional groups into more stable carbonyl groups leads to a sudden increase in the content of carboxyl and lactone. In this work, Boehm titration was introduced into the determination of oxygen-containing functional groups on the surface of char during gasification in H 2 O/CO 2. • Evolution of oxygen-containing functional groups on coal char surface during gasification was revealed. • The evolution of oxygen-containing groups in H 2 O/CO 2 was significantly different. • H 2 O has more noticeable effect in increasing aromatic C=C of char than CO 2 during gasification. [ABSTRACT FROM AUTHOR]

Published

2024