Physical–chemical properties and hygroscopicity of Brazilian metallurgical charcoal

IF 3.1 2区 农林科学 Q1 FORESTRY Wood Science and Technology Pub Date : 2024-02-01 DOI:10.1007/s00226-024-01529-2
Luciano Junqueira Costa, Vinícius Resende de Castro, Paulo Fernando Trugilho, Artur Queiroz Lana, Aylson Costa Oliveira, Michael Douglas Roque Lima, Thiago de Paula Protásio, Angélica de Cássia Oliveira Carneiro, Marcos Oliveira de Paula
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Abstract

Wood is exposed to different atmospheric conditions in the production of charcoal due to the occurrence of rainfall and variation in relative humidity. However, there is a lack of scientific information related to charcoal hygroscopicity and desorption capacity depending on water content. Thus, in the present study, we analyzed the influence of carbonization temperature in brick kilns on the hygroscopic capacity of charcoal from a 7-year-old Eucalyptus sp. wood. Charcoal was produced at final temperatures of 340, 380, 420, and 460 °C. Raman spectroscopy, Fourier-transform infrared absorption spectroscopy, scanning electron microscopy, and surface area measurement were performed to identify structural changes in charcoal. The charcoal samples were exposed to six different saline solutions to simulate the relative humidity of the environment, ranging from 33 to 98%, for the determination of the moisture adsorption capacity. The charcoal surface area values ranged from 7.9 (340 °C) to 12.3 m2 g−1 (460 °C). Charcoal porosity increased by 14.4% with increasing temperature. The adsorption capacity decreased with the rising final carbonization temperature. An average reduction of 9.9% between the moisture adsorbed by the charcoal samples produced at 340 °C and 460 °C was observed. The increase in surface area and porosity of charcoal as a function of temperature resulted in the loss of environmental moisture adsorption capacity due to the removal of carboxyl and hydroxyl groups in the temperature range analyzed. Physical mechanisms were more relevant in the water–charcoal relationship, which can directly influence the drying process of the bioreducer in stockyards.

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巴西冶金木炭的物理化学特性和吸湿性
在木炭生产过程中,由于降雨和相对湿度的变化,木材会暴露在不同的大气条件下。然而,有关木炭吸湿性和解吸能力取决于含水量的科学信息却很缺乏。因此,在本研究中,我们分析了砖窑炭化温度对 7 年树龄桉树木炭吸湿能力的影响。木炭的最终温度分别为 340、380、420 和 460 °C。通过拉曼光谱、傅立叶变换红外吸收光谱、扫描电子显微镜和表面积测量来确定木炭的结构变化。将木炭样品暴露在六种不同的盐溶液中,模拟环境的相对湿度(从 33% 到 98%),以测定其吸湿能力。木炭的表面积值从 7.9(340 °C)到 12.3 m2 g-1(460 °C)不等。木炭的孔隙率随温度升高增加了 14.4%。吸附能力随着最终碳化温度的升高而降低。在 340 °C 和 460 °C 下生产的木炭样品吸附的水分平均减少了 9.9%。随着温度的升高,木炭的表面积和孔隙率也随之增大,在分析的温度范围内,由于羧基和羟基的去除,导致环境吸湿能力下降。物理机制与水和木炭的关系更为相关,可直接影响堆场中生物还原剂的干燥过程。
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来源期刊
Wood Science and Technology
Wood Science and Technology 工程技术-材料科学:纸与木材
CiteScore
5.90
自引率
5.90%
发文量
75
审稿时长
3 months
期刊介绍: Wood Science and Technology publishes original scientific research results and review papers covering the entire field of wood material science, wood components and wood based products. Subjects are wood biology and wood quality, wood physics and physical technologies, wood chemistry and chemical technologies. Latest advances in areas such as cell wall and wood formation; structural and chemical composition of wood and wood composites and their property relations; physical, mechanical and chemical characterization and relevant methodological developments, and microbiological degradation of wood and wood based products are reported. Topics related to wood technology include machining, gluing, and finishing, composite technology, wood modification, wood mechanics, creep and rheology, and the conversion of wood into pulp and biorefinery products.
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