Customised Microporous Carbon 3D Structures with Good Mechanical Properties and High Nitrogen Content Obtained from Whey Powders

C Pub Date : 2023-10-24 DOI:10.3390/c9040100
Raúl Llamas-Unzueta, Luis A. Ramírez-Montoya, J. Angel Menéndez, Miguel A. Montes-Morán
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Abstract

Novel customised carbon monoliths with a high specific surface area were synthesised by carbonisation plus activation of dehydrated whey powders, a biomass byproduct of the dairy industry. The whey powders were casted directly by pouring them into a desired mould. After a pseudo-sintering process promoted by the self-reaction of the whey components (mostly lactose and whey proteins) at moderate temperatures (ca. 250 °C), 3D porous carbons were obtained. The process did not require any binder or external overpressure to prepare the 3D porous carbons. Upon thermal activation with CO2 or chemical activation with H3PO4 and KOH, the shape of the monolithic structure was preserved after the development of a microporous network (SBET up to 2400 m2/g). Both thermal and chemical activation had little effect on the macroporosity of the monoliths. Activation of these 3D carbons had to be performed with care to avoid heterogeneous skin/core activation and/or overactivation. Highly porous monoliths (SBET of 980 m2/g; open porosity of 70%) with outstanding compressive strength (10 MPa) could be obtained by thermal activation (CO2) of whey monoliths at 850 °C for 1.5 h. Additionally, the use of whey as a precursor provided the carbon monolith with a relatively high nitrogen content (ca. 3 wt.%).
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从乳清粉中获得具有良好机械性能和高氮含量的定制微孔碳三维结构
新型定制的碳单体具有高比表面积,通过碳化和脱水乳清粉的活化合成,乳清粉是乳制品工业的生物质副产品。乳清粉是通过将它们倒入所需的模具中直接铸造的。乳清成分(主要是乳糖和乳清蛋白)在中等温度(约250°C)下的自反应促进了伪烧结过程,得到了三维多孔碳。该工艺不需要任何粘合剂或外部超压来制备3D多孔碳。经CO2热活化或H3PO4和KOH化学活化,形成微孔网络(SBET高达2400 m2/g)后,整体结构的形状得以保留。热活化和化学活化对整体石的宏观孔隙度影响不大。这些三维碳的活化必须小心进行,以避免异质皮/核活化和/或过度活化。高孔隙单体石(SBET为980 m2/g;通过在850°C下对乳清整体体进行1.5小时的热活化(CO2),可以获得具有优异抗压强度(10 MPa)的开孔率(70%)。此外,使用乳清作为前驱体,可以使碳整体体具有相对较高的氮含量(约3 wt.%)。
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