2006
DOI: 10.1021/ef0504164
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Preparation of Nitrogen-Enriched Activated Carbons from Brown Coal

Abstract: Nitrogen-enriched activated carbons were prepared from a Polish brown coal. Nitrogen was introduced from urea at 350 °C in an oxidizing atmosphere both to carbonizates obtained at 500-700 °C and to activated carbons prepared from them. The activation was performed at 800 °C with KOH in argon. It has been observed that the carbonization temperature determines the amount of nitrogen that is incorporated (DC5U, 8.4 wt % N daf ; DC6U, 6.3 wt % N daf ; and DC7U, 5.4 wt % N daf ). X-ray photoelectron spectroscopy (X… Show more

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Cited by 122 publications
(83 citation statements)
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“…However, the vast majority of the research made has been focused on the production of activated carbons from the precursors with a relatively low mineral substance content and even deliberately deprived of mineral admixtures (Starck et al 2004;Pietrzak et al 2006;Jurewicz et al 2008;Pietrzak et al 2008).…”
Section: Introductionmentioning
confidence: 99%
“…However, the vast majority of the research made has been focused on the production of activated carbons from the precursors with a relatively low mineral substance content and even deliberately deprived of mineral admixtures (Starck et al 2004;Pietrzak et al 2006;Jurewicz et al 2008;Pietrzak et al 2008).…”
Section: Introductionmentioning
confidence: 99%
“…These changes are certainly related to the high temperature of the processes, which is responsible for breaking of the least stable chemical bonds present in the material, removal of heteroatoms in the form of simple gas or liquid compounds and consequently for the ordering of carbonaceous structure. The increase in nitrogen content observed for UPA and PUA samples is most probably related to the nitrogen building into the carbon structure during the reaction with urea, in the form of amines, amides, imines, lactams or nitriles [35,36]. Nevertheless, under the effect of high temperature (during pyrolysis or activation processes), a considerable part of these groups underwent decomposition or transformation to more thermally stable nitrogen species (e.g.…”
Section: Elemental Composition Of Materials Preparedmentioning
confidence: 99%
“…Nevertheless, under the effect of high temperature (during pyrolysis or activation processes), a considerable part of these groups underwent decomposition or transformation to more thermally stable nitrogen species (e.g. N-5, N-6 or N-Q [35,36]) and consequently the amount of nitrogen in the products of activation is not too high, especially for sample PUA, modified with nitrogen just before the activation process. High-temperature treatment of the demineralized coal causes also a significant increase in the ash content, as evidenced by the fact that the activation products are characterized by almost twice higher content of mineral substances than the starting material.…”
Section: Elemental Composition Of Materials Preparedmentioning
confidence: 99%
“…So great differences in the content of N daf between the samples subjected to the reaction with urea at the stage of precursor (SUDAX, SUP6AX, SUP7AX- Table 1) and those subjected to this reaction at the stage of chars (SP6UAX, SP7UAX- Table 2), and the samples modified after activation (SDAXU, SP6AXU and SP7AXU- Table 3) are most probably a consequence of a low thermal resistance of nitrogen groups introduced into the carbon structure. Earlier studies by XPS (Pietrzak et al 2006;Nowicki et al 2010b;Burg et al 2002) have proved that the reaction of carbonaceous materials with urea or ammonia involves generation of considerable amounts of amine, amide, nitrile, imine and lactam groups, characterised by low thermal stability. An indirect evidence of formation of such groups is a simultaneous increase in the content of nitrogen and hydrogen after the reaction with urea.…”
Section: Pyrolysis 600ºc 700ºcmentioning
confidence: 99%
“…Efficiency of nitrogenation at this stage is about twice smaller than during precursor modification, but it is much higher than for chars SP6 and SP7. This result is probably a consequence of the presence of numerous oxygen groups on the surface of activated carbons which favours introduction of nitrogen groups (Pietrzak et al 2006;Bimer et al 1998). …”
Section: Pyrolysis 600ºc 700ºcmentioning
confidence: 99%