Influence of surface morphology on the performance of nanostructured ZnO-loaded ceramic honeycomb for syngas desulfurization

[Display omitted] •ZnO nanorods (ZnO-nR) and nanosheets (ZnO-nS) were immobilized on honeycomb.•The nanostructured ZnO-loaded honeycomb were used for syngas desulfurization.•The mechanisms of ZnO-nS and ZnO-nR formation are proposed to provide further insights.•ZnO-nS (single layer) present better p...

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Veröffentlicht in:	Fuel (Guildford) 2018-01, Vol.211, p.591-599
Hauptverfasser:	Oh, Wen-Da, Lei, Junxi, Veksha, Andrei, Giannis, Apostolos, Lisak, Grzegorz, Chang, Victor W.-C., Hu, Xiao, Lim, Teik-Thye
Format:	Artikel
Sprache:	eng
Schlagworte:	Cordierite Crystal structure Crystallinity Desulfurization Desulfurizing Gasification H2S removal Heat transfer Hexamethylenetetramine Honeycomb Honeycomb construction Honeycombs Hydrogen sulfide Mass transfer Morphology Mullite Nanorods Nanostructure Nanostructured materials Nanostructured ZnO Scanning electron microscopy Sorbents Sorption Studies Sulfur Sulfur compounds Syngas Synthesis gas Synthetic fuels Zinc Zinc oxide ZnO nanosheets
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creator	Oh, Wen-Da Lei, Junxi Veksha, Andrei Giannis, Apostolos Lisak, Grzegorz Chang, Victor W.-C. Hu, Xiao Lim, Teik-Thye
description	[Display omitted] •ZnO nanorods (ZnO-nR) and nanosheets (ZnO-nS) were immobilized on honeycomb.•The nanostructured ZnO-loaded honeycomb were used for syngas desulfurization.•The mechanisms of ZnO-nS and ZnO-nR formation are proposed to provide further insights.•ZnO-nS (single layer) present better performance than ZnO-nS (three layers), ZnO-nR and commercial ZnO.•ZnO-nS has better regenerability and higher sorption capacity than other sorbents. A facile seeding-growth protocol was employed to immobilize nanostructured ZnO with nanorod and nanosheet morphologies (ZnO-nR and ZnO-nS, respectively) on cordierite-mullite honeycomb support. By varying the hexamethylenetetramine (HMTA) concentration, Zn precursor, and number of growth cycles during synthesis, different nanorod sizes, nanosheets textures and ZnO layers were obtained. The ZnO-loaded honeycombs were characterized using FESEM, EDX and XRD indicating that the immobilized layer of nanostructured ZnO was highly-crystalline with a thickness of ∼1µm. The synthesized nanostructured ZnO-loaded honeycombs and a commercial ZnO sorbent were applied for removal of sulfur compounds (H2S and COS) from syngas at 400°C. The ZnO-nS showed significantly longer breakthrough time (BTTS) and higher total sulfur sorption capacity (48.7mgg−1 ZnO, BTTS=75.4min) than the ZnO-nR (9–12mgg−1 ZnO, BTTS=23–25min) and commercial ZnO sorbent (4.6mgg−1 ZnO, BTTS=6.8min). The superior sorption capacity of ZnO-nS was attributed to the significantly better surface coverage and higher crystallinity of ZnO nanosheets on the honeycomb. The introduction of additional ZnO nanosheets layers (up to 3 layers) through repeated growth process increased the ZnO loading to ∼1.5±0.1mgmm−1 (from ∼0.9±0.1mgmm−1 in the single layer) but resulted in poorer performance (11.6mgg−1 ZnO, BTTS=24.6min) compared to ZnO-nS. This was due to the increased internal mass transfer resistance and decreased density of the effective reactive sites. The mechanism of ZnO-nS formation is also proposed to provide further insights. Overall, the ZnO-nS showed better regenerability, lower mass transfer resistance, and higher sorption capacity compared to the commercial ZnO and ZnO-nR sorbents indicating that it has a promising potential for syngas desulfurization.
doi_str_mv	10.1016/j.fuel.2017.09.088
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A facile seeding-growth protocol was employed to immobilize nanostructured ZnO with nanorod and nanosheet morphologies (ZnO-nR and ZnO-nS, respectively) on cordierite-mullite honeycomb support. By varying the hexamethylenetetramine (HMTA) concentration, Zn precursor, and number of growth cycles during synthesis, different nanorod sizes, nanosheets textures and ZnO layers were obtained. The ZnO-loaded honeycombs were characterized using FESEM, EDX and XRD indicating that the immobilized layer of nanostructured ZnO was highly-crystalline with a thickness of ∼1µm. The synthesized nanostructured ZnO-loaded honeycombs and a commercial ZnO sorbent were applied for removal of sulfur compounds (H2S and COS) from syngas at 400°C. The ZnO-nS showed significantly longer breakthrough time (BTTS) and higher total sulfur sorption capacity (48.7mgg−1 ZnO, BTTS=75.4min) than the ZnO-nR (9–12mgg−1 ZnO, BTTS=23–25min) and commercial ZnO sorbent (4.6mgg−1 ZnO, BTTS=6.8min). The superior sorption capacity of ZnO-nS was attributed to the significantly better surface coverage and higher crystallinity of ZnO nanosheets on the honeycomb. The introduction of additional ZnO nanosheets layers (up to 3 layers) through repeated growth process increased the ZnO loading to ∼1.5±0.1mgmm−1 (from ∼0.9±0.1mgmm−1 in the single layer) but resulted in poorer performance (11.6mgg−1 ZnO, BTTS=24.6min) compared to ZnO-nS. This was due to the increased internal mass transfer resistance and decreased density of the effective reactive sites. The mechanism of ZnO-nS formation is also proposed to provide further insights. Overall, the ZnO-nS showed better regenerability, lower mass transfer resistance, and higher sorption capacity compared to the commercial ZnO and ZnO-nR sorbents indicating that it has a promising potential for syngas desulfurization.</description><identifier>ISSN: 0016-2361</identifier><identifier>EISSN: 1873-7153</identifier><identifier>DOI: 10.1016/j.fuel.2017.09.088</identifier><language>eng</language><publisher>Kidlington: Elsevier Ltd</publisher><subject>Cordierite ; Crystal structure ; Crystallinity ; Desulfurization ; Desulfurizing ; Gasification ; H2S removal ; Heat transfer ; Hexamethylenetetramine ; Honeycomb ; Honeycomb construction ; Honeycombs ; Hydrogen sulfide ; Mass transfer ; Morphology ; Mullite ; Nanorods ; Nanostructure ; Nanostructured materials ; Nanostructured ZnO ; Scanning electron microscopy ; Sorbents ; Sorption ; Studies ; Sulfur ; Sulfur compounds ; Syngas ; Synthesis gas ; Synthetic fuels ; Zinc ; Zinc oxide ; ZnO nanosheets</subject><ispartof>Fuel (Guildford), 2018-01, Vol.211, p.591-599</ispartof><rights>2017 The Authors</rights><rights>Copyright Elsevier BV Jan 1, 2018</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c409t-454d25b37e8ad198bfa40b629ecdd031c94c81d3ea545bb73627eacdb5d8b0c03</citedby><cites>FETCH-LOGICAL-c409t-454d25b37e8ad198bfa40b629ecdd031c94c81d3ea545bb73627eacdb5d8b0c03</cites><orcidid>0000-0003-4647-0342 ; 0000-0003-4230-9092</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://dx.doi.org/10.1016/j.fuel.2017.09.088$$EHTML$$P50$$Gelsevier$$Hfree_for_read</linktohtml><link.rule.ids>314,777,781,3537,27905,27906,45976</link.rule.ids></links><search><creatorcontrib>Oh, Wen-Da</creatorcontrib><creatorcontrib>Lei, Junxi</creatorcontrib><creatorcontrib>Veksha, Andrei</creatorcontrib><creatorcontrib>Giannis, Apostolos</creatorcontrib><creatorcontrib>Lisak, Grzegorz</creatorcontrib><creatorcontrib>Chang, Victor W.-C.</creatorcontrib><creatorcontrib>Hu, Xiao</creatorcontrib><creatorcontrib>Lim, Teik-Thye</creatorcontrib><title>Influence of surface morphology on the performance of nanostructured ZnO-loaded ceramic honeycomb for syngas desulfurization</title><title>Fuel (Guildford)</title><description>[Display omitted] •ZnO nanorods (ZnO-nR) and nanosheets (ZnO-nS) were immobilized on honeycomb.•The nanostructured ZnO-loaded honeycomb were used for syngas desulfurization.•The mechanisms of ZnO-nS and ZnO-nR formation are proposed to provide further insights.•ZnO-nS (single layer) present better performance than ZnO-nS (three layers), ZnO-nR and commercial ZnO.•ZnO-nS has better regenerability and higher sorption capacity than other sorbents. A facile seeding-growth protocol was employed to immobilize nanostructured ZnO with nanorod and nanosheet morphologies (ZnO-nR and ZnO-nS, respectively) on cordierite-mullite honeycomb support. By varying the hexamethylenetetramine (HMTA) concentration, Zn precursor, and number of growth cycles during synthesis, different nanorod sizes, nanosheets textures and ZnO layers were obtained. The ZnO-loaded honeycombs were characterized using FESEM, EDX and XRD indicating that the immobilized layer of nanostructured ZnO was highly-crystalline with a thickness of ∼1µm. The synthesized nanostructured ZnO-loaded honeycombs and a commercial ZnO sorbent were applied for removal of sulfur compounds (H2S and COS) from syngas at 400°C. The ZnO-nS showed significantly longer breakthrough time (BTTS) and higher total sulfur sorption capacity (48.7mgg−1 ZnO, BTTS=75.4min) than the ZnO-nR (9–12mgg−1 ZnO, BTTS=23–25min) and commercial ZnO sorbent (4.6mgg−1 ZnO, BTTS=6.8min). The superior sorption capacity of ZnO-nS was attributed to the significantly better surface coverage and higher crystallinity of ZnO nanosheets on the honeycomb. The introduction of additional ZnO nanosheets layers (up to 3 layers) through repeated growth process increased the ZnO loading to ∼1.5±0.1mgmm−1 (from ∼0.9±0.1mgmm−1 in the single layer) but resulted in poorer performance (11.6mgg−1 ZnO, BTTS=24.6min) compared to ZnO-nS. This was due to the increased internal mass transfer resistance and decreased density of the effective reactive sites. The mechanism of ZnO-nS formation is also proposed to provide further insights. 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A facile seeding-growth protocol was employed to immobilize nanostructured ZnO with nanorod and nanosheet morphologies (ZnO-nR and ZnO-nS, respectively) on cordierite-mullite honeycomb support. By varying the hexamethylenetetramine (HMTA) concentration, Zn precursor, and number of growth cycles during synthesis, different nanorod sizes, nanosheets textures and ZnO layers were obtained. The ZnO-loaded honeycombs were characterized using FESEM, EDX and XRD indicating that the immobilized layer of nanostructured ZnO was highly-crystalline with a thickness of ∼1µm. The synthesized nanostructured ZnO-loaded honeycombs and a commercial ZnO sorbent were applied for removal of sulfur compounds (H2S and COS) from syngas at 400°C. The ZnO-nS showed significantly longer breakthrough time (BTTS) and higher total sulfur sorption capacity (48.7mgg−1 ZnO, BTTS=75.4min) than the ZnO-nR (9–12mgg−1 ZnO, BTTS=23–25min) and commercial ZnO sorbent (4.6mgg−1 ZnO, BTTS=6.8min). The superior sorption capacity of ZnO-nS was attributed to the significantly better surface coverage and higher crystallinity of ZnO nanosheets on the honeycomb. The introduction of additional ZnO nanosheets layers (up to 3 layers) through repeated growth process increased the ZnO loading to ∼1.5±0.1mgmm−1 (from ∼0.9±0.1mgmm−1 in the single layer) but resulted in poorer performance (11.6mgg−1 ZnO, BTTS=24.6min) compared to ZnO-nS. This was due to the increased internal mass transfer resistance and decreased density of the effective reactive sites. The mechanism of ZnO-nS formation is also proposed to provide further insights. Overall, the ZnO-nS showed better regenerability, lower mass transfer resistance, and higher sorption capacity compared to the commercial ZnO and ZnO-nR sorbents indicating that it has a promising potential for syngas desulfurization.</abstract><cop>Kidlington</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.fuel.2017.09.088</doi><tpages>9</tpages><orcidid>https://orcid.org/0000-0003-4647-0342</orcidid><orcidid>https://orcid.org/0000-0003-4230-9092</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Cordierite Crystal structure Crystallinity Desulfurization Desulfurizing Gasification H2S removal Heat transfer Hexamethylenetetramine Honeycomb Honeycomb construction Honeycombs Hydrogen sulfide Mass transfer Morphology Mullite Nanorods Nanostructure Nanostructured materials Nanostructured ZnO Scanning electron microscopy Sorbents Sorption Studies Sulfur Sulfur compounds Syngas Synthesis gas Synthetic fuels Zinc Zinc oxide ZnO nanosheets
title	Influence of surface morphology on the performance of nanostructured ZnO-loaded ceramic honeycomb for syngas desulfurization
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