Graphite felt incorporated with MoS2/rGO for electrochemical detoxification of high-arsenic fly ash

Yang Luo; Yinghong Wu; Chao Huang; Dezhi Xiao; Lizhai Zhang; Shuhua Ma; Jingkui Qu; Shili Zheng; Paul K. Chu

Graphite felt incorporated with MoS₂/rGO for electrochemical detoxification of high-arsenic fly ash

Yang Luo^*
, Yinghong Wu
, Chao Huang
, Dezhi Xiao
, Lizhai Zhang
, Shuhua Ma
, Jingkui Qu
, Shili Zheng
, Paul K. Chu

^*Corresponding author for this work

Research output: Conference Papers › RGC 32 - Refereed conference paper (without host publication) › peer-review

Abstract

1. Introduction – Accumulation of high-arsenic fly ash (HAFA) poses a serious environmental threat due to the toxicity. As(III) oxidation is a necessary step for HAFA detoxification and in situ H₂O₂ electrogeneration via the two-electron-pathway (2e^-) oxygen reduction reaction (ORR) is considered a promising technique for As(III) oxidation [1, 2]. MoS₂ has been reported to have attractive 2e^- ORR catalytic activity [3]. However, there are still some problems to be solved: (i) its conductivity needs to be improved, (ii) gaseous O₂ is difficult to be effectively utilized, and (iii) the assembled electrode is not flexible and durable enough to treat solid waste.
2. Experimental - the experimental flow is schematically illustrated in Image. 1.
3. Results and Discussion - A novel graphite felt (GF) modified with the MoS₂/reduced graphene oxide (rGO) heterojunction is developed and demonstrated as an efficient electrode for electrochemical detoxification of HAFA, as shown in Image 2(a). The modified GF has abundant microchannels (Image 2(b)), desirable surface properties, and fast electron transfer capability thereby enabling effective utilization of both dissolved O₂ and gaseous O₂ in 2e^- ORR. The p-n junction consists of the p-type rGO substrate and uniformly distributed n-type MoS₂ nanoflowers, seeing Images 2(c) and 2(d). Theoretical calculation indicates that gaseous O₂ adsorb stably on sulfur vacancies and is reduced by electrons transferred from rGO. The modified GF exhibits superior ORR catalytic activity such as a high H₂O₂ yield of 47.53 mg·L^-1·h¹·cm^-1 (Image 2(e)) and onset potential of -0.12 V vs. SCE. The ·OH generated by the autocatalytic mechanism promotes oxidative dissolution of As(III) during detoxification of HAFA and the As removal percentage is 96.10% after electrolysis for 135 min, displayed in Images 2(f) and 2(g). The modified GF with excellent stability and durability has large industrial potential in detoxification of HAFA and other As-bearing hazardous wastes.
4. Conclusions - This study makes significant contributions. Firstly, the gaseous O₂ reaction path in ORR is confirmed by the combination of experiment and calculation. Secondly, 2e ORR is innovatively applied to detoxification of high-arsenic solid waste.

Original language	English
Publication status	Published - Jul 2019
Event	2019 International Conference on Green Energy and Environmental Technology, GEET 19 - Université París 8, Paris, France Duration: 24 Jul 2019 → 26 Jul 2019 http://geet-19.com/

Conference

Conference	2019 International Conference on Green Energy and Environmental Technology, GEET 19
Abbreviated title	GEET 19
Place	France
City	Paris
Period	24/07/19 → 26/07/19
Internet address	http://geet-19.com/

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@conference{a7e434012f534a6ca4dccf81c9810575,

title = "Graphite felt incorporated with MoS2/rGO for electrochemical detoxification of high-arsenic fly ash",

abstract = "1. Introduction – Accumulation of high-arsenic fly ash (HAFA) poses a serious environmental threat due to the toxicity. As(III) oxidation is a necessary step for HAFA detoxification and in situ H2O2 electrogeneration via the two-electron-pathway (2e-) oxygen reduction reaction (ORR) is considered a promising technique for As(III) oxidation [1, 2]. MoS2 has been reported to have attractive 2e- ORR catalytic activity [3]. However, there are still some problems to be solved: (i) its conductivity needs to be improved, (ii) gaseous O2 is difficult to be effectively utilized, and (iii) the assembled electrode is not flexible and durable enough to treat solid waste. 2. Experimental - the experimental flow is schematically illustrated in Image. 1. 3. Results and Discussion - A novel graphite felt (GF) modified with the MoS2/reduced graphene oxide (rGO) heterojunction is developed and demonstrated as an efficient electrode for electrochemical detoxification of HAFA, as shown in Image 2(a). The modified GF has abundant microchannels (Image 2(b)), desirable surface properties, and fast electron transfer capability thereby enabling effective utilization of both dissolved O2 and gaseous O2 in 2e- ORR. The p-n junction consists of the p-type rGO substrate and uniformly distributed n-type MoS2 nanoflowers, seeing Images 2(c) and 2(d). Theoretical calculation indicates that gaseous O2 adsorb stably on sulfur vacancies and is reduced by electrons transferred from rGO. The modified GF exhibits superior ORR catalytic activity such as a high H2O2 yield of 47.53 mg·L-1·h1·cm-1 (Image 2(e)) and onset potential of -0.12 V vs. SCE. The ·OH generated by the autocatalytic mechanism promotes oxidative dissolution of As(III) during detoxification of HAFA and the As removal percentage is 96.10\% after electrolysis for 135 min, displayed in Images 2(f) and 2(g). The modified GF with excellent stability and durability has large industrial potential in detoxification of HAFA and other As-bearing hazardous wastes. 4. Conclusions - This study makes significant contributions. Firstly, the gaseous O2 reaction path in ORR is confirmed by the combination of experiment and calculation. Secondly, 2e ORR is innovatively applied to detoxification of high-arsenic solid waste. ",

author = "Yang Luo and Yinghong Wu and Chao Huang and Dezhi Xiao and Lizhai Zhang and Shuhua Ma and Jingkui Qu and Shili Zheng and Chu, \{Paul K.\}",

note = "Author(s) information for this publication is provided by the author(s) concerned.; 2019 International Conference on Green Energy and Environmental Technology, GEET 19, GEET 19 ; Conference date: 24-07-2019 Through 26-07-2019",

year = "2019",

month = jul,

language = "English",

url = "http://geet-19.com/",

}

Graphite felt incorporated with MoS₂/rGO for electrochemical detoxification of high-arsenic fly ash. / Luo, Yang ; Wu, Yinghong ; Huang, Chao et al.
2019. Paper presented at 2019 International Conference on Green Energy and Environmental Technology, GEET 19, Paris, France.

Research output: Conference Papers › RGC 32 - Refereed conference paper (without host publication) › peer-review

TY - CONF

T1 - Graphite felt incorporated with MoS2/rGO for electrochemical detoxification of high-arsenic fly ash

AU - Luo, Yang

AU - Wu, Yinghong

AU - Huang, Chao

AU - Xiao, Dezhi

AU - Zhang, Lizhai

AU - Ma, Shuhua

AU - Qu, Jingkui

AU - Zheng, Shili

AU - Chu, Paul K.

N1 - Author(s) information for this publication is provided by the author(s) concerned.

PY - 2019/7

Y1 - 2019/7

N2 - 1. Introduction – Accumulation of high-arsenic fly ash (HAFA) poses a serious environmental threat due to the toxicity. As(III) oxidation is a necessary step for HAFA detoxification and in situ H2O2 electrogeneration via the two-electron-pathway (2e-) oxygen reduction reaction (ORR) is considered a promising technique for As(III) oxidation [1, 2]. MoS2 has been reported to have attractive 2e- ORR catalytic activity [3]. However, there are still some problems to be solved: (i) its conductivity needs to be improved, (ii) gaseous O2 is difficult to be effectively utilized, and (iii) the assembled electrode is not flexible and durable enough to treat solid waste. 2. Experimental - the experimental flow is schematically illustrated in Image. 1. 3. Results and Discussion - A novel graphite felt (GF) modified with the MoS2/reduced graphene oxide (rGO) heterojunction is developed and demonstrated as an efficient electrode for electrochemical detoxification of HAFA, as shown in Image 2(a). The modified GF has abundant microchannels (Image 2(b)), desirable surface properties, and fast electron transfer capability thereby enabling effective utilization of both dissolved O2 and gaseous O2 in 2e- ORR. The p-n junction consists of the p-type rGO substrate and uniformly distributed n-type MoS2 nanoflowers, seeing Images 2(c) and 2(d). Theoretical calculation indicates that gaseous O2 adsorb stably on sulfur vacancies and is reduced by electrons transferred from rGO. The modified GF exhibits superior ORR catalytic activity such as a high H2O2 yield of 47.53 mg·L-1·h1·cm-1 (Image 2(e)) and onset potential of -0.12 V vs. SCE. The ·OH generated by the autocatalytic mechanism promotes oxidative dissolution of As(III) during detoxification of HAFA and the As removal percentage is 96.10% after electrolysis for 135 min, displayed in Images 2(f) and 2(g). The modified GF with excellent stability and durability has large industrial potential in detoxification of HAFA and other As-bearing hazardous wastes. 4. Conclusions - This study makes significant contributions. Firstly, the gaseous O2 reaction path in ORR is confirmed by the combination of experiment and calculation. Secondly, 2e ORR is innovatively applied to detoxification of high-arsenic solid waste.

AB - 1. Introduction – Accumulation of high-arsenic fly ash (HAFA) poses a serious environmental threat due to the toxicity. As(III) oxidation is a necessary step for HAFA detoxification and in situ H2O2 electrogeneration via the two-electron-pathway (2e-) oxygen reduction reaction (ORR) is considered a promising technique for As(III) oxidation [1, 2]. MoS2 has been reported to have attractive 2e- ORR catalytic activity [3]. However, there are still some problems to be solved: (i) its conductivity needs to be improved, (ii) gaseous O2 is difficult to be effectively utilized, and (iii) the assembled electrode is not flexible and durable enough to treat solid waste. 2. Experimental - the experimental flow is schematically illustrated in Image. 1. 3. Results and Discussion - A novel graphite felt (GF) modified with the MoS2/reduced graphene oxide (rGO) heterojunction is developed and demonstrated as an efficient electrode for electrochemical detoxification of HAFA, as shown in Image 2(a). The modified GF has abundant microchannels (Image 2(b)), desirable surface properties, and fast electron transfer capability thereby enabling effective utilization of both dissolved O2 and gaseous O2 in 2e- ORR. The p-n junction consists of the p-type rGO substrate and uniformly distributed n-type MoS2 nanoflowers, seeing Images 2(c) and 2(d). Theoretical calculation indicates that gaseous O2 adsorb stably on sulfur vacancies and is reduced by electrons transferred from rGO. The modified GF exhibits superior ORR catalytic activity such as a high H2O2 yield of 47.53 mg·L-1·h1·cm-1 (Image 2(e)) and onset potential of -0.12 V vs. SCE. The ·OH generated by the autocatalytic mechanism promotes oxidative dissolution of As(III) during detoxification of HAFA and the As removal percentage is 96.10% after electrolysis for 135 min, displayed in Images 2(f) and 2(g). The modified GF with excellent stability and durability has large industrial potential in detoxification of HAFA and other As-bearing hazardous wastes. 4. Conclusions - This study makes significant contributions. Firstly, the gaseous O2 reaction path in ORR is confirmed by the combination of experiment and calculation. Secondly, 2e ORR is innovatively applied to detoxification of high-arsenic solid waste.

M3 - RGC 32 - Refereed conference paper (without host publication)

T2 - 2019 International Conference on Green Energy and Environmental Technology, GEET 19

Y2 - 24 July 2019 through 26 July 2019

ER -