Effect of Graphene Oxide Thin Film on Growth and Electrochemical Performance of Hierarchical Zinc Sulfide Nanoweb for Supercapacitor Applications

MF Iqbal; Mahmood-Ul-Hassan; A Razaq; MN Ashiq; YV Kaneti; AA Azhar; F Yasmeen; Khurram Saleem Joya; S Abbass

Effect of Graphene Oxide Thin Film on Growth and Electrochemical Performance of Hierarchical Zinc Sulfide Nanoweb for Supercapacitor Applications

MF Iqbal, Mahmood-Ul-Hassan, A Razaq, MN Ashiq, YV Kaneti, AA Azhar, F Yasmeen, Khurram Saleem Joya, S Abbass

King Fahd University of Petroleum & Minerals

Research output: Contribution to journal › Article › peer-review

41 Scopus citations

Abstract

Surface morphology induced electrical conductivity and specific surface area of a material play a significant role to facilitate electrochemical behavior for supercapacitor application. Therefore, the synthesis step for controlling such parameters becomes very imperative and challenging. Herein, a ZnS nanoweb is deposited directly onto Ni foam with a pre-deposited thin layer of hydrothermally prepared graphene oxide. The structure and surface morphology of the deposited ZnS is observed using XRD and SEM, respectively. The electrical conductivity of the graphene oxide supported ZnS nanoweb, determined using the four probes method, is 100.15 Scm(-1). The specific surface area is 104.42 m(2)g(-1) as determined by BET measurements. Pseudocapacitive behavior is monitored by cyclic voltammetry, and the excellent specific capacity of 3052 Fg(-1) has been found at a scan rate of 2 mVs(-1), while it is 2400.30 Fg(-1) according the galvanostatic charge-discharge profile at a current density of 3

Original language	English
Journal	WILEY-V C H VERLAG GMBH
State	Published - 2018

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@article{40c9b60aeef745809dddef5b155e1e46,

title = "Effect of Graphene Oxide Thin Film on Growth and Electrochemical Performance of Hierarchical Zinc Sulfide Nanoweb for Supercapacitor Applications",

abstract = "Surface morphology induced electrical conductivity and specific surface area of a material play a significant role to facilitate electrochemical behavior for supercapacitor application. Therefore, the synthesis step for controlling such parameters becomes very imperative and challenging. Herein, a ZnS nanoweb is deposited directly onto Ni foam with a pre-deposited thin layer of hydrothermally prepared graphene oxide. The structure and surface morphology of the deposited ZnS is observed using XRD and SEM, respectively. The electrical conductivity of the graphene oxide supported ZnS nanoweb, determined using the four probes method, is 100.15 Scm(-1). The specific surface area is 104.42 m(2)g(-1) as determined by BET measurements. Pseudocapacitive behavior is monitored by cyclic voltammetry, and the excellent specific capacity of 3052 Fg(-1) has been found at a scan rate of 2 mVs(-1), while it is 2400.30 Fg(-1) according the galvanostatic charge-discharge profile at a current density of 3",

author = "MF Iqbal and Mahmood-Ul-Hassan and A Razaq and MN Ashiq and YV Kaneti and AA Azhar and F Yasmeen and Joya, \{Khurram Saleem\} and S Abbass",

year = "2018",

language = "English",

}

TY - JOUR

T1 - Effect of Graphene Oxide Thin Film on Growth and Electrochemical Performance of Hierarchical Zinc Sulfide Nanoweb for Supercapacitor Applications

AU - Iqbal, MF

AU - Mahmood-Ul-Hassan, null

AU - Razaq, A

AU - Ashiq, MN

AU - Kaneti, YV

AU - Azhar, AA

AU - Yasmeen, F

AU - Joya, Khurram Saleem

AU - Abbass, S

PY - 2018

Y1 - 2018

N2 - Surface morphology induced electrical conductivity and specific surface area of a material play a significant role to facilitate electrochemical behavior for supercapacitor application. Therefore, the synthesis step for controlling such parameters becomes very imperative and challenging. Herein, a ZnS nanoweb is deposited directly onto Ni foam with a pre-deposited thin layer of hydrothermally prepared graphene oxide. The structure and surface morphology of the deposited ZnS is observed using XRD and SEM, respectively. The electrical conductivity of the graphene oxide supported ZnS nanoweb, determined using the four probes method, is 100.15 Scm(-1). The specific surface area is 104.42 m(2)g(-1) as determined by BET measurements. Pseudocapacitive behavior is monitored by cyclic voltammetry, and the excellent specific capacity of 3052 Fg(-1) has been found at a scan rate of 2 mVs(-1), while it is 2400.30 Fg(-1) according the galvanostatic charge-discharge profile at a current density of 3

AB - Surface morphology induced electrical conductivity and specific surface area of a material play a significant role to facilitate electrochemical behavior for supercapacitor application. Therefore, the synthesis step for controlling such parameters becomes very imperative and challenging. Herein, a ZnS nanoweb is deposited directly onto Ni foam with a pre-deposited thin layer of hydrothermally prepared graphene oxide. The structure and surface morphology of the deposited ZnS is observed using XRD and SEM, respectively. The electrical conductivity of the graphene oxide supported ZnS nanoweb, determined using the four probes method, is 100.15 Scm(-1). The specific surface area is 104.42 m(2)g(-1) as determined by BET measurements. Pseudocapacitive behavior is monitored by cyclic voltammetry, and the excellent specific capacity of 3052 Fg(-1) has been found at a scan rate of 2 mVs(-1), while it is 2400.30 Fg(-1) according the galvanostatic charge-discharge profile at a current density of 3

M3 - Article

SN - 2196-0216

JO - WILEY-V C H VERLAG GMBH

JF - WILEY-V C H VERLAG GMBH

ER -

Effect of Graphene Oxide Thin Film on Growth and Electrochemical Performance of Hierarchical Zinc Sulfide Nanoweb for Supercapacitor Applications

Abstract

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