Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor

Studies on the preparation of activated carbon derived from agricultural waste; desiccated coconut residue (DCR); the grated coconut residue left after the extraction of milk, for electrode material in electric double layer capacitor (EDLC) were conducted. The preparation of activated carbon (AC)...

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Main Author: Mohd Adib bin Yahya
Format: Thesis
Language:en_US
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id my-usim-ddms-13090
record_format uketd_dc
institution Universiti Sains Islam Malaysia
collection USIM Institutional Repository
language en_US
topic Carbon
Activated--Recycling--Case studies.
Carbon
Activated--Recycling--Case studies.
Carbon
Activated--Recycling--Case studies.
spellingShingle Carbon
Activated--Recycling--Case studies.
Carbon
Activated--Recycling--Case studies.
Carbon
Activated--Recycling--Case studies.
Mohd Adib bin Yahya
Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor
description Studies on the preparation of activated carbon derived from agricultural waste; desiccated coconut residue (DCR); the grated coconut residue left after the extraction of milk, for electrode material in electric double layer capacitor (EDLC) were conducted. The preparation of activated carbon (AC) involves chemical activations with sodium hydroxide (NaOH) and potassium hydroxide (KOH) to the charred DCR. The effects of temperature and impregnation ratio on the physicochemical properties of AC prepared were also investigated. DCR sample was first carbonized for 1 hour at three different temperatures; 400°C, 500°C, and 600°C respectively. The resulting chars were impregnated with NaOH and KOH at three different impregnation ratio (IR); 1: 1,1: 2, and 1: 3 respectively followed by further activation under nitrogen atmosphere for 1 hour at the respective carbonization temperatures. The prepared ACs were characterized by Brunauer-Emmett-Teller (BET) surface area (SBET), bulk density, ultimate analysis, scanning electron microscopy (SEM), and yield. Results show both NaOH and KOH treatments resulted in different effects on the resulting ACs particularly on SBET. NaOH derived activated carbon (NAC) was strongly affected by IR while KOH derived activated carbon (KAC) was strongly affected by temperature. For NAC, the SBET increased with the increased in IR while for KAC the SBET increased with increasing temperature. The SBET of the prepared ACs was in the order: NAC3: 500 > NAC3: 600 > NAC2: 500 > NAC2: 600 > NAC1: 500 > NAC1: 600 > NAC2: 400 > NAC3: 400 > NAC 1: 400 and KAC2: 600 > KAC3: 600 > KAC2: 500 > KAC3: 500 > KACI: 600 > KAC 1: 500 > KAC2: 400 > KAC 1: 400 > KAC3: 400, respectively. The highest SBET for NAC and KAC were found to be 1394.79 m2/g and 823.81 m2/g, with total pore volume (Vi) of 0.78 and 0.50 cm3/g respectively. In general, ACs produced were microporous in characteristic and both activating agents and temperature were found to be important factors in developing microporosity properties of both ACs. Under SEM observation, the selected NAC and KAC had shown a wide variety of pores with honey-comb like structure which resulted from porosity developments. The highest SBET from both NAC and KAC were selected for studying the AC as electrode material in EDLC. Selected ACs were further studied under X-Ray Diffraction (XRD), Raman spectroscopy, Energy Dispersive X-Ray (EDX), and X-ray Photoelectron Spectroscopy (XPS). Under XRD analysis, results show both NAC and KAC were found to have turbostratic structures with amorphous characters and disordered structures. The different values of both interlayer spacing (d002 and d100) and microcrystallite dimensions (Lc and La) were attributed to the activation temperature used in AC preparations. KAC was found to have higher degree graphitization and lower degree of disordered as compared to NAC under Raman spectroscopy analysis. Under EDX and XPS analyses, results indicate that NAC had double amount of oxygen functional groups in comparison with KAC. For EDLC fabrications, the EDLCs derived from NAC and KAC was characterized by cyclic voltammetry and charge-discharge with potential window of IV using aqueous electrolytes. Two types of current collectors were applied namely; aluminium foil and stainless steel foil. For aluminium foil, only aqueous electrolyte of IM Na2SO4 were used to fabricate EDLC, whereas for stainless steel foil, three types of electrolytes were utilized; IM H2SO4, IM Na2SO4 and 6M KOH. Results showed that for IM Na2SO4 electrolyte, both NAC and KAC showed similar trends for both types of current collectors in which KAC had shown larger specific capacitance (SC) as compared to NAC even though the SBET of NAC was greater than that of KAC. It was suggested that ion sieving effects had resulted in lower specific capacitance in NAC. Nevertheless, for IM H2SO4 and 6M KOH electrolytes, NAC had shown higher specific capacitance than that of KAC. Factors such as surface functional groups, molar conductivities, size of electrolyte ions have resulted in higher specific capacitance in NAC. NAC had two times oxygen functional groups compared to KAC which could improve the wettability of between NAC electrode surface and electrolytes. The specific capacitance were in the order of 6M KOH > IM H2SO4 > 1M Na2SO4 for both NAC and KAC. Nevertheless, results showed that KAC had better cycle stability than that of NAC due to higher contents of oxygen functional groups that deteriorated the electrodes in NAC. Finally, EDLC derived from DCR was found to exhibit excellent EDLC behaviour in terms of specific capacitance and cycle stability.
format Thesis
author Mohd Adib bin Yahya
author_facet Mohd Adib bin Yahya
author_sort Mohd Adib bin Yahya
title Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor
title_short Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor
title_full Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor
title_fullStr Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor
title_full_unstemmed Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor
title_sort activated carbon derived from desiccated coconut residue as electrode material for electric doublelayer capacitor
granting_institution Universiti Sains Islam Malaysia
_version_ 1812444669011820544
spelling my-usim-ddms-130902024-05-29T05:32:55Z Activated Carbon Derived From Desiccated Coconut Residue As Electrode Material For Electric Doublelayer Capacitor Mohd Adib bin Yahya Studies on the preparation of activated carbon derived from agricultural waste; desiccated coconut residue (DCR); the grated coconut residue left after the extraction of milk, for electrode material in electric double layer capacitor (EDLC) were conducted. The preparation of activated carbon (AC) involves chemical activations with sodium hydroxide (NaOH) and potassium hydroxide (KOH) to the charred DCR. The effects of temperature and impregnation ratio on the physicochemical properties of AC prepared were also investigated. DCR sample was first carbonized for 1 hour at three different temperatures; 400°C, 500°C, and 600°C respectively. The resulting chars were impregnated with NaOH and KOH at three different impregnation ratio (IR); 1: 1,1: 2, and 1: 3 respectively followed by further activation under nitrogen atmosphere for 1 hour at the respective carbonization temperatures. The prepared ACs were characterized by Brunauer-Emmett-Teller (BET) surface area (SBET), bulk density, ultimate analysis, scanning electron microscopy (SEM), and yield. Results show both NaOH and KOH treatments resulted in different effects on the resulting ACs particularly on SBET. NaOH derived activated carbon (NAC) was strongly affected by IR while KOH derived activated carbon (KAC) was strongly affected by temperature. For NAC, the SBET increased with the increased in IR while for KAC the SBET increased with increasing temperature. The SBET of the prepared ACs was in the order: NAC3: 500 > NAC3: 600 > NAC2: 500 > NAC2: 600 > NAC1: 500 > NAC1: 600 > NAC2: 400 > NAC3: 400 > NAC 1: 400 and KAC2: 600 > KAC3: 600 > KAC2: 500 > KAC3: 500 > KACI: 600 > KAC 1: 500 > KAC2: 400 > KAC 1: 400 > KAC3: 400, respectively. The highest SBET for NAC and KAC were found to be 1394.79 m2/g and 823.81 m2/g, with total pore volume (Vi) of 0.78 and 0.50 cm3/g respectively. In general, ACs produced were microporous in characteristic and both activating agents and temperature were found to be important factors in developing microporosity properties of both ACs. Under SEM observation, the selected NAC and KAC had shown a wide variety of pores with honey-comb like structure which resulted from porosity developments. The highest SBET from both NAC and KAC were selected for studying the AC as electrode material in EDLC. Selected ACs were further studied under X-Ray Diffraction (XRD), Raman spectroscopy, Energy Dispersive X-Ray (EDX), and X-ray Photoelectron Spectroscopy (XPS). Under XRD analysis, results show both NAC and KAC were found to have turbostratic structures with amorphous characters and disordered structures. The different values of both interlayer spacing (d002 and d100) and microcrystallite dimensions (Lc and La) were attributed to the activation temperature used in AC preparations. KAC was found to have higher degree graphitization and lower degree of disordered as compared to NAC under Raman spectroscopy analysis. Under EDX and XPS analyses, results indicate that NAC had double amount of oxygen functional groups in comparison with KAC. For EDLC fabrications, the EDLCs derived from NAC and KAC was characterized by cyclic voltammetry and charge-discharge with potential window of IV using aqueous electrolytes. Two types of current collectors were applied namely; aluminium foil and stainless steel foil. For aluminium foil, only aqueous electrolyte of IM Na2SO4 were used to fabricate EDLC, whereas for stainless steel foil, three types of electrolytes were utilized; IM H2SO4, IM Na2SO4 and 6M KOH. Results showed that for IM Na2SO4 electrolyte, both NAC and KAC showed similar trends for both types of current collectors in which KAC had shown larger specific capacitance (SC) as compared to NAC even though the SBET of NAC was greater than that of KAC. It was suggested that ion sieving effects had resulted in lower specific capacitance in NAC. Nevertheless, for IM H2SO4 and 6M KOH electrolytes, NAC had shown higher specific capacitance than that of KAC. Factors such as surface functional groups, molar conductivities, size of electrolyte ions have resulted in higher specific capacitance in NAC. NAC had two times oxygen functional groups compared to KAC which could improve the wettability of between NAC electrode surface and electrolytes. The specific capacitance were in the order of 6M KOH > IM H2SO4 > 1M Na2SO4 for both NAC and KAC. Nevertheless, results showed that KAC had better cycle stability than that of NAC due to higher contents of oxygen functional groups that deteriorated the electrodes in NAC. Finally, EDLC derived from DCR was found to exhibit excellent EDLC behaviour in terms of specific capacitance and cycle stability. Universiti Sains Islam Malaysia 2016-03 Thesis en_US https://oarep.usim.edu.my/handle/123456789/13090 https://oarep.usim.edu.my/bitstreams/5fcfd741-f825-4711-98ea-974898df68f0/download 8a4605be74aa9ea9d79846c1fba20a33 Carbon, Activated--Recycling--Case studies. Carbon, Activated--Industrial applications--Case studies. Desiccated coconut residue, chemical activation.