Open Access. Powered by Scholars. Published by Universities.®
- Keyword
-
- Biodiesel; castor oil; simulation; yield; transesterification (1)
- Co-electrodeposition; Fuel cells; Pt-Cu; Catalyst poisoning; Formic acid (1)
- Fuel cells; Electrocatalysis; Methanol electro-oxidation; Formic acid electro-oxidation; Ethylene glycol electro-oxidation (1)
- Pd-Au; Co-electrodeposition; Fuel Cells; Formic acid oxidation; Poisoning (1)
- Poisoning; Formic acid; Cobalt oxide; Gold; Platinum; Fuel cells (1)
Articles 1 - 6 of 6
Full-Text Articles in Engineering
Augmented Formic Acid Electro-Oxidation At A Co-Electrodeposited Pd/Au Nanoparticle Catalyst, Yaser M. Asal, Ahmad M. Mohammad, Sayed S. Abd El Rehim, Islam M. Al-Akraa
Augmented Formic Acid Electro-Oxidation At A Co-Electrodeposited Pd/Au Nanoparticle Catalyst, Yaser M. Asal, Ahmad M. Mohammad, Sayed S. Abd El Rehim, Islam M. Al-Akraa
Chemical Engineering
In this study, the formic acid electro-oxidation reaction (FAEOR) was catalyzed on a Pd-Au co-electrodeposited binary catalyst. The kinetics of FAEOR were intensively impacted by changing the Pd2+:Au3+ molar ratio in the deposition medium. The Pd1-Au1 catalyst (for which the Pd2+:Au3+ molar ratio was 1:1) acquired the highest activity with a peak current density for the direct FAEOR (Ip) of 4.14 mA cm−2 (ca. 13- times higher than that (ca. 0.33 mA cm−2) of the pristine Pd1-Au0 catalyst). It also retained the highest stability that was denoted in fulfilling ca. 0.292 mA cm−2 (ca. 19-times higher than 0.015 …
Surface Engineering Of Pt Surfaces With Au And Cobalt Oxide Nanostructures For Enhanced Formic Acid Electro-Oxidation, Yaser M. Asal, Islam M. Al-Akraa, Ahmad M. Mohammad
Surface Engineering Of Pt Surfaces With Au And Cobalt Oxide Nanostructures For Enhanced Formic Acid Electro-Oxidation, Yaser M. Asal, Islam M. Al-Akraa, Ahmad M. Mohammad
Chemical Engineering
This study aims to mitigate the CO poisoning of platinum (Pt) surfaces during formic acid electro-oxidation (FAEO), the essential anodic reaction in the direct formic acid fuel cells (DFAFCs). For this purpose, a glassy carbon (GC) electrode was amended sequentially with Pt (n-Pt), gold (n-Au), and cobalt oxide (n-CoOx) nanostructures. Fascinatingly, the ternary modified n-CoOx/n-Au/n-Pt/GC catalyst (for which n-Pt, n-Au, and n-CoOx were sequentially and respectively assembled onto the GC surface) exhibited a remarkable electrocatalytic enhancement toward FAEO, which surpassed ca. 53 times that of the Pt/GC catalyst. Additionally, it exhibited a much (ca. 18 times) higher stability after 3000 …
Effect Of Palladium Loading On Catalytic Properties Of Pd/Gce For The Electro-Oxidation Of Methanol, Formic Acid, And Ethylene Glycol, Islam M. Al-Akraa, Yaser M. Asal, Sohir A. Darwish, Rafik M. Fikry, Reem H. Mahmoud, Mohamed Hassan, Ahmad M. Mohammad
Effect Of Palladium Loading On Catalytic Properties Of Pd/Gce For The Electro-Oxidation Of Methanol, Formic Acid, And Ethylene Glycol, Islam M. Al-Akraa, Yaser M. Asal, Sohir A. Darwish, Rafik M. Fikry, Reem H. Mahmoud, Mohamed Hassan, Ahmad M. Mohammad
Chemical Engineering
This study investigates the influence of the catalyst (Palladium, Pd) mass that loaded onto a glassy carbon electrode (GCE) on the catalytic activity of methanol (MEO), formic acid (FAEO), and ethylene glycol (EGEO) electro-oxidation, the corresponding principal anodic reactions in the direct methanol (DMFCs), formic acid (DFAFCs), and ethylene glycol (DEGFCs) fuel cells, respectively. By increasing the Pd loading at 0.1 V, the Pd surface area increased from 0.55 cm2 (2 min Pd deposition) to 1.94 cm2 (25 min Pd deposition) which increased the peak currents (IP) of MEO (from 0.181 to 0.608 mA), FAEO (from 0.236 to …
A Competent Mwcnt-Grafted Mnox/Pt Nanoanode For The Direct Formic Acid Fuel Cells, Islam M. Al-Akraa, Mamdouh M. Moutaz, Ahmad M. Mohammad, Yaser M. Asal
A Competent Mwcnt-Grafted Mnox/Pt Nanoanode For The Direct Formic Acid Fuel Cells, Islam M. Al-Akraa, Mamdouh M. Moutaz, Ahmad M. Mohammad, Yaser M. Asal
Chemical Engineering
A novel “MnOx/Pt/MWCNT-GC” nanocatalyst is recommended for the electrooxidation of formic acid (EOFA), the principal anodic reaction in the direct formic acid fuel cells (DFAFCs). The sequential (layer-by-layer) protocol was employed to prepare the catalyst through the electrodeposition of Pt (nano-Pt) and manganese oxide (nano-MnOx) nanoparticles onto the surface of a glassy carbon (GC) electrode supported with multiwalled carbon nanotubes (MWCNTs). The nano-MnOx could successfully mediate the mechanism of EOFA by accelerating the charge transfer, “electronic effect”. On the other hand, MWCNTs could enhance the catalytic performance by changing the surface geometry that inhibited the adsorption of poisoning CO, which …
Synergistic Enhancement Of Formic Acid Electro-Oxidation On Ptxcuy Co-Electrodeposited Binary Catalysts, Yaser M. Asal, Ahmad M. Mohammad, Sayed S. Abd El Rehim, Islam M. Al-Akraa
Synergistic Enhancement Of Formic Acid Electro-Oxidation On Ptxcuy Co-Electrodeposited Binary Catalysts, Yaser M. Asal, Ahmad M. Mohammad, Sayed S. Abd El Rehim, Islam M. Al-Akraa
Chemical Engineering
A propitious binary catalyst composed of Pt and Cu which were electrodeposited simultaneously onto a glassy carbon (GC) substrate was recommended for the formic acid (FA) electro-oxidation reaction (FAOR); the principal anodic reaction in the direct FA fuel cells (DFAFCs). The simultaneous co-electrodeposition of Pt and Cu in the catalyst provided an opportunity to tune the geometric functionality of the catalyst to resist the adsorption of poisoning CO at the Pt surface that represented the major impediment for DFAFCs marketing. The catalytic activity of the catalyst toward FAOR was significantly influenced by the (Pt4+/Cu2+) molar ratio of the electrolyte during …
Castor Oil Conversion To Biodiesel: A Process Simulation Study, Islam M. Al-Akraa, Ahmad M. Mohammad, Yaser M. Asal, Razan Aymen
Castor Oil Conversion To Biodiesel: A Process Simulation Study, Islam M. Al-Akraa, Ahmad M. Mohammad, Yaser M. Asal, Razan Aymen
Chemical Engineering
The aim of this study is to highlights the importance to shift from the use of traditional fossil fuels to biodiesel as a clean energy source. A simulation study has been conducted using ASPEN HYSIS software for the biodiesel production form castor oil. The simulation was run and the properties of the produced biodiesel were highlighted. The optimum conditions resulted in 88 % conversion.