Monday, August 5, 2019
Development of Magnesium-Hydrogen Peroxide Fuel Cell
Development of Magnesium-Hydrogen Peroxide Fuel Cell Performance of Carbon felt cathode for Magnesiumââ¬âHydrogen peroxide fuel cells K. Naga Mahesh, Balaji Rengarajan, K.S. Dhathathreyan* Centre for Fuel Cell Technology, International Advanced Research Centre for Powder Metallurgy and New Materials (ARCI), 2nd Floor, IITM Research Park, Taramani, Chennaiââ¬â600113. Abstract Carbon felt and carbon cloth are used as a cathode in Magnesium-Hydrogen peroxide fuel cell. The performance of the cathode are tested in a 30 cm2 area single cell assembly along with 0.68M NaCl as anolyte and 0.5M to 2M H2O2 + H2SO4 solution as catholyte. The cell was tested in different concentration of the reactants and at temperatures 35 to 70à °C. Carbon felt cathode was shown better performance than carbon cloth. The maximum current density achieved at cell voltage 1.11V was 80 mA cm-2. Keywords: Mg-H2O2 fuel cell, Carbon felt, Carbon cloth, hydrogen peroxide, Corresponding author* Dr. K.S. Dhathathreyan, Head and Associate Director, Centre for Fuel Cell Technology, International Advanced Research Centre for Powder Metallurgy and New Materials (ARCI), 2nd Floor, IITM Research Park, Taramani, Chennaiââ¬â600113. Ph: +91ââ¬â44ââ¬â6663 2723 Email: [emailprotected] Introduction Electrochemical systems based on Magnesiumââ¬âhydrogen peroxide fuel cells (Mgââ¬âH2O2) have high specific energy and are capable of converting chemical energy stored in magnesium and hydrogen peroxide to electrical energy [7]. Recently, much attention was focused due to its high theoretical voltage compared to existing semi fuel cells like Aluminumââ¬âsilver oxide (Alââ¬âAgO) [1] or Aluminumââ¬âhydrogen peroxide (Alââ¬â H2O2) [2,3]. The Mgââ¬âH2O2 fuel cell has a theoretical voltage of 4.14V which is higher than the resources mentioned above [4]. The theoretical half cell and overall voltages for the Magnesiumââ¬âhydrogen peroxide fuel cell system are as follows [5]: Anode: Mg à ¯Ãâà Mg+2 + 2e E0 = 2.37 V (vs SHE) Cathode : H2O2 + 2H2 + 2e à ¯Ãâà 2H2O E0 = 1.78 V (vs. SHE) Overall reaction : Mg + H2O2 + 2H+à ¯Ãâà Mg+2 + 2H2O Ecell = 4.15 V (vs. SHE) The Mgââ¬âH2O2 fuel cells possess advantages of environmentally benign and low costs, prior to commercialization further improvement is necessary. The cathode materials used in Mgââ¬âH2O2 fuel cell are the key components, which determine the performance and stability of the cell [7]. Extensive studies were carried out and explored the substrates suitable for cathodic materials and hydrogen peroxide reduction reactions [6, 8]. Benette et al [9] has used fabricated Microfibre carbon electrode (MCE) as cathode in Alââ¬âH2O2 fuel cells, the fabricated MCE was covered by Pd/Ir clusters using a textile flocking technique. The MCE has shown a maximum power density of 90 mW cm-2 with increased loading of Pd/Ir on cathode to 10 mg cm-2. Carbon and Nickel foil substrates have been studied comparatively with Pd/Ir catalyst in Mgââ¬âH2O2 fuel cell. The cell voltages of 1.3V and 1.5V were obtained with nickel foil and carbon substrate catalyzed by Pd/Ir catalyst at 25 mA cm-2 [10] . To achieve a better performance and stability, besides a high catalytic activity of the catalyst toward the hydrogen peroxide reaction, the properties of the material for cathodic catalysts should be considered. Considering above aspects, carbon can be a good choice for its excellent corrosive resistance in different media. However, it is of challenge to prepare a carbon based substrate with both high electronic conductivity and good mechanical property [11]. In the present study, carbon felt and carbon cloth has been used as cathode. The fuel cell was operated in various concentrations of 0.2, 0.5, 1.0, 1.5 and 2M hydrogen peroxide and sulfuric acid as catholyte and 0.68M NaCl as anolyte. The performance of the fuel cell in comparison with carbon cloth and Carbon felt was investigated at temperatures 35 to 70à °C and at flow rates 20, 50, 100 ml min-1. 2. Experimental 2.1 Materials All materials used in this study are reagent grade quality and used as received from SRL chemicals, without further purification. All solutions are prepared in deionised water. The anode used in AZ61 magnesium alloy supplied by Omega Enterprises. The cathode used in carbon cloth and Carbon felt supplied by Nickunj Eximp Ltd. Mg-H2O2 fuel cell tests The performance studies for carbon cloth and Carbon felt as cathode were performed in homemade Mg-H2O2 fuel cell of area 30 cm2 area single cell assembly. The active area of the electrode was 5.5 cm Ãâ" 5.5 cm. Nafion 117 membrane was used as a PEM membrane. The distance between the membrane and electrodes is 1 mm for Mgââ¬âAZ61 anode as well as cathode (Carbon felt and carbon cloth). The testing of the cell was carried out by feeding different concentrations hydrogen peroxide and sulfuric acid at cathode and 0.6M sodium chloride solution at anode. The flow rates of the mixture of hydrogen peroxide and sulfuric acid and sodium chloride solution are supplied at 20, 50 and 100 ml min-1 by calibrated peristaltic pumps. The cell was tested at temperatures of 35, 40, 50, 60 and 70à °C and at 1 bar pressure. The cell temperature was controlled by plate heaters fixed to the cell. 3.0 Results and Discussion 3.1 Carbon felt as cathode The current in the cell has been increased in step wise of 0.5A and the corresponding voltages were recorded. Initially the OCV of the cell with carbon cloth as cathode is ~2.04V and with Carbon felt is ~2.14V. This is ~2.0V lower than the theoretical voltage this may be due to the resistance of the cell materials, and mixed potential at the anode and cathode from simultaneous oxidation of H2O2 to H2O and O2 [12]. 3.2 Effect of temperature Mg-H2O2 fuel cell is operated at temperatures 35, 40, 50, 60 and 70à °C. Fig. 1 represents the electrode polarization curve at different temperatures. It can be seen that the performance of the cell improved with the increase in temperatures from 35ââ¬â70à °C. At current density of 60 mA cm-2 the voltage was increased from 0.86V to 1.41V with increase in temperatures from 35ââ¬â70à °C. This behavior of the cell is due to reduction of hydrogen peroxide in high temperatures [6]. Even though the cell performance increased, the instability in the mass transport region at higher current densities may be attributed to formation of gas bubbles due to the decomposition of hydrogen peroxide during discharge process [7]. 3.2 Effect of hydrogen peroxide concentration The activity of the Mg-H2O2 fuel cell increases with increasing in concentration of hydrogen peroxide. However, at high concentrations the decomposition reaction of hydrogen peroxide also occurs [6]. The effect of hydrogen peroxide concentration has been investigated in concentrations of 0.5M H2O2+1.5M H2SO4 and 2M H2O2+2M H2SO4 for carbon cloth and Carbon felt. The concentrations of the catholyte have been optimized by running the fuel cell at concentrations 0.2, 0.5, 1.0, 1.5, 2M hydrogen peroxide and sulfuric acid. 0.5M H2O2+1.5M H2SO4 and 2M H2O2+2M H2SO4 have been chosen for the present study as they demonstrated good performance in comparison with others. Fig. 2 shows the performance of carbon cloth and Carbon felt at 70à °C with concentrations of 0.5M H2O2+1.5M H2SO4 and 2M H2O2+2M H2SO4. The increase in concentration of hydrogen peroxide and sulfuric acid improved the cell performance [7]. The cathode with carbon cloth has shown maximum power density of 9.1 mW cm-2 and 6.01 mW cm-2 at 0.72V and 0.78 V and current density of 10 mA cm-2 at voltages of 0.88V and 0.55V for 2M H2O2+2M H2SO4 and 0.5M H2O2+1.5M H2SO4 concentrations, while the cathode with carbon fibre felt shown maximum power density of 91 mW cm-2 and 89 mW cm-2 at 1.3V and 1.16V and current density of 70 mA cm-2 at voltages 1.3V and 1.16 for 2M H2O2+2M H2SO4 and 0.5M H2O2+1.5M H2SO4 concentrations. The results imply that Carbon felt has performed 10 times better than carbon cloth. The reason for this effect can be due to less contact area for cathode to perform electrochemical reduction of hydrogen peroxide on carbon cloth. In case of Carbon felt the fibrous structure provides more surface area for cathode to electrochemically reduce hydrogen peroxide [12]. It can also be observed that the cathode with Carbon felt has shown better performance in the ohmic region with increase in concentration of hydrogen peroxide, later on same performance can be seen with 0.5M H2O2+1.5M H2SO4 in mass transf er region. This can be due to the 1.5 and 2M concentration of sulfuric acid. This is reasonable because electrochemical reaction of hydrogen peroxide involves H+ as reactant, the formation of H+ is rate determining step for electrochemical reaction of hydrogen peroxide, with concentrations of 1.5 and 2M H2SO4 there is very little difference in concentrations so there is a possibility of same performance in mass transfer region. It is evident that with the increase in concentration of hydrogen peroxide the cell performance increased. However, the decomposition of hydrogen peroxide is also more significant as the concentration increases and can be observed during discharge of the cell. The same can be represented in Figure 2, the fluctuant curves in mass transport region indicate the possible decomposition of hydrogen peroxide and production of gas bubbles that hindered mass transfer for the reactants [7]. 3.3 Effect of flow rate Fig.3 shows the operation of Mg-H2O2 fuel cell in flow rates of 20, 50 and 100 ml min-1. For both anode and cathode electrodes flow rates are kept constant. 0.6M NaCl was fed at anode and 0.5M H2O2 + 1.5M H2SO4 and 2M H2O2 + 2M H2SO4 was fed at cathode during operation of the cell. The curves have been recorded at temperature 70à °C. The performance of the cell shows that as the flow rate increase from 20 to 50 ml min-1 there is an improvement in performance of the cell. The flow rate was increased further 50 to 100 ml min-1 but no significance improvement can be seen in the performance. 3.4 Constant current mode The stability test for Mg-H2O2 fuel cell with carbon felt as cathode was conducted and represented in Figure 4. The measured OCV was 2.2V and the fuel cell was operated at constant current density of 50 mA cm-2 for 300 minutes. During the constant current mode operation the voltage was 1.15V and constantly decreased to 0.8V for a period of 50 minutes, during the first cycle. This is due to the consumption of Mg AZ61 anode, and was replaced with a fresh Mg AZ61 sheet for every cycle. The humps observed in the figure 4 represents cycles. Conclusion Carbon felt cathode has shown better performance in comparison with carbon cloth. Carbon felt shown a better performance with maximum power density of 91 mW cm-2 at 1.3V for 2M H2O2+2M H2SO4 which is higher than all the cathodes used and high current density of 70 mA cm-2 at voltages 1.3V and 1.16 for 2M H2O2+2M H2SO4 and 0.5M H2O2+1.5M H2SO4 concentrations which is very high in comparison with carbon cloth. References G. Anderson, Aluminumââ¬âSilver Oxide Primary Battery, US Patent #3,953,239 (1976). E.G. Dow, R.R. Bessette, M.G. Medeiros, H. Meunier, G.L. Seebach, J. Van Zee, C. Marsh-Orndorff, Enhanced electrochemical performance in the development of the aluminumââ¬âhydrogen peroxide semi-fuel cell, J. Power Sources 65 (1997) 207ââ¬â212. C. Marsh, H. Munier, R. Bessette, M.G. Medeiros, J. Van Zee, G. Seebach, US Patent #5,296,429, An Effective Method for the Reduction of H2O2. M.G. Medeiros, R. Bessette, D. Dischert, J. Cichon, US Navy Patent #6,228,527, Magnesium-Solution Phase Catholyte Seawater Electrochemical System. Maria G. Medeiros, Russell R. Bessette, Craig M. Deschenes, Charles J. Patrissi, Louis G. Carreiro, Steven P. Tucker, Delmas W. Atwater, ââ¬Å"Magnesium-solution phase catholyte semi-fuel cell for undersea vehiclesâ⬠, Journal of Power Sources 136 (2004) 226ââ¬â231. Weiqian Yang, Shaohua Yang, Wei Sun, Gongquan Sun, Qin Xin, ââ¬Å"Nanostructured silver catalyzed nickel foam cathode for an aluminumââ¬âhydrogen peroxide fuel cellâ⬠, Journal of Power Sources 160 (2006) 1420ââ¬â1424. Chaozhu Shu, Erdong Wang, Luhua Jiang, Qiwen Tang, Gongquan Sun, ââ¬Å"Studies on palladium coated titanium foams cathode for Mgââ¬âH2O2 fuel cellsâ⬠, Journal of Power Sources 208 (2012) 159ââ¬â164. L.M. Sun, D.X. Cao, G.L. Wang, ââ¬Å"Pdââ¬âRu/C as the electrocatalyst for hydrogen peroxide reductionâ⬠, Journal of Applied Electrochemistry 38 (2008) 1415ââ¬â1419. C.J. Patrissi, R.R. Bessette, Y.K. Kim, C.R. Schumacher, Fabrication and Rate Performance of a Microfiber Cathode in a Mgà ¢Ã¢â ¬Ã¢â¬ °Ã¢â¬âà ¢Ã¢â ¬Ã¢â¬ °H2O2Flowing Electrolyte Semi-Fuel Cellâ⬠, Journal of the Electrochemical Society 155 (2008) B558ââ¬âB562. M.G. Medeiros, E.G. Dow, Magnesium-solution phase catholyte seawater electrochemical system, Journal of Power Sources 80 (1999) 78ââ¬â82. J. Zhang, G.P. Yin, Z.B. Wang, Y.Y. Shao, ââ¬Å"Effects of MEA preparation on the performance of a direct methanol fuel cellâ⬠, Journal of Power Sources 160 (2006) 1035ââ¬â1040. C. Ponce de Leà ´on, F.C. Walsh, A. Rose, J.B. Lakeman, D.J. Browning, R.W. Reeve, ââ¬Å"A direct borohydrideââ¬âAcid peroxide fuel cellâ⬠, Journal of Power Sources 164 (2007) 441ââ¬â448.
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