Electrochemical carbon corrosion in high temperature proton exchange membrane fuel cells

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Electrochemical carbon corrosion in high temperature proton exchange membrane fuel cells Hyung-Suk Oh, Jin-Hee Lee, Hansung Kim* Dept. of Chemical and Biomolecular Engineering, Yonsei University, 50 Yonsei-ro, Seodaemun-gu, Seoul 120-749, Republic of Korea

article info

abstract

Article history:

Electrochemical carbon corrosion occurring in a high temperature proton exchange

Received 8 March 2012

membrane fuel cell (HT-PEMFC) operating under non-humidification conditions was

Received in revised form

investigated by measuring CO2 generation using on-line mass spectrometry and comparing

9 April 2012

the results with a low-temperature proton exchange membrane fuel cell (LT-PEMFC)

Accepted 17 April 2012

operated under fully humidified conditions. The experimental results showed that more

Available online 15 May 2012

CO2 was measured for the HT-PEMFC, indicating that more electrochemical carbon corrosion occurs in HT-PEMFCs. This observation is attributed to the enhanced kinetics of

Keywords:

electrochemical carbon corrosion due to the elevated operating temperature in HT-

High temperature proton exchange

PEMFCs. Additionally, electrochemical carbon corrosion in HT-PEMFCs showed a strong

membrane fuel cell

dependence on water content. Therefore, it is critical to remove the water content in the

Carbon corrosion

supply gases to reduce electrochemical carbon corrosion.

Durability

Copyright ª 2012, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights

Mass spectrometry

reserved.

Electrocatalysts

1.

Introduction

In recent years, there has been significant interest in the development of high-temperature proton exchange membrane fuel cells (HT-PEMFCs) operating at temperatures greater than 100
C [1e3]. Compared with low-temperature proton exchange membrane fuel cells (LT-PEMFCs) operating at approximately 60e80
C, HT-PEMFCs offer numerous advantages, such as the high tolerance of catalyst to contaminants, improved electrode kinetics, and simplified water and heat management [4e9]. To realize HT-PEMFCs, the largest challenge is replacing the perfluorosulfonic acid membranes (such as Nafion) that are currently used as the proton exchange membrane in LT-PEMFCs. Thus, tremendous effort has focused on the development of proton exchange membranes with high ionic conductivity and chemical and physical stability at elevated temperatures [10e12]. In recent

years, phosphoric acid-doped PBI (polybenzimidazole) has shown not only good proton conductivity but also excellent oxidative and thermal stability and almost zero electroosmotic drag [13e15]. In addition to developing a membrane for high temperature applications, it is critical to demonstrate the durability of HT-PEMFCs for commercial viability. The reduced life time of HT-PEMFCs is considered to be mainly due to the degradation of the electrode and the membrane such as the aggregation of catalyst particles [16] and the depletion of phosphoric acid [17]. However, compared to membranes, relatively little is reported about the degradation mechanism for the electrode, especially for catalyst supports associated with electrochemical carbon corrosion in HTPEMFCs. Recently, electrochemical carbon corrosion has received a considerable amount of attention because this is considered

* Corresponding author. Tel.: þ82 2 2123 5753; fax: þ82 2 312 6401. E-mail address: [email protected] (H. Kim). 0360-3199/$ e see front matter Copyright ª 2012, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights reserved. doi:10.1016/j.ijhydene.2012.04.095

i n t e r n a t i o n a l j o u r n a l o f h y d r o g e n e n e r g y 3 7 ( 2 0 1 2 ) 1 0 8 4 4 e1 0 8 4 9

one of the critical factors limiting the durability of PEMFCs [18e22]. The suggested mechanism of carbon corrosion involves carbon reacting with water and generating CO2, as shown in eq. (1). C þ 2H2 O/CO2 þ 4Hþ þ 4e

Eo ¼ 0:207 V vs: NHE

(1)

The equilibrium potential for carbon corrosion is 0.207 V vs. NHE at 25
C [23]. Although this implies that carbon is thermodynamically unstable to electrochemical carbon corrosion, the slow kinetics of this reaction makes it possible to use carbon in PEMFCs. However, it is well known that abnormal operating conditions, such as the air/fuel boundary created during the shut-down/start-up process at the anode, increase the cathodic potential to a level higher than the open circuit voltage [24e26]. Such a high potential quickly corrodes the carbon catalyst support, resulting in the severe loss of the active surface area of catalysts and rapid fuel cell performance degradation [27,28]. However, carbon corrosion research has mainly focused on LT-PEMFCs, and a detailed study of the carbon corrosion in HT-PEMFCs has not been conducted precisely. Our previous study about carbon corrosion in LT-PEMFCs revealed that carbon corrosion is accelerated as the humidity and the cell temperature increase [29]. HT-PEMFCs are generally operated under non-humidified conditions and at higher temperatures than are LT-PEMFCs. Therefore, increasing the cell temperature contributes to accelerating the carbon corrosion, while a non-humidified condition decelerates the carbon corrosion. As a result, it is difficult to predict the behavior of carbon corrosion in the HT-PEMFC. The focus of this work is to evaluate the dependence of electrochemical carbon corrosion in HT-PEMFCs and to compare the results with those of LT-PEMFCs. The influence of the humidity and cell temperature of HT-PEMFCs on the electrochemical carbon corrosion is studied systematically using on-line mass spectrometry and several electrochemical techniques.

2.

Experimental

2.1.

Preparation of the membrane electrode assemblies

High temperature polymer electrolyte membranes (Advent TPS), which were provided by the Advent Technologies Corporation, were used in this research. Catalyst ink was prepared by adding Pt/C catalyst (commercial 40 wt.% Pt from Johnson Matthey) into a solvent of n-methyl-2-pyrrolidone (NMP) containing Advent TPS solution (1.9 wt.% in NMP). After being dispersed in an ultrasonic bath for 30 min, the solution was stirred for 12 h with a magnetic stirrer. For preparation of the electrode, the ink was sprayed directly on the gas diffusion layer (SGL GDL 35BC, 350 mm thickness), dried at 80
C for 1 h, and then dried at 160
C for 2 h to remove NMP in a ventilated oven. The cell area was 5 cm2, and the amount of Pt loaded was 0.4 mg cm2 for both anode and cathode electrodes. The Advent TPS membranes were doped in 85% H3PO4 in a closed vessel at 140
C for 19 h. The doping level was calculated using the following equation and was fixed at 185%.

Doping level ¼

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Wdoped  Wdry  100 Wdry

The completed membrane electrode assemblies (MEAs) were fabricated by sandwiching the doped membrane between two electrodes using an assembling torque of 3 N m. For comparison, the MEAs of LT-PEMFCs were prepared as follows. A commercial Pt/C catalyst from Johnson Matthey Co. was used for both the cathode and the anode. The catalysts were ultrasonically mixed with 5 wt.% Nafion ionomer in isopropanol and then sprayed directly on a Nafion 212 membrane to prepare the MEAs. The cell area was 5 cm2, and the amount of Pt loaded was 0.4 mg cm2.

2.2.

Electrochemical analysis and corrosion test

The polarization curve and cyclic voltammogram (CV) were conducted before and after the corrosion test to examine the effects associated with carbon corrosion. In the case of the LT-PEMFC, the polarization curves were measured at 75
C under 1 atm using humidified O2 (150 mL min1) and H2 (150 mL min1). For the HT-PEMFC, the polarization curves were obtained at a cell temperature of 150
C under 1 atm. The dry H2 was supplied to the anode at a flow rate of 50 mL min1, and dry O2 was supplied to the cathode at a flow rate of 50 mL min1. The CV was performed in the range of 0.05e1.2 V at a sweep rate 50 mV s1 to determine the electrochemically active surface area of Pt. For the carbon corrosion test, a constant potential between 1 V and 1.4 V with reference to the anode was applied to the cathode of the fuel cell for 30 min, and the amount of CO2 produced from the cathode of the fuel cell was monitored as a function of time using on-line mass spectrometry. Hydrogen was supplied to the anode at a flow rate of 20 mL min1, and oxygen was supplied to the cathode at a flow rate of 20 mL min1. In the humidified condition, humidified gases are delivered to the anode and the cathode after passing through a saturator at a different temperature to control the relative humidity (RH) during the carbon corrosion. In the non-humidified condition, gases are directly delivered to the anode and the cathode without passing through the saturator. The carbon corrosion tests were performed at 70
C in the LT-PEMFC and at 150
C in the HT-PEMFC.

3.

Results and discussion

To investigate the electrochemical carbon corrosion in the HTPEMFC, the potential of the oxygen electrode in the fuel cell was controlled from 1.0 V to 1.4 V using a potentiostat to simulate the abnormal operating conditions in fuel cells. As shown in equation (1), the generation of CO2 represents direct evidence of carbon corrosion. Therefore, electrochemical carbon corrosion could be evaluated by measuring the amounts of CO2 emitted during the corrosion test using online mass spectrometry as a function of time. Fig. 1 shows the CO2 concentration profiles during the corrosion test of the HT-PEMFC at different potentials. At 1.0 V, no CO2 gas was detected. CO2 gas started to be measured after 1.1 V. In general, as soon as the potential was applied, the

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Fig. 1 e CO2 mass-spectrographic profiles of HT-PEMFCs. Carbon corrosion tests performed at 1.0 V, 1.1 V, 1.2 V, 1.3 V and 1.4 V for 30 min at a cell temperature of 150
C with non-humidified O2 delivered to the cathode.

concentration of CO2 increased initially and then gradually decreased, becoming zero after 30 min when the corrosion test was terminated. It is apparent that the amount of released CO2 increased significantly as the potential increased due to the enhanced overpotential of the carbon corrosion reaction. These observations strongly support that HT-PEMFCs also suffer from electrochemical carbon corrosion, even though they are operated under non-humidified conditions. Fig. 2 shows the polarization curves of the HT-PEMFC before and after the corrosion tests. When 1.0 V was applied to the cathode during the corrosion tests, the performance of the system remained essentially unaltered, whereas the cells tested at 1.1 V, 1.2 V, 1.3 V and 1.4 V showed considerable performance decays of approximately 15%, 22%, 44% and 52% at 0.6 V, respectively. These results are in good agreement with the results of CO2 formation shown in Fig. 1, indicating that electrochemical carbon corrosion is responsible for the decrease in the performance of HT-PEMFCs.

Fig. 2 e Comparison of the MEA performances before and after the corrosion tests at different potentials for the HTPEMFC.

To examine the effect of electrochemical carbon corrosion on the change in the active surface area Pt, CV measurements on MEAs were conducted before and after the corrosion tests. As shown in Fig. 3, the loss of active surface area tends to increase with increasing potential in the corrosion test. This occurs because electrochemical carbon corrosion converts carbon to CO2 gas, resulting in a decrease in the carbon surface available for Pt catalyst loading. Consequently, the corrosion of carbon supports forces Pt particles to aggregate and reduces the electrochemically active surface area of Pt. For comparison, the corrosion test using on-line mass spectrometry was conducted for the LT-PEMFC and is displayed in Fig. 4. Unlike the HT-PEMFC, the corrosion test of the LT-PEMFC was performed at 70
C under fully humidified conditions (RH 100%). The obtained CO2 concentration profiles look similar to those of the HT-PEMFC. However, the decreasing slope with time is lower in the case of the LT-PEMFC because water is supplied continuously through humidified gas during the corrosion test. Below 1.1 V, no CO2 was detected. This indicates that 1.1 V is not high enough for electrochemical carbon corrosion to occur in the LT-PEMFC during the period of the corrosion test. With further increased in the potential, the amount of released CO2 increased gradually. Fig. 5 shows the comparison of the total amount of CO2 production for the HT-PEMFC and the LT-PEMFC with respect to the potential. The figure clearly reveals that the CO2 emission for the HT-PEMFC under non-humidified conditions was higher than that of the LT-PEMFC under fully humidified conditions. The HT-PEMFC demonstrated a lower onset potential for carbon corrosion and a steeper slope with increasing potential. The total amount of CO2 produced at 1.4 V was three times higher in the HT-PEMFC than in the LT-PEMFC. This result suggests that the operating conditions of the HT-PEMFC are more vulnerable to carbon corrosion than those of the LT-PEMFC. According to our previous study, electrochemical carbon corrosion is affected by the water content and the cell temperature [29]. The presence of water is

Fig. 3 e Comparison of cyclic voltammograms before and after the corrosion tests at different potentials in the HTPEMFC. The cyclic voltammograms of the MEAs were measured at a scan rate of 50 mV sL1.

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Fig. 4 e CO2 mass-spectrographic profiles of LT-PEMFCs. Carbon corrosion tests were performed at 1.1 V, 1.2 V, 1.3 V and 1.4 V for 30 min at a cell temperature of 70
C with humidified O2 delivered to the cathode.

indispensable for electrochemical carbon corrosion. Oxygen functional groups are created on the surface of a carbon support in contact with water and are ultimately converted into CO2. In this regard, the HT-PEMFC was expected to have less carbon corrosion than the LT-PEMFC because the HTPEMFC uses dry gases while the LT-PEMFC uses hydrated gases. However, it is notable that the kinetics of the electrochemical carbon corrosion occurring in the HT-PEMFC is much faster than that in the LT-PEMFC. Because the kinetics of electrochemical carbon corrosion is slow, a high temperature accelerates the rate of electrochemical carbon corrosion. Water exists in the HT-PEMFC as a result of the oxygen reduction reaction at the cathode in the vapor phase due to its high operating temperature. This water vapor reacts with carbon and produced CO2 at an enhanced rate during abnormal operating conditions. Therefore, it is more critical to

Fig. 5 e Comparison of the total amount of CO2 emitted as determined by on-line mass spectrometry at different potentials in both the HT-PEMFC and the LT-PEMFC, respectively.

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Fig. 6 e CO2 mass-spectrographic profiles of HT-PEMFCs. Carbon corrosion tests were performed at a cell temperature of 150
C under different humidification conditions. Humidified O2 (RH 1.6%) was delivered to the cathode after passing through a saturator at 40
C. The potential is fixed at 1.4 V.

control water in the HT-PEMFC to avoid electrochemical carbon corrosion. To investigate the effect of electrochemical carbon corrosion on water in the HT-PEMFC, oxygen gas was passed through the humidifier at 40
C. The relative humidity (RH) is calculated to be 1.6% based on the humidification conditions and the cell temperature. From the mass spectrometry results shown in Fig. 6, the CO2 production at RH 1.6% increases significantly, as high as 6 times compared with the nonhumidified conditions. These results suggest that a small change in water content plays a critical role in the electrochemical carbon corrosion in the HT-PEMFC. Fig. 7 shows the MEA performance before and after carbon corrosion tests with respect to humidification of the feed gases. As predicted from the mass spectrometry results shown in Fig. 6, an additional decrease in the MEA

Fig. 7 e Comparison of the MEA performances before and after the corrosion tests using non-humidified O2 and humidified O2 (RH 1.6%) at 40
C.

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performance is observed at RH 1.6%. These results demonstrate that the amount of water supplied to the MEA is an important factor in the electrochemical carbon corrosion in the HT-PEMFC. To date, most durability studies of HT-PEMFCs have occurred under non-humidified conditions [30,31]. However, under actual circumstances, the supplied hydrogen gas could contain a small amount of water if it is produced from an on-site hydrogen generator (e.g., a reformer) [32]. For the cathode, the supplied ambient air can also contain a significant amount of water based on the weather conditions. Therefore, it is essential to remove water from the supply gases to decrease carbon corrosion and enhance the durability of HT-PEMFCs.

4.

Conclusion

The electrochemical corrosion of an HT-PEMFC under nonhumidification conditions was evaluated and compared with that of an LT-PEMFC under full humidification conditions by measuring the CO2 emission using an on-line mass spectrometer. As indicated by the results of the mass spectra, polarization curves and CV, the operating conditions of the HT-PEMFC are more vulnerable to electrochemical carbon corrosion than the operating conditions of the LT-PEMFC. Although the water content, which is indispensable for carbon corrosion, is lower in the HT-PEMFC compared with the LT-PEMFC, the enhanced kinetics due to the elevated temperature in the HT-PEMFC accelerates carbon corrosion significantly. Thus, it is critical to control the water content in the feed gases to reduce electrochemical carbon corrosion and increase the durability of HT-PEMFCs.

Acknowledgements This work was supported by the New & Renewable Energy of the Korea Institute of Energy Technology Evaluation and Planning (KETEP) grant funded by the Korea government Ministry of Knowledge Economy (No. 20093021030021) and the Priority Research Centers Program through the National Research Foundation of Korea (2009-0093823) and the National Research Foundation of Korea (NRF-2009-C1AAA001-0092926) funded by the Ministry of Education, Science and Technology.

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