This paper reports an experimental study of the degradation of single PBI-based high temperature MEAs doped with phosphoric acid. The study is carried out by operating the single MEAs for long periods in steady state, the degradation is quantified considering the voltage decay rate. Besides the most common operating condition suggested by the MEAs producer (T = 160 degrees C, i = 0.2 A cm(-2), lambda(H2) = 1.2, lambda(air) = 2), the study also investigates higher operating temperature (T = 180 degrees C), higher current density (i = 0.4 A cm(-2)) and double air flow rate (lambda(air) = 4). A temperature of 180 C accelerates the degradation of the MEA which increases from around 8 mu V h(-1) up to around 19 mu V h(-1). On the opposite side, operating the MEA at i = 0.4 A cm(-2) reduces the voltage degradation rate down to 4 mu V h(-1) and increases the power output making this condition particularly interesting. EIS, CV and LSV are used to clarify the causes of degradation. A consistent increase in the charge transfer resistance is observed and is related to the loss of catalyst active area due to catalyst agglomeration, carbon corrosion and possible acid leaching. Concerning the electrolyte membrane, a slight decrease in the proton conductivity is measured, a major effect on degradation is played by the increasing gas crossover rate and by the short circuit current. Copyright (C) 2013, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights reserved.