New catalytic converter composite reduces rare Earth element usage

In their most recent attempt to reduce the amount of Ce in their experimental catalyst, Professor Machida and collaborators from Japan's National Institute of Advanced Industrial Science & Technology (AIST) grafted cerium oxide to MnFeO_y (CeO₂/MnFeO_y), and compared their new catalyst with two reference catalysts, CeO₂/Fe₂O₃ and CeO₂/Mn₂O₃. Upon assessing the oxygen-release profiles through carbon monoxide temperature-programmed reduction (CO-TPR), the researchers found that even though CeO₂/Mn₂O₃ exhibited oxygen release rates greater than CeO₂/MnFeO_y between ~350 to ~550 degrees Celsius, the experimental catalyst started releasing at the lowest possible temperature. This provided evidence that oxygen release was improved by both combining Fe₂O₃ and Mn₂O₃, and grafting CeO₂ to the surface.

The oxygen storage capacity (OSC) was also found to improve with the addition of CeO₂, which supports evidence of its oxygen gateway effect. The researchers believe that this was due to an increase in efficiency when the two oxygen-storage materials are brought together. Most importantly, however, is the TWCs ability to buffer variations in the air-to-fuel (A/F) ratio during fuel-rich and fuel-lean exhausts. For this experiment, Pd/A₂O₃ was used as the reference against the CeO₂/MnFeO_y experimental catalyst. The experimental catalyst was found to provide a pronounced buffering effect, whereas the reference catalyst had none. Furthermore, the buffering effect was found to increase as variations in the A/F frequency increased. This was considered to be due to the high oxygen release rate of CeO₂ in the early stages of the experiment.

The researchers then put their new catalyst to the test in conditions that more closely resembled the real world. Using the Japanese standard JC08 (hot start) mode for gasoline engines, they developed two (reference and experimental) real-sized honeycomb catalysts and compared their performance using a four cylinder, 1339 cc, gasoline engine on a chassis dynamometer. The experimental catalyst was a 1:2 wt ratio of 1 wt% Rh-loaded CeO₂/MnFeO_y and 2.5 wt% Pd/A₂O₃, and the reference catalyst was a mixture of 1 wt% Rh/CeO₂ and Pd/A₂O₃. The experimental catalyst used 30% less CeO₂ than the reference thereby reducing the need for the rare earth metal.

The tests of the full sized catalytic converters revealed that the conversion rate of total hydrocarbons (THC) for both converters is very high and relatively consistent throughout the 20 minute test, and the reference catalyst performs slightly better overall. Conversion rates for CO and NO_x vary greatly with engine speed, acceleration, and deceleration for both catalysts, and the differences between the two catalysts are very small. Despite the 30% reduction in CeO₂, the experimental catalyst performed very similar to the reference catalyst.

"Our new catalyst shows great promise and we hope that we can find a way to increase performance, particularly at lower temperatures," said Professor Machida. "CeO₂-ZrO₂ works well for oxygen storage and release at high reaction rates, and we are currently working on creating a composite with it and the MnFeO_y oxygen reservoir. We hope to be able to improve catalyst performance and reduce the amount of expensive rare earth elements used at the same time."