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Toyota claims hydrogen fuel cell breakthrough

Platinum isn't cheap. And it's a necessary component of hydrogen fuel-cell technology. Which means that Toyota's recent discovery of a way to better analyze how platinum breaks down is a bit of an H2 vehicle breakthrough. Toyota worked with the Japan Fine Ceramics Center (JFCC) to observe nanometer-sized platinum particles and, specifically, how they deteriorate. Platinum is used as a catalyst for when electrons are stripped away from the hydrogen molecule to create an electrical charge and when hydrogen ions and electrons mix with oxygen to create water vapor. So, when platinum gets more course during the countless chemical reactions inside of fuel cells, things slow down. Now that Toyota says it's figured out a better way to observe this process, greater efficiency and durability within the fuel-cell process of electricity production are likely to follow, though more chemistry study will be needed to figure out how that will work. Still, it's topical because Toyota last year started producing the world's first production hydrogen fuel-cell vehicle. The Japanese automaker debuted sales of the Mirai fuel-cell vehicle in Japan late last year and plans to start selling the car in California this fall (the car will be priced at $57,500). Toyota also plans to boost Mirai production to about 2,000 units in 2016 from about 700 this year. Take a look at Toyota's documents and video below. R&D Breakthrough Sets Stage for More Efficient, Durable Fuel Cell Stacks Toyota City, Japan, May 18, 2015—A breakthrough in the real-time observation of fuel cell catalyst degradation could lead to a new generation of more efficient and durable fuel cell stacks. Toyota Motor Corporation and Japan Fine Ceramics Center (JFCC) have developed a new observation technique that allows researchers to monitor the behavior of nanometer-sized particles of platinum during chemical reactions in fuel cells, so that the processes leading to reduced catalytic reactivity can be observed. Platinum is an essential catalyst for the electricity-producing chemical reactions occurring between oxygen and hydrogen in fuel cell stacks. Reduced reactivity is the result of "coarsening" of platinum nanoparticles—a process whereby the nanoparticles increase in size and decrease in surface area. Up until now, however, it has not been possible to observe the processes leading to coarsening, making it difficult to analyze the root causes.

When a Ferrari and a Toyota GT86 get jiggy, strange things happen

Swapping V8s into small Japanese cars is not new. In fact, swapping V8s into small sportscars from anywhere is not new. From the original Cobra to the modern FR-S and BRZ, big V8 power in a light, lithe chassis has been delicious combination rivaling the Reese's peanut butter cup. People familiar with these swaps know that American iron is the preferred source for large-displacement grunt, but Ryan Tuerck and Gumout have taken a different route, specifically from Italy. Replacing the 2.0-liter flat-4 of this Toyota GT86 is a Ferrari F136 V8. Unfortunately that's about the only detail we really know about this project. The F136 was used in the F430, California and 458 Italia, and all with varying displacement and output. So we don't even know which of those variants this engine is. If it came from a California, that'd at least make the front-engine location easier to fabricate. No matter though, it's still a Ferrari engine in a small car, and that's awesome. And Donut Media, the company that produced the video, promises more details down the road. In the meantime, enjoy this video preview of the project. Related Video: Related Gallery 2017 Toyota 86: New York 2016 View 12 Photos Aftermarket Weird Car News Ferrari Toyota Performance Videos sports car toyota gt86 engine swap 86 flat-four

Old Toyota Camry Hybrid batteries find new life in Yellowstone

Beginning this fall, used hybrid batteries that would otherwise be recycled will get a second life in Yellowstone National Park. 208 nickel-metal hydride batteries are being retired from the Toyota Camry Hybrids they once helped power and will become part of an off-the-grid energy system at Yellowstone's remote Lamar Buffalo Ranch field campus. The Lamar campus provides field seminars and other education and research in the northeastern corner of the park. The energy stored in the battery packs will come from solar panels and micro-hydro turbines. The total storage capacity of the batteries is 85 kWh, which is sufficient to provide plenty of emissions-free power to the five buildings at the field campus. Toyota says this program essentially doubles the life of the batteries that are no longer suitable for driving. It's great to see the batteries get another life cycle before recycling, especially in a place where wild animals easily outnumbers the cars. The battery project is part of a larger partnership between Toyota and Yellowstone. Toyota has previously donated a RAV4 and $50,000 to support sustainability projects at the park. In addition to the energy system being implemented at the Lamar Buffalo Ranch, Toyota has taken part in similar energy projects. Beginning last year, Toyota dealers in Japan have been using hybrid batteries for power storage. Also, Toyota Motor Manufacturing Alabama is testing a system to use hybrid batteries to power operations and for emergency backup power. Learn more in the press release from Toyota below. Buffalo and Bears and Batteries – Oh My! Toyota Brings Power to Yellowstone National Park June 04, 2014 Yellowstone...Where the Deer and the Antelope and the Prius Play Torrance, Calif. (June 4, 2014) – The nation's oldest National Park is ready for some new power. Toyota Camry hybrid batteries will soon power the Lamar Buffalo Ranch field campus in Yellowstone National Park. It's a new lease on life for the batteries and new, zero emission, energy option for the Park. Now that's a "bear-able" solution! The stationary distributed energy system will feature 208 used Camry Hybrid nickel-metal hydride battery packs and a total storage capacity of 85 kWh, more than enough pluck to power the five buildings on the Ranch field campus.