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Despite strong support from the FAA, the airline industry, and aerospace companies, the U.S. Senate ceased funding the development of a supersonic airliner in 1971. Two years later, the FAA banned supersonic flight over land, a prohibition that remains to this day.

The Concorde went on to serve various destinations, including some in the United States, flying at supersonic speeds only over water. That continued until 2,003 when British Airways and Air France retired their fleets, together amounting to just 12 aircraft. (Fourteen production aircraft were manufactured, but one was scrapped in 1,994 and another crashed in 2000.)

While the Concorde successfully overcame the technical hurdles standing in the way of supersonic passenger service, it succumbed to economics: The cost of fuel and maintenance was especially high for these planes. A new generation of aeronautical engineers and entrepreneurs are, however, keen to once again take on the technical, environmental, and economic challenges.

Elon Musk has mentioned that the Tesla Cybertruck’s production version would be extremely similar to the all-electric pickup truck’s controversial prototype from 2019. While this may largely be the case, Musk has hinted at some new features that would be included in the production Cybertruck. Apart from updated door handles and rear-wheel steering capabilities, for example, Musk also hinted at “other great things” coming for the vehicle.

A recently published patent application from Tesla has now hinted at a couple more updates that may be coming to the Cybertruck, at least on the design front. The patent, titled “Automotive Glass Structure Having Feature Lines and Related Method of Manufacture,” describes a way to form extremely durable glass structures with aggressive curves and folds. Using such a technique, Tesla stated that it could create components like windshields with very aggressive feature lines that would otherwise not be possible with conventional glass-forming methods.

The patent application’s illustrations showcased how the system would be used in a vehicle such as the Cybertruck. One of the images in the patent featured the far left and right side of the Cybertruck’s windshield having aggressive feature lines that make the all-electric pickup truck even more futuristic and CGI-esque. This is quite different from the windshield used on the prototype Cybertruck, which seemed completely flat.

Using hydrogen for transportation is criticized by many. It would not be as energy-efficient as batteries, and a recent study even pointed out that producing it can be more pollutant than just burning the natural gas from where it is extracted. One of the main hurdles involving it is storage: putting the gas in a tank demands a lot of energy. E for Electric discovered a “solid-state hydrogen fueling” thanks to Sandy Munro and told us more about Plasma Kinetics, the company that developed it.

Watch developer Plus testing an autonomous truck on the highway without a driver behind the wheel.


Autonomous tech developer Plus has recently completed a real-world demonstration of its Level 4 autonomous truck technology on a traffic-filled highway. The company tested the truck without a driver behind the wheel, and also without any other remote operator who could take control of the truck if needed. The test took place on the Wufengshan highway in the business hub of the Yangtze Delta region, with Plus being the first company to be granted a special permit to test Level 4 vehicles in the country.

#Electric and faster than a Tesla. The Rimac Nevera is now officially the fastest accelerating production vehicle in the world. While on its way to participate in Pebble Beach celebrations this weekend, the electric hypercar made a stop at Famoso Raceway in McFarland, California, where it managed to set a production car record quarter-mile time of 8.582 seconds at 167.51 mph, according to Rimac. That was fast enough to beat the company’s own unofficial record of 8.62 seconds, which it set in Croatia back in June. Unlike that previous attempt, Rimac utilized a drag-friendly, VHT-prepped surface this time around. https://www.roadandtrack.com/news/a37304155/rimac-nevera-qua…ld-record/


Rimac enlisted Brooks Weisblat from DragTimes to be the wheelman for the record-setting attempt. Thankfully, that means we have some great video footage to go along with the new record. The Nevera is perfectly suited for this sort of endeavor, as the electric hypercar packs 1,914 horsepower and 1,741 lb-ft of torque. The car’s four electric motors also provide all-wheel drive, which utilizes Rimac’s All-Wheel Torque Vectoring 2 technology. Despite the help from the prepared surface and AWD, the Nevera wasn’t exactly testing in ideal conditions. The temperatures outside were as high as 98 degrees fahrenheit, with the track itself measuring in at 149 degrees fahrenheit. This required the company to make some setup adjustments as they went, making several passes in the process. The record-setting run itself was actually the eleventh pass the company made in quick succession.

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The rover will dig deeper into Mars than any previous mission in search of ancient life.


The rover, set for launch in 2,022 will bring to a head a decades-in-development program that has suffered a series of setbacks. If all goes well, the Rosalin Franklin rover may be scientists’ best shot at getting a definitive answer about whether there was ever life on Mars and what its fate can tell us about our own planet.

What is the Rosalind Franklin rover?

The Rosalind Franklin rover is an astrobiology lab on six wheels. It’s the mobile component of the joint ESA-Roscosmos ExoMars mission that also includes the Kazachok lander vehicle. Kazachok will land and release the rover on Mars’s Oxia Planum, an area believed to have once contained liquid water and may have been hospitable to early life.

We’ve seen a lot of electric vehicle growth and success stories in the past several years, but one area that’s been a bit of a letdown has been the semi truck market. Unfortunately, we still don’t have the Tesla Semi, and it was recently delayed until 2,022 and a big side area of that market that “futurists” have long been excited about is potential self-driving trucks. Platoons of self-driving semi trucks are especially exciting since tight, train-like caravans of semi trucks would use far less energy than the current system, and those trucks could much more easily be cost-competitive electric trucks with zero tailpipe emissions. Anyway, though, we’re getting ahead of ourselves again.

Last month, Indiana’s Department of Transport (INDOT) announced a collaboration with Purdue University and German company Magment to test out whether cement with embedded magnetized particles could provide an affordable road-charging solution.

Most wireless vehicle charging technologies rely on a process known as inductive charging, where electricity pumped into a wire coil creates a magnetic field that can induce an electric current in any other nearby wire coil. The charging coils are installed at regular intervals under the road, and cars are fitted with a receiver coil that picks up the charge.

But installing thousands of miles of copper under the road is obviously fairly costly. Magment’s solution is to instead embed standard concrete with recycled ferrite particles, which are also able to generate a magnetic field but are considerably cheaper. The company claims its product can achieve transmission efficiency of up to 95 percent and can be built at “standard road-building installation costs.”