Why build a novel green fuels plant in remote Patagonia? First, strong winds are created when Antarctica's cold air meets the warm air from the Pacific. Turbines there can achieve 75% operating efficiency versus an average of 45% for Texas wind farms. Second, the plant's owner, Santiago, Chile-based HIF Global, already operates vast Atacama Desert solar farms and is looking to erect thousands of wind turbines in Patagonia.
That would be enough to make billions of gallons of fuel a year and turn Chile into the unlikely exporter of millions of gallons a year of greener gasoline made from Patagonia winds—the same ones that 500 years ago blew Magellan's ships through the strait that bears his name.
But Patagonia is not logistically the easiest place to build, which is why HIF aims to construct its first world-scale plant in Texas, near its chemical plants and refineries. Meg Gentle, HIF's executive director, was captivated by the concept when she heard about it in 2021 from chairman Cesar Norton.
Gentle, 48, had just exited the liquefied natural gas business and agreed to put some money behind HIF (Highly Innovative Fuels). "I started as an investor. Soon it was, 'Meg can you help us' with this or that." Her job for the last two years has been planning, permitting and contracting for a $6 billion plant in Matagorda County, Texas, that will make 200 million gallons of greener fuels a year—equivalent to taking the emissions of 400,000 cars off the road.
WHY IT MATTERS
It’s an irony of the green wave—the world needs to make such enormous investments in low-carbon infrastructure that megaprojects might be easier to finance than small ones.
“Demand for these projects is boundless,” says Andrew Ellenbogen, managing director at private equity shop Global Infrastructure Partners, “and will be much better addressed by projects of this size.”
The inside of the space-based Microwave Array for Power-transfer Low-orbit Experiment (MAPLE) which emits collected energy across empty space using an array of transmitters (right) to two receivers (right) to illuminate an LED.Image:Caltech
The California Institute of Technology has big news for space-based power. Researchers at the university have reportedly beamed solar power from space to Earth without a single wire—and they say it’s a first.
The experiment is a part of Caltech’s Space Solar Power Project, and the institute announced a successful transmission viapress releaseyesterday. The researchers conducted the power transfer experiment using the Microwave Array for Power-transfer Low-orbit Experiment, or MAPLE, which is a small prototype aboard the in-orbit Space Solar Power Demonstrator (SSPD-1) that launched this past January.
The researchers say that, in a first, MAPLE’s array of transmitters successfully beamed solar power collected in space using microwaves to a receiver on the rooftop of Gordon and Betty Moore Laboratory of Engineering on Caltech’s campus in Pasadena.
“Through the experiments we have run so far, we received confirmation that MAPLE can transmit power successfully to receivers in space,” said Space Solar Power Project co-director Ali Hajimiri in the press release. “We have also been able to program the array to direct its energy toward Earth, which we detected here at Caltech. We had, of course, tested it on Earth, but now we know that it can survive the trip to space and operate there.”
How Does Wireless Power Transfer Work?
The SSPD-1,attached to a Vigoride spacetug from Momentus Space,consists oftwopanels used to collect solar power.An array of transmitters within MAPLE sends that energy across a given distance using constructive and destructive interference. Located about a foot away from its transmitter, MAPLE has two receivers that collect solar energy and convert it to DC electricity which, during the experiment, was used to light up two LEDs inside MAPLE. The researchers were able to light up one LED at a time by shifting the transmissions between the receivers, demonstrating the accuracy of the array. MAPLE also has a window that can allow the transmitters to beam energy to a target outside the spacecraft, like Earth“In the same way that the internet democratized access to information, we hope that wireless energy transfer democratizes access to energy,” Hajimiri said in the release. “No energy transmission infrastructure will be needed on the ground to receive this power. That means we can send energy to remote regions and areas devastated by war or natural disasterThe ability to wirelessly transmit solar power from space has huge implications for renewable energy, so much so thatJapan plans to start using it by the mid-2030's. A Japanese research team is looking to pilot the technology in2025with a public-private partnership.As humanity’s growing need for energy continues, a powerful solution like space-based solar power collection and transmission could be a huge step in theright direction. Space-based power collection would be able to operate 24-hours a day—whereas night pauses ground-based solar power collection—and would be to able to beam power to remote or disaster-stricken areas, assuming they have the requisiteinfrastructure.
