Barack Obama, Justin Trudeau and Enrique Peña Nieto to announce new ‘aggressive but achievable’ goal at ‘Three Amigos’ summit in Ottawa
Barack Obama, Justin Trudeau and Enrique Peña Nieto will commit to a new regional clean power goal at a summit this week in Ottawa, the White House has said.
The leaders of the US, Canada and Mexico, meeting on Wednesday at the so-called “Three Amigos” summit, will pledge to have their countries produce 50% of their power by 2025 from hydropower, wind, solar and nuclear plants, carbon capture and storage, as well as from energy efficiency measures.
“We believe this is an aggressive goal, but for all three countries, one that we believe is achievable, continent-wide,” said Brian Deese, a senior adviser to Obama.
It is a jump from the current collective clean power levels of about 37% and will require the most work from the United States, which produces about 75% of the countries’ power.
About a third of US power now comes from clean energy sources.
Curbing climate-changing carbon emissions has been a priority for Obama as the end of his second and final term in office draws closer.
But his new regulations on coal-fired power plants – the main US tool to reach emissions targets pledged at UN climate talks in Paris in December 2015 – were put on hold by the US supreme court earlier this year.
The White House believes its Clean Power Plan rules will ultimately survive the challenge. The rules, along with tax credits for renewable power plants, would help the United States do its share to reach the North American goal, Deese said.
He said it would not be necessary for the United States itself to hit the 50% mark to achieve the regional target.
Mexico produced less than 20% of its power from clean energy, Deese said, noting officials there had already pledged to reach 35% by 2024.
Canada produces 81% of its electricity from hydroelectric, solar, wind and nuclear power generation, according to the Canadian Broadcasting Corp, which first reported the North American deal on Monday.
At the Wednesday summit the leaders also would announce new agreements to make it easier and cheaper to trade and transmit clean energy across the continent, Deese said.
Mexico would will join a pledge made earlier this year by Obama and Trudeau to reduce methane emissions by 40% to 45% by 2015, he said.
By: Mahmoud Habboush Claudia Carpenter
The amount of electricity generated using solar panels stands to expand as much as sixfold by 2030 as the cost of production falls below competing natural gas and coal-fired plants, according to the International Renewable Energy Agency.
Solar plants using photovoltaic technology could account for 8 percent to 13 percent of global electricity produced in 2030, compared with 1.2 percent at the end of last year, the Abu Dhabi-based industry group said in a report Wednesday. The average cost of electricity from a photovoltaic system is forecast to plunge as much as 59 percent by 2025, making solar the cheapest form of power generation “in an increasing number of cases,” it said.
Renewables are replacing nuclear energy and curbing electricity production from gas and coal in developed areas such as Europe and the U.S., according to Bloomberg New Energy Finance. California’s PG&E Corp. is proposing to close two nuclear reactors as wind and solar costs decline. Even as supply gluts depress coal and gas prices, solar and wind technologies will be the cheapest ways to produce electricity in most parts of the world in the 2030s, New Energy Finance said in a report this month.
“The renewable energy transition is well underway, with solar playing a key role,” Irena Director General Adnan Amin said in a statement. “Cost reductions, in combination with other enabling factors, can create a dramatic expansion of solar power globally.”
Bloomberg New Energy Finance also forecasts growth in solar photovoltaics, reaching 15 percent of total electricity output by 2040, according to Jenny Chase, head of solar analysis in Zurich. “Irena’s assumptions are reasonable,” she said. “Solar just gets so cheap under any reasonable scenario.”
The “most attractive” markets for solar panels up to 2020 are Brazil, Chile, Israel, Jordan, Mexico, the Philippines, Russia, South Africa, Saudi Arabia, and Turkey, according to Irena. Global capacity could reach 1,760 to 2,500 gigawatts in 2030, compared with 227 gigawatts at the end of 2015, it said.
Smart grids, or power networks capable of handling and distributing electricity from different sources, and new types of storage technologies will encourage further use of solar power, Irena said.
As of 2015, the average cost of electricity from a utility-scale solar photovoltaic system was 13 cents per kilowatt hour. That’s more than coal and gas-fired plants that averaged 5 cents to 10 cents per kilowatt hour, according to Irena. The average cost of building a solar-powered electricity utility could fall to 79 cents per watt in 2025 from $1.80 per watt last year, it said. Coal-fired power generation costs are about $3 per watt while gas plants cost $1 to $1.30 per watt, according to Irena.
The record for the world’s cheapest solar tariff was set in Dubai last month in an auction. MEED reported that a consortium including Masdar Abu Dhabi Future Energy Co. and Saudi Arabia’s Abdul Latif Jameel bid 2.99 cents per kilowatt-hour, 15 percent cheaper than the previous record.
The flexible photovoltaics, made by researchers in South Korea, could power wearable electronics.
Scientists in South Korea have made ultra-thin photovoltaics flexible enough to wrap around the average pencil. The bendy solar cells could power wearable electronics like fitness trackers and smart glasses. The researchers report the results in the journal Applied Physics Letters, from AIP Publishing.
Thin materials flex more easily than thick ones — think a piece of paper versus a cardboard shipping box. The reason for the difference: The stress in a material while it’s being bent increases farther out from the central plane. Because thick sheets have more material farther out they are harder to bend.
“Our photovoltaic is about 1 micrometer thick,” said Jongho Lee, an engineer at the Gwangju Institute of Science and Technology in South Korea. One micrometer is much thinner than an average human hair. Standard photovoltaics are usually hundreds of times thicker, and even most other thin photovoltaics are 2 to 4 times thicker.
The researchers made the ultra-thin solar cells from the semiconductor gallium arsenide. They stamped the cells directly onto a flexible substrate without using an adhesive that would add to the material’s thickness. The cells were then “cold welded” to the electrode on the substrate by applying pressure at 170 degrees Celcius and melting a top layer of material called photoresist that acted as a temporary adhesive. The photoresist was later peeled away, leaving the direct metal to metal bond.
The metal bottom layer also served as a reflector to direct stray photons back to the solar cells. The researchers tested the efficiency of the device at converting sunlight to electricity and found that it was comparable to similar thicker photovoltaics. They performed bending tests and found the cells could wrap around a radius as small as 1.4 millimeters.
The team also performed numerical analysis of the cells, finding that they experience one-fourth the amount of strain of similar cells that are 3.5 micrometers thick.
“The thinner cells are less fragile under bending, but perform similarly or even slightly better,” Lee said.
A few other groups have reported solar cells with thicknesses of around 1 micrometer, but have produced the cells in different ways, for example by removing the whole substract by etching.
By transfer printing instead of etching, the new method developed by Lee and his colleagues may be used to make very flexible photovoltaics with a smaller amount of materials.
The thin cells can be integrated onto glasses frames or fabric and might power the next wave of wearable electronics, Lee said.
By: James Vincent
Solar Impulse 2 has successfully crossed the Atlantic — the first journey of its kind made by a solar-powered plane. The experimental aircraft set off from New York on Monday and landed this morning in Seville, Spain.
The four-day crossing is one of the most difficult sections in the aircraft’s round-the-world flight. The journey started in March 2015 in Abu Dhabi, and last year, the Solar Impulse 2 flew eight stages of its trip — including a record-breaking four-day, 21-hour leg from Japan to Hawaii. However, the craft was forced to wait out the winter on the Pacific island, spending 10 months in a hangar as repairs were carried out and the crew waited for optimum solar conditions.
The Solar Impulse 2 is no heavier than a car, but has a wingspan of 72 meters — exceeding that of a Boeing 747. It’s covered in 17,000 photovoltaic cells which power its motors and charge its batteries during the day, continuing to power the craft at night. The Solar Impulse can only carry a single passenger in its unheated, unpressurized cabin, and typically flies at speeds of around 30 mph (that’s 18 times slower than a regular airplane). However, the plane could hypothetically fly perpetually, and the time it spends airborne is constrained primarily by the pilot’s endurance.
Two pilots — Bertrand Piccard and Andre Borschberg — have managed alternate legs of the aircraft’s round-the-world journey. The aim of the Solar Impulse 2, they say, is not to provide a template for future airplanes, but to show the potential of clean, solar energy.
“The Atlantic is the symbolic part of the flight,” Piccard told The Guardian this morning, a few hours before landing in Spain. “It is symbolic because all the means of transportation have always tried to cross the Atlantic, the first steamboats, the first aeroplane, the first balloons, the first airships and, today, it is the first solar-powered aeroplane.”
Piccard said that during his Atlantic crossing he saw whales breaching the water and an iceberg floating south away from the Arctic. “Every minute is a minute of suspense, a minute of challenge, and the fact I can stay [airborne] without fuel or pollution for four days and four nights is something so new,” he said. “I have the impression I am in a science fiction story and it’s like I am already in the future. And then I look outside and I say, well it’s not the future, it’s now.”
After Seville, the Solar Impulse 2 will fly on to Abu Dhabi, with this last section of its flight split into two or three legs. Greece and Egypt have been highlighted as possible pit-stops, but as with previous legs, this final journey will depend on the weather.