The Tesla Effect is Reaching Critical Mass – Could it Really Put Big Oil on the Defensive … Really?


Tesla-S3X-Semi-fleet-press-photo-e1548882286108-1024x523

*** This article appeared in TESLARATI and was re-posted in Fully Charged. We have Followed and Written a LOT about the ‘Coming EV Revolution’, about Advances in Charging Stations and Battery Technology. Most recently we posted an article ‘What If Green Energy Isn’t the Future?’

So maybe … just maybe, ‘Green Energy’ might NOT be able to meet the current Projected Carbon Fuel Replacement Schedule …. However, could the EV/ Hydrogen Fuel Cell Revolution replace forever the Internal Combustion Engine (ICE)?  (Hint: We Think So!)

Let Us Know What YOU think! Leave us your thoughts and comments. (below)

Headed by vehicles like the Tesla Model 3, the electric car revolution is showing no signs of stopping. The auto landscape today is very different from what it was years ago. Before, only Tesla and a few automakers were pushing electric cars, and the Model S was proving to the industry that EVs could be objectively better than internal combustion vehicles. Today, practically every automaker has plans to release electric cars. EV startup Bollinger Motors CEO Robert Bollinger summed it up best: “If you want to start a (car company) now, it has to be electric.”

CATALYSTS FOR A TRANSITION

A critical difference between then and now is that veteran automakers today are coming up with decent electric vehicles. No longer were EVs glorified golf carts and compliance cars; today’s electric vehicles are just as attractive, sleek, and powerful than their internal combustion peers. The auto industry has warmed up to electric vehicles as well. The Jaguar I-PACE has been collecting awards left and right since its release, and more recently, the Kia Niro EV was dubbed by Popular Mechanics as the recipient of its Car of the Year award.

A survey by CarGurus earlier this year revealed that 34% of car buyers are open to purchasing an electric car within the next ten years. A survey among young people in the UK last year revealed even more encouraging results, with 50% of respondents stating that they want electric cars. Amidst the disruption being brought about by the Tesla Model 3, which has all but dominated EV sales since production ramped last year, experienced automakers have responded in kind. Volkswagen recently debuted the ID.3, Audi has the e-tron, Hyundai has the Kona EV, and Mercedes-Benz has the EQC. Even Porsche, a low-volume car manufacturer, is attracting the high-end legacy market with the Taycan.

At this point, it appears that Tesla’s mission is going well underway. With the market now open to the idea of electric vehicles, there is an excellent chance that EV adoption will only increase from this point on.

Tesla CEO Elon Musk unveils the Tesla Semi. (Credit: Tesla)

BIG OIL FEELS A CHANGE IN THE WIND

Passenger cars are the No.1 source of demand for oil, and with the potential emergence of a transportation industry whose life and death does not rely on a gas pump, Big Oil could soon find itself on the defensive. Depending on how quickly the auto industry could shift entirely to sustainable transportation and how seriously governments handle issues like climate change, “peak oil” could happen a couple of decades or a few years from now. This could adversely affect investors in the oil industry, who might be at risk of losing their investments if peak oil happens faster than expected. JJ Kinahan, chief market strategist at TD Ameritrade, described this potential scenario in a statement to CNN. “Look at what happened to the coal industry. You have to keep that in the back of your mind and be vigilant. It can turn very, very quickly,” the strategist said.

Paul Sankey of Mizuho Securities previously mentioned that a “Tesla Effect” is starting to be felt in the oil markets. According to the analyst, the Tesla Effect is an increasingly prevalent concept today which states that while the 20th century was driven by oil, the 21st century will be driven by electricity. This, together with the growing movements against climate change today, does not bode well for the oil industry. Adam White, an equity strategist at SunTrust Advisory, stated that investors might not be looking at the oil market with optimism anymore. “A lot of damage has already been done. People are jaded towards the industry,” he said.

Prospective oil developments have been fraudulently overvalued, as claimed by a Complaint filed against Exxon. (Photo: Pixabay)

An analysis from Barclays points to the world’s reliance on oil peaking somewhere between 2030 and 2035, provided that countries keep to their low-carbon goals. The investment bank also noted that peak oil could happen as early as 2025 if more aggressive climate change initiatives are adopted on a wider scale. This all but makes investments in oil stocks very risky in the 2020s, and this risk gets amplified if electric vehicles become more mainstream. Sverre Alvik of research firm DNV GL described this concern. “By 2030, oil shareholders will feel the impact. Electric vehicles are likely to cause light vehicle oil demand to plunge by nearly 50% by 2040,” Alvik said.

Some of today’s prolific oil producers appear to be making the necessary preparations for peak oil’s inevitable decline. Amidst pressures from shareholders, BP, Royal Dutch Shell, and Total have expanded their operations into solar, wind, and electric charging, seemingly as a means to future-proof themselves. On the flipside, there are also big oil players that are ramping their activities. Earlier this month, financial titan Warren Buffet, who recently expressed his skepticism towards Elon Musk’s plan of introducing an insurance service for Tesla’s electric cars, committed $10 billion to Occidental Petroleum, one of the largest oil and gas exploration companies in the United States.

A POINT OF NO RETURN

The auto industry is now at a point where a real transition towards electrification is happening. Tesla’s efforts over the years, from the original Roadster to the Model 3, have played a huge part in this transition. Tesla, as well as its CEO, Elon Musk, have awakened the public’s eye about the viability of electric cars, while showing the auto industry that there is a demand for good, well-designed EVs. Nevertheless, Tesla still has a long journey ahead of it, as the company ramps its activities in the energy storage sector. If Tesla Energy mobilizes and becomes as disruptive as the company’s electric car division, it would deal yet another blow to the oil industry.

At this point, it is pertinent for veteran automakers that have released their own electric cars to ensure that they do not stop. Legacy car makers had long talked the talk when it came to electric vehicles, but today, it is time to walk the walk. German automaker Volkswagen could be a big player in this transition, as hinted at by the reception of its all-electric car, the ID.3. The ID.3 launch was successful, with Volkswagen getting 10,000 preorders for the vehicle in just 24 hours. The German carmaker should see this as writing on the wall: the demand for EVs is there.

The Volkswagen ID.3. (Credit: Volkswagen)

The Volkswagen ID.3 is not as quick or sleek as a Tesla Model 3, nor does it last as long on the road between charges. But considering its price point and its badge, it does not have to be. Volkswagen states that the ID.3 will be priced below 40,000 euros ($45,000) in Germany, which should make it attainable for car buyers in the country.  If done right, the ID.3 could be the second coming of the Beetle, ultimately becoming a car that redeems the company from the stigma of the Dieselgate scandal. Thus, it would be a great shame if Volkswagen drops the ball on the ID.3.

Tesla will likely remain a divisive company for years to come; Elon Musk, even more so. Nevertheless, Tesla and what it stands for is slowly becoming an idea, one that connotes hope for something better and cleaner for the future. And if history’s victories and tragedies are any indication, once something becomes an idea, an intangible concept, it becomes impossible to kill.

Watch and Learn More

Mobility Disruption | Tony Seba

Tony Seba, Silicon Valley entrepreneur, Author and Thought Leader, Lecturer at Stanford University, Keynote The reinvention and connection between infrastructure and mobility will fundamentally disrupt the clean transport model.

Nano-Enabled Batteries and Super Capacitors

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Argonne National Laboratory – New coating could have big implications for lithium batteries


Argonne scientists have developed a new coating (shown in blue) for battery cathodes that can improve the electronic and ionic conductivity of a battery while improving its safety and cycling performance. Credit: Argonne National Laboratory

Building a better lithium-ion battery involves addressing a myriad of factors simultaneously, from keeping the battery’s cathode electrically and ionically conductive to making sure that the battery stays safe after many cycles.

In a new discovery, scientists at the U.S. Department of Energy’s (DOE) Argonne National Laboratory have developed a new   by using an oxidative chemical vapor deposition technique that can help solve these and several other potential issues with  all in one stroke.

“The coating we’ve discovered really hits five or six birds with one stone.” Khalil Amine, Argonne distinguished fellow and  scientist.

In the research, Amine and his fellow researchers took particles of Argonne’s pioneering nickel-manganese-cobalt (NMC) cathode material and encapsulated them with a sulfur-containing polymer called PEDOT. This polymer provides the cathode a layer of protection from the battery’s electrolyte as the battery charges and discharges.

Unlike conventional coatings, which only protect the exterior surface of the micron-sized cathode particles and leave the interior vulnerable to cracking, the PEDOT coating had the ability to penetrate to the cathode particle’s interior, adding an additional layer of shielding.

In addition, although PEDOT prevents the chemical interaction between the battery and the electrolyte, it does allow for the necessary transport of lithium ions and electrons that the battery requires in order to function.

“This coating is essentially friendly to all of the processes and chemistry that makes the battery work and unfriendly to all of the potential reactions that would cause the battery to degrade or malfunction,” said Argonne chemist Guiliang Xu, the first author of the research.

The coating also largely prevents another reaction that causes the battery’s cathode to deactivate. In this reaction, the  converts to another form called spinel. “The combination of almost no spinel formation with its other properties makes this coating a very exciting material,” Amine said.

The PEDOT material also demonstrated the ability to prevent oxygen release, a major factor for the degradation of NMC cathode materials at . “This PEDOT coating was also found to be able to suppress oxygen release during charging, which leads to better  and also improves safety,” Amine said.

Amine indicated that battery scientists could likely scale up the coating for use in nickel-rich NMC-containing batteries. “This polymer has been around for a while, but we were still surprised to see that it has all of the encouraging effects that it does,” he said.

With the coating applied, the researchers believe that the NMC-containing batteries could either run at higher voltages—thus increasing their —or have longer lifetimes, or both.

To perform the research, the scientists relied on two DOE Office of Science User Facilities located at Argonne: the Advanced Photon Source (APS) and the Center for Nanoscale Materials (CNM). In situ high-energy X-ray diffraction measurements were taken at beamline 11-ID-C of the APS, and focused ion beam lithography and  were performed at the CNM.

A paper based on the study, “Building ultra-conformal protective layers on both secondary and primary particles of layered lithium transition metal oxide cathodes,” appeared in the May 13 online edition of Nature Energy.

More information: Gui-Liang Xu et al, Building ultraconformal protective layers on both secondary and primary particles of layered lithium transition metal oxide cathodes, Nature Energy(2019).  DOI: 10.1038/s41560-019-0387-1

Journal information: Nature Energy

Provided by Argonne National Laboratory

Electric Car Price Tag Shrinks Along With Battery Cost – Updated ‘Crossover Point’ – 2022


Bloomberg Shrinking EV 800x-1Big things, small packages. Photographer: Kiyoshi Ota/Bloomberg

Every year, Bloomberg NEF’s advanced transport team builds a bottom-up analysis of the cost of purchasing an electric vehicle and compares it to the cost of a combustion-engine vehicle of the same size. The crossover point — when electric vehicles become cheaper than their combustion-engine equivalents — will be a crucial moment for the EV market. All things being equal, upfront price parity makes a buyer’s decision to buy an EV a matter of taste, style or preference — but not, for much longer, a matter of cost.

Every year, that crossover point gets closer. In 2017, a Bloomberg NEF analysis forecast that the crossover point was in 2026, nine years out. In 2018, the crossover point was in 2024 — six years (or, as I described it then, two lease cycles) out.

The crossover point, per the latest analysis, is now 2022 for large vehicles in the European Union. For that, we can thank the incredible shrinking electric vehicle battery, which isn’t so much shrinking in size as it is shrinking — dramatically — in cost.

Analysts have for several years been using a sort of shorthand for describing an electric vehicle battery: half the car’s total cost. That figure, and that shorthand, has changed in just a few years. For a midsize U.S. car in 2015, the battery made up more than 57 percent of the total cost. This year, it’s 33 percent. By 2025, the battery will be only 20 percent of total vehicle cost.

Bloombergs Shrinking EV Battery -1x-1

My colleague Nikolas Soulopoulos, author of the research note, provided further insights. The first is that he expects electric vehicle chassis and body costs to drop slightly, while those same costs will rise modestly for combustion vehicles “as a result of light-weighting and other measures to help comply with emissions targets.”

Second, Soulopoulos expects bigger cost improvements in the electric powertrain, as “large-volume manufacturing is only now beginning for such parts.” By 2030, costs for motors, inverters and power electronics could be 25 to 30 percent lower than they are today.

The incredible shrinking electric vehicle battery doesn’t just mean cheaper electric passenger cars. It also means all sorts of other vehicles that weren’t previously practical to electrify now are — and beyond proof-of-concept scale, too.

One example: Komatsu Ltd. has just announced a small all-electric excavator. The company’s rationale is worth reading:

Equipped with an in-house developed new charger, high-voltage converter and other devices, it offers excavation performance on par with the internal combustion model of the same power output, while achieving zero exhaust gas emissions and a dynamic reduction in noise levels. It is an environment and people-friendly machine. Komatsu expects a wider range of applications for this machine, including construction work near hospitals or schools or in residential areas, where contractors have conventionally paid special attention to exhaust gas and noise during work, as well as inside tunnels or buildings.

There are new electric vehicles at sea as well. Stena Line plans to install batteries in one of its car ferries between Sweden and Denmark, rolling out its battery systems incrementally. The first, a 1 megawatt-hour battery, will power the ship when it is maneuvering in port. The next, a 20 megawatt-hour battery, will provide power for port operations and “about 10 nautical miles” beyond. The final, a 50 megawatt-hour battery, will provide 50 nautical miles’ worth of power. “As both the size and cost of batteries decrease, battery operation becomes a very exciting alternative to traditional fuels for shipping, as emissions to air can be completely eliminated,” says Stena Line’s CEO Niclas Martensson.

Smaller EV batteries will soon be flying, too. Harbour Air Ltd., which operates 42 planes in 12 short routes in British Columbia, is adding an electric plane to its fleet. “The intent is to eventually convert the entire fleet,” says founder and CEO Greg McDougall, who offers a familiar rationale for his optimism: Ranges and capabilities “are changing very rapidly with the development of the battery technology.”

McDougall’s company is seeking approval for his plans ahead of today’s battery economics in anticipation of what’s coming. “We don’t want to be trying to get through the regulatory process after it becomes more economically viable; we want to do it now,” he says.

 

Nathaniel Bullard is a Bloomberg NEF energy analyst, covering technology and business model innovation and system-wide resource transitions.

 

 

Chinese electric car maker BYD reports 632% jump in profits … “Taking Tesla to the Wood Shed”


Electric car maker BYD is speeding ahead of Tesla with respect to profitability.

The Chinese company today (April 28) reported a 632% jump in profits in the first quarter from a year ago. Days earlier, the US car company led by Elon Musk announced one of its worst quarters ever.

BYD is the world’s largest electric vehicle maker (membership), though its brand isn’t widely recognized outside of China. It started out as a battery maker about 25 years ago and transitioned into the car business a little more than a decade ago, making both conventional fossil fuel-powered cars and “new energy vehicles.”

The success of its first mass-produced hybrid caught the attention of legendary US investor Warren Buffett, who in 2008 bought a 10% stake in BYD for $230 million. That investment seems to be really paying off right now.

There is increased demand for electric vehicles in China, BYD says, and it expects continued growth. The company’s profits rose to about 750 million yuan ($111 million) in the first quarter, compared to 102 million yuan a year ago. BYD sold 73,172 new energy vehicles (pdf) in the quarter, up 147% from the same period a year ago.  

Including conventional fuel cars, it sold 73,172 vehicles in the quarter, up 5% from last year. The company is now selling more electric vehiclesthan conventional cars.

“New energy vehicles are expected to continue to sell well in the second quarter, and new energy vehicle sales and revenues continue to maintain strong growth,” the company’s latest stock exchange filing reports.

According to Reuters, BYD expects to sell 655,000 cars in 2019, and will account for a substantial portion of the 1.6 million electric vehicle total that China’s Association of Automobile Manufacturers predicts will be sold this year.

In stark contrast to this positive news for BYD, its US rival Tesla lost nearly $700 million in the first quarter. It attributed over $120 million in losses to a higher return rate than expected after it raised prices for the Model S and Model X.

In its quarterly earnings call, Tesla chief financial officer Zachary Kirkhorn described the first quarter as “one of the most complicated… in the history of the company.”

Beyond its faltering quarterly profits, Tesla also had some bad news in China to contend with recently.

Last week, a video that circulated widely on Chinese social media showed a parked Tesla Model S abruptly caching fire in Shanghai, where the company plans to build its first overseas factory. Earlier in the month, a parked Tesla in the US also caught fire.

The two electric vehicle makers do have something in common, however. Tesla and BYD both plan to expand into each other’s markets. China is the world’s largest car market, and the US comes second.

Read More: BYD Sold Over 28,000 EVs In January — Will China See Over 50% Sales Growth Again This Year? — #CleanTechnica Report

A new battery for EV’s that lasts 1 million Miles – Coming Next Year – Tesla CEO Elon Musk


Tesla CEO Elon Musk says that the automaker is working on a new battery pack to come out next year which will last 1 million miles.

When talking about the economics of Tesla’s future fleet of robotaxis at the Tesla Autonomy Event yesterday, Musk emphasized that the vehicles need to be durable in order for the economics to work:

“The cars currently built are all designed for a million miles of operation. The drive unit is design, tested, and validated for 1 million miles of operation.”

Tesla says it will roll out robotaxis in U.S. next year

But the CEO admitted that the battery packs are not built to last 1 million miles.

Just a week ago, Musk said that they built Model 3 to last as long as a commercial truck, a million miles, and the battery modules should last between 300,000 miles and 500,000 miles.

At the time, he also said that Tesla plans to provide battery module replacements.

Now, Musk added that there’s a new Tesla battery pack coming that will last as long as the rest of the vehicles:

“The new battery pack that is probably going to production next year is designed explicitly for 1 million miles of operation.”

The CEO said that they are optimizing every aspect of the cars, including the tires, in order to achieve minimal maintenance to create an “hyper-efficient” electric robotaxi.

Read More: Tesla acquires robots company to accelerate car production

Electrek’s Take

With Tesla still being relatively young for an automaker, we have a limited set of data to look into the longevity of Tesla’s vehicles.

Early data about Tesla battery degradation show less than 10% reduction in energy capacity after over 160,000 miles, but that’s about all we have.

It’s pretty good, but 1 million miles is a whole new level.

We know that Tesla has been focusing its battery research on longevity for a while now.

Earlier this year, we reported on Tesla’s battery research group led by Jeff Dahn in Halifax applying for a patent that describes a new battery cell chemistry that would result in faster charging and discharging, better longevity, and even lower cost.

The battery technology that Tesla is trying to get through its acquisition of Maxwell could also potentially result in longevity improvements.

Read More About Maxwell: Tesla’s newly acquired battery tech could result in more power, longer range, and more durability

What CEO EM is saying now might be the result of some of those recent advancements in battery technology starting to be implemented by Tesla.

Genesis Nanotech – ICYMI – Our Top 3 Blog Posts (as picked by you) This Week


#1

MIT Review: Borophene (not graphene) is the new wonder material that’s got everyone excited

#2

China made an artificial star that’s 6 times (6X) as hot as our sun … And it could be the future of energy

 

#3

Graphene Coating Could Help Prevent Lithium Battery Fires

 

Read/ Watch More …

Genesis Nanotech – Watch a Presentation Video on Our Current Project

Nano Enabled Batteries and Super Capacitors

Tenka Energy, Inc. Building Ultra-Thin Energy Dense SuperCaps and NexGen Nano-Enabled Pouch & Cylindrical Batteries – Energy Storage Made Small and POWERFUL!

 

 

 

Flexible Nanoribbons of Crystalline Phosphorus are a World First – They could Revolutionize Electronics and Fast-Charging Battery Technology.


Phosphorous Nanoribbons 5cadc15c710a9
Credit: University College London

Tiny, individual, flexible ribbons of crystalline phosphorus have been made by UCL researchers in a world first, and they could revolutionise electronics and fast-charging battery technology.

Since the isolation of 2-dimensional phosphorene, which is the phosphorus equivalent of graphene, in 2014, more than 100  have predicted that new and exciting properties could emerge by producing narrow ‘ribbons’ of this material. These properties could be extremely valuable to a range of industries.

In a study published today in Nature, researchers from UCL, the University of Bristol, Virginia Commonwealth and University and École Polytechnique Fédérale de Lausanne, describe how they formed quantities of high-quality ribbons of phosphorene from crystals of black phosphorous and lithium ions.

“It’s the first time that individual phosphorene nanoribbons have been made. Exciting properties have been predicted and applications where phosphorene nanoribbons could play a transformative role are very wide-reaching,” said study author, Dr. Chris Howard (UCL Physics & Astronomy).

The ribbons form with a typical height of one , widths of 4-50 nm and are up to 75 μm long. This  is comparable to that of the cables spanning the Golden Gate Bridge’s two towers.

“By using advanced imaging methods, we’ve characterised the ribbons in great detail finding they are extremely flat, crystalline and unusually flexible. Most are only a single-layer of atoms thick but where the ribbon is formed of more than one layer of phosphorene, we have found seamless steps between 1-2-3-4 layers where the ribbon splits. This has not been seen before and each layer should have distinct electronic properties,” explained first author, Mitch Watts (UCL Physics & Astronomy).

While nanoribbons have been made from several materials such as graphene, the phosphorene nanoribbons produced here have a greater range of widths, heights, lengths and aspect ratios. Moreover, they can be produced at scale in a liquid that could then be used to apply them in volume at low cost for applications.

The team say that the predicted application areas include batteries, solar cells, thermoelectric devices for converting waste heat to electricity, photocatalysis, nanoelectronics and in quantum computing. What’s more, the emergence of exotic effects including novel magnetism, spin density waves and topological states have also been predicted.

Wonder material—individual 2-D phosphorene nanoribbons made for the first time

Credit: University College London

The nanoribbons are formed by mixing black phosphorus with lithium ions dissolved in  at -50 degrees C. After twenty-four hours, the ammonia is removed and replaced with an organic solvent which makes a solution of nanoribbons of mixed sizes.

“We were trying to make sheets of  so were very surprised to discover we’d made ribbons. For nanoribbons to have well defined properties, their widths must be uniform along their entire length, and we found this was exactly the case for our ribbons,” said Dr. Howard.

“At the same time as discovering the ribbons, our own tools for characterising their morphologies were rapidly evolving. The high-speed atomic force microscope that we built at the University of Bristol has the unique capabilities to map the nanoscale features of the ribbons over their macroscopic lengths,” explained co-author Dr. Loren Picco (VCU Physics).

Wonder material—individual 2-D phosphorene nanoribbons made for the first time

Credit: University College London

“We could also assess the range of lengths, widths and thicknesses produced in great detail by imaging many hundreds of ribbons over large areas.”

While continuing to study the fundamental properties of the nanoribbons, the team intends to also explore their use in energy storage, electronic transport and thermoelectric devices through new global collaborations and by working with expert teams across UCL.


Explore further

Small tweaks to nanoribbon edge structures can drastically alter heat conduction

MIT Review: Borophene (not graphene) is the new wonder material that’s got everyone excited


Stronger and more flexible than graphene, a single-atom layer of boron could revolutionize sensors, batteries, and catalytic chemistry.

Not so long ago, graphene was the great new wonder material. A super-strong, atom-thick sheet of carbon “chicken wire,” it can form tubes, balls, and other curious shapes.

And because it conducts electricity, materials scientists raised the prospect of a new era of graphene-based computer processing and a lucrative graphene chip industry to boot. The European Union invested €1 billion to kick-start a graphene industry.

This brave new graphene-based world has yet to materialize. But it has triggered an interest in other two-dimensional materials. And the most exciting of all is borophene: a single layer of boron atoms that form various crystalline structures.

The reason for the excitement is the extraordinary range of applications that borophene looks good for. Electrochemists think borophene could become the anode material in a new generation of more powerful lithium-ion batteries.

Read More: Borophene Discoveries at Rice University

Chemists are entranced by its catalytic capabilities. And physicists are testing its abilities as a sensor to detect numerous kinds of atoms and molecules.

Today, Zhi-Qiang Wang at Xiamen University in China and a number of colleagues review the remarkable properties of borophene and the applications they might lead to.

Borophene has a short history. Physicists first predicted its existence in the 1990s using computer simulations to show how boron atoms could form a monolayer.

But this exotic substance wasn’t synthesized until 2015, using chemical vapor deposition. This is a process in which a hot gas of boron atoms condenses onto a cool surface of pure silver.

The regular arrangement of silver atoms forces boron atoms into a similar pattern, each binding to as many as six other atoms to create a flat hexagonal structure. However, a significant proportion of boron atoms bind only with four or five other atoms, and this creates vacancies in the structure. The pattern of vacancies is what gives borophene crystals their unique properties.

Since borophene’s synthesis, chemists have been eagerly characterizing its properties. Borophene turns out to be stronger than graphene, and more flexible. It a good conductor of both electricity and heat, and it also superconducts. These properties vary depending on the material’s orientation and the arrangement of vacancies. This makes it “tunable,” at least in principle. That’s one reason chemists are so excited.

Borophene is also light and fairly reactive. That makes it a good candidate for storing metal ions in batteries. “Borophene is a promising anode material for Li, Na, and Mg ion batteries due to high theoretical specific capacities, excellent electronic conductivity and outstanding ion transport properties,” say Wang and co.

Hydrogen atoms also stick easily to borophene’s single-layer structure, and this adsorption property, combined with the huge surface area of atomic layers, makes borophene a promising material for hydrogen storage. Theoretical studies suggest borophene could store over 15% of its weight in hydrogen, significantly outperforming other materials.

Then there is borophene’s ability to catalyze the breakdown of molecular hydrogen into hydrogen ions, and water into hydrogen and oxygen ions.

“Outstanding catalytic performances of borophene have been found in hydrogen evolution reaction, oxygen reduction reaction, oxygen evolution reaction, and CO2 electroreduction reaction,” say the team. That could usher in a new era of water-based energy cycles.

Nevertheless, chemists have some work to do before borophene can be more widely used. For a start, they have yet to find a way to make borophene in large quantities.

And the material’s reactivity means it is vulnerable to oxidation, so it needs to be carefully protected. Both factors make borophene expensive to make and hard to handle. So there is work ahead.

But chemists have great faith. Borophene may just become the next wonder material to entrance the world.

Ref: arxiv.org/abs/1903.11304 : Review of borophene and its potential applications

From MIT Technology Review March 2019

 

Report: Levelized Cost of Energy for Lithium-Ion Batteries Is Plummeting


Bloomberg New Energy Finance finds the long-term costs of multi-hour energy storage can compete with natural gas and coal in an increasing number of markets today.

The long-term cost of supplying grid electricity from today’s lithium-ion batteries is falling even faster than expected, making them an increasingly cost-competitive alternative to natural-gas-fired power plants across a number of key energy markets. 

That’s the key finding from a Tuesday report from Bloomberg New Energy Finance on the levelized cost of energy (LCOE) — the cost of a technology delivering energy over its lifespan — for a number of key clean energy technologies worldwide.

Read More: Four Charts that Show the Future of Battery Storage

According to its analysis of public and proprietary data from more than 7,000 projects worldwide, this benchmark LCOE for lithium-ion batteries has fallen by 35 percent, to $187 per megawatt-hour, since the first half of 2018. This precipitous decline has outpaced the continuing slide in LCOE for solar PV and onshore and offshore wind power. 

Over the past year, offshore wind saw a 24 percent decline in LCOE to fall below $100 per megawatt-hour, compared to about $220 per megawatt-hour only five years ago.

The benchmark LCOE for onshore wind and solar PV fell by 10 percent and 18 percent, respectively, to reach $50 and $57 per megawatt-hour for projects starting construction in early 2019. 

To be sure, these generation technologies are still far cheaper than batteries in terms of their LCOEs — and that’s not mentioning the fact that they actually make electricity, rather than simply storing it for later use. To convert a battery’s storage capacity into a LCOE figure, the report models a utility-scale battery installation running daily cycles, with charging costs assumed to be at 60 percent of the wholesale base power price for the country in question.  

Even so, the pace of the decline in battery LCOE, particularly for multi-hour storage applications that previous generations of lithium-ion technologies have struggled to provide, is startling, BNEF notes. Since 2012, the benchmark LCOE of lithium-ion batteries configured to supply four hours of grid power — a standard requirement for many grid services — has fallen by 74 percent, as extrapolated from historical data.

In comparison, the LCOE per megawatt-hour for onshore wind, solar PV and offshore wind has fallen by 49 percent, 84 percent and 56 percent, respectively, since 2010.

In fact, the LCOE for multi-hour lithium-ion batteries is falling to the point that “batteries co-located with solar or wind projects are starting to compete, in many markets and without subsidy, with coal- and gas-fired generation for the provision of ‘dispatchable power’ that can be delivered whenever the grid needs it (as opposed to only when the wind is blowing, or the sun is shining),” the report notes. 

These findings match those we’ve been covering from our own analysts at Wood Mackenzie Power & Renewables, as well as from the broader industry. In the past year and a half, several large-scale solar-battery requests for proposals have set record-low prices, including Xcel Energy in Colorado with solar-plus-storage bids as low as $36 per megawatt-hour, compared to $25 per megawatt-hour for standalone solar, and NV Energy reporting even lower bids in its solar and solar-plus-storage RFPs.

These price points equate to about a $6 to $7 per megawatt-hour premium for solar projects that are partially “dispatchable” in the manner of a traditional power plant, compared to standalone solar, Ravi Manghani, WoodMac energy storage research director, reported at Greentech Media’s Energy Storage Summit in December. 

Just this week, clean energy advocacy and research organization Energy Innovation and Vibrant Clean Energy released a report finding that the LCOE of new renewables in the U.S. is lower than that of nearly three-quarters of the U.S. coal fleet — a not completely surprising finding, given the coal power industry’s well-documented challenges in competing with cheap natural gas, and increasingly cheap wind and solar power. 

At the same time, it’s worth noting that the current trends in pricing for lithium-ion batteries, what they actually cost today, has been mixed. While continuing technology improvements and increasing scale of manufacturing have continued to push down prices, these have been somewhat counterbalanced in the past year or so by a bottleneck in available supply, driven by a boom in demand from big projects in the U.S. and South Korea. 

WoodMac discovered that battery rack prices fell by only about 6 percent from 2017 to 2018, rather than the 14 percent range previously predicted, based on these supply shortage challenges.

Article from GreenTech Media

U of Maryland: Wang Group Develops Highly Reversible 5.3 V Battery ~ 720Wh/kg for 1k cycles ~ With graphite and Li-metal anodes ~ Game Changer?


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Over the last several years, increasing the energy density of batteries has been a top priority in battery technology development, congruent with increasing demands for faster mobile devices and longer-lasting electrIc vehicles.

The energy density of lithium-ion batteries can be enhanced by either increasing the capacity of electrodes, or by enhancing the cell voltage (V).

Extensive research has been devoted to exploring the pairing of various materials in the search for the most efficient cathode/anode mix, but until now, only limited advances have been achieved due to the narrow electrochemical stability window of traditional electrolyte.

Researchers at the University of Maryland (UMD) led by Chunsheng Wang – a professor with joint appointments in the Departments of Chemical & Biomolecular Engineering (ChBE), and Chemistry & Biochemistry – have developed a highly reversible 5.3 V battery offering a Mn3+-free LiCoMnO4 cathode, and graphite and Li-metal anodes.

A specially designed electrolyte was also created, which is stable to 5.5V for both the LiCoMnO4 cathode and (graphite and Li-metal) anodes. This resulted in a 5.3V Li-metal cell, delivering a high energy density of 720Wh/kg for 1k cycles.

What’s more, this battery chemistry boasts a Coulombic efficiency of >99%, offering new development opportunity for high-voltage and energy Li-ion batteries.

Long Chen – a ChBE post-doctoral research associate – and Xiulin Fan– a ChBE assistant research scientist – served as first authors on the corresponding research paper, published in Chem on February 28, 2019.

“We are pleased to announce that we have created a stable 5.3V battery,” said Long Chen.

“The key is the super electrolytes with an especially wide electrochemical windows of 0 – 5.5V – this is due to the formation of robust interfacial layer on the electrodes.”   

Said Wang, “The high voltage electrolytes enable us to use high voltage cathode and high capacity Si- and potential Li-metal anodes, which will significantly increase the cell energy density.

However, the Coulombic efficiency of >99% for 5.3V LiCoMnO4 still needs improvement to achieve a long cycle life.”

For additional information:

Chen, L., Fa, X., Hu, E., Ji, X., Chen, J., HouS., Deng, T., Li, J., Su, D., Yang, X., Wang, C. “Achieving High Energy Density through Increasing the Output Voltage:

A Highly Reversible 5.3 V Battery.” Chem, 28 February 2019. https://doi.org/10.1016/j.chempr.2019.02.003

Published March 6, 2019