clean tech

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Endua creates hydrogen-powered clean energy storage, using tech from Australia’s national science agency

Hydrogen-based generators are an environmentally friendly alternative to ones powered by diesel fuel. But many rely on solar, hydro or wind power, which aren’t available all the time. Brisbane-based Endua is making hydrogen-based power generators more accessible by using electrolysis to create more hydrogen and storing it for long-term use. The startup’s technology was developed at CSIRO, Australian’s national science agency, and is being commercialized by Main Sequence, the venture fund founded by CSIRO and Ampol, one of the country’s largest fuel companies.

Main Sequence’s venture science model means that it first identifies a global challenge, then brings together the technology, team and investors to launch a startup that can address that problem. Through the program, Paul Sernia, the founder of electric vehicle charger maker Tritium, was brought on to serve as Endua’s chief executive officer, working with Main Sequence partner Martin Duursma to commercialize the hydrogen-based power generation and storage technology developed at CSIRO. Ampol will serve as Endua’s industry partner.

Endua is backed by $5 million AUD (about $3.9 million USD) from Main Sequence, CSIRO and Ampol. The company plans to launch in Australia first before expanding into other countries.

Sernia told TechCrunch that Endua was created to “solve one of the biggest problems facing the transition to renewable energy — how to store renewable energy in large quantities, for long periods of time.”

Endua’s modular power banks can run up to 150 kilowatts per pack and be extended for different use cases, serving as an alternative to power generators that run on diesel fuel. Batteries serve as backup, but Endua’s goal is to deliver renewable energy that can be stored in large quantities, enabling off-grid infrastructure and communities to have self-sustaining power sources.

“Hydrogen electrolysis technology has been around for quite some time but it still has a long way to go to meet the expectations of commercial markets and be cost-effective when compared to existing energy sources,” Sernia said. “The technology we’ve developed with CSIRO enables us to make the cost more affordable compared to fossil fuel sources, more reliable and easily maintained in remote communities.”

The startup plans to focus on industrial clients before reaching smaller businesses and residences. “One of the biggest opportunities, that few have really tackled, is that of diesel generator users like regional communities, mines or remote infrastructure,” Sernia said. “In farming, Endua’s solution could be used to power equipment such as a bore or irrigation pumps.” The power banks can plug into existing renewable energy systems, including solar and wind, to make the switch economical for users, he added. Water is part of the electrolysis process, but only a small amount is needed.

“Batteries are a great way to deliver dispatchable power in small increments and are a complementary part of the overall transition plan, but we’re focusing on delivering renewable energy that can be stored in large quantities, for large periods of time, so communities and remote infrastructure can access reliable, renewable energy at any time of day,” Sernia told TechCrunch.

Ampol is working with Endua as part of its Future Energy and Decarbonisation Strategy. It will test and commercialize Endua’s tech to reach its 80,000 B2B customers, focusing first on the off-grid diesel generator market, which the company said generates 200,000 tonnes of carbon emissions per year.

In a press statement, Ampol managing director and CEO Matthew Halliday said, “We are excited to be involved with Endua, which is part of our commitment to extending our customer value proposition by finding and developing new energy solutions that will assist with their energy transition.”

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EU and Bill Gates make joint push for $1BN to accelerate clean tech

The European Commission has announced a partnership with Bill Gates’ sustainable energy funding vehicle with the goal of unlocking new investments for clean tech and sustainable energy projects totaling up to $1 billion (€820 million) over five years (2022-2026).

EU-based projects the partnership will initially focus on four sectors that are being prioritized for their potential to deliver substantial reductions in regional emissions — namely:

  • Green hydrogen.
  • Sustainable aviation fuels.
  • Direct air capture.
  • Long-duration energy storage.

The goal is to scale technologies that are currently too expensive to compete with fossil-fuel-based incumbent technologies.

The pair said they will continue to work on setting up the program over the coming months, with an eye on having something further to announce at the COP-26 conference in November.

It’s not the first time the commission and Gates’ Breakthrough Energy organization have worked together on funding sustainable investment. But the scale of this latest partnership dwarfs the €100 million fund the EU established back in 2019 with its venture investment funding arm.

Now the commission has partnered with Breakthrough Energy Catalyst — a financing program within Gates’ organization that aims to accelerate the development and adoption of technologies needed to underpin a low-carbon economy — to mobilize up to 10x more than the earlier fund to build large-scale, commercial demonstration projects for clean technologies.

The overarching goal is of course to lower the costs and accelerate deployment of clean tech in order to deliver significant reductions in CO2 emissions in line with the Paris Agreement.

The bloc is a major emitter of CO2 but has committed to achieving net-zero emissions by 2050, under the European Green Deal.

Gates’ philosophy with his 2015-founded Breakthrough Energy vehicle, meanwhile, is that renewables alone won’t be enough to avert catastrophic climate change — and investments in a range of high risk but potentially high reward technologies is also needed.

But given the lengthy time scales needed for a return on these types of investments, public-private partnerships look like a key piece of the financing puzzle.

Commenting on the partnership announcement in a statement, EU president Ursula von der Leyen, said: “With our European Green Deal, Europe wants to become the first climate-neutral continent by 2050. … Europe has also the great opportunity to become the continent of climate innovation. For this, the European Commission will mobilise massive investments in new and transforming industries over the next decade. This is why I’m glad to join forces with Breakthrough Energy. Our partnership will support EU businesses and innovators to reap the benefits of emission-reducing technologies and create the jobs of tomorrow.”

In another supporting statement, Gates, founder of Breakthrough Energy, added: “Decarbonising the global economy is the greatest opportunity for innovation the world has ever seen. Europe will play a critical role, having demonstrated an early and consistent commitment to climate and longstanding leadership in science, engineering, and technology. Through this partnership, Europe will lay solid ground for a net-zero future in which clean technologies are reliable, available, and affordable for all.”

On the EU side, funding for the partnership is expected to come from the bloc’s flagship R&D fund, Horizon Europe, and also via the low-carbon-focused Innovation Fund within the framework of the InvestEU program.

Breakthrough Energy Catalyst will mobilise equivalent private capital and philanthropic funds to finance selected projects.

The partnership will also be open to national investments by EU Member States through InvestEU or at project level, the commission noted. It added that a call for expressions of interest for potential InvestEU implementing partners is currently open until June 30, 2021.

Renewable energy and clean(er) transport were also key focus areas for the massive €750 billion “Next Generation EU” coronavirus recovery fund put together by the commission last year — which said it would borrow money on the financial markets through the issuance of bonds for post-pandemic recovery — with that money pegged to be channelled through EU programs between 2021 and 2024.

The bloc’s lawmakers have also suggested that digitization and AI technologies — which are other areas it’s pegged for major investment — will play a key supporting role in Europe’s green transition.

 

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Our love of the cloud is making a green energy future impossible

Mark Mills
Contributor

Mark Mills is the author of the book, “Digital Cathedrals: The Information Infrastructure Era,” and is a senior fellow at the Manhattan Institute, a Faculty Fellow at Northwestern University’s McCormick School of Engineering, and a partner in Cottonwood Venture Partners, an energy-tech venture fund.

An epic number of citizens are video-conferencing to work in these lockdown times. But as they trade in a gas-burning commute for digital connectivity, their personal energy use for each two hours of video is greater than the share of fuel they would have consumed on a four-mile train ride. Add to this, millions of students ‘driving’ to class on the internet instead of walking.

Meanwhile in other corners of the digital universe, scientists furiously deploy algorithms to accelerate research. Yet, the pattern-learning phase for a single artificial intelligence application can consume more compute energy than 10,000 cars do in a day.

This grand ‘experiment’ in shifting societal energy use is visible, at least indirectly, in one high-level fact set. By the first week of April, U.S. gasoline use had collapsed by 30 percent, but overall electric demand was down less than seven percent. That dynamic is in fact indicative of an underlying trend for the future. While transportation fuel use will eventually rebound, real economic growth is tied to our electrically fueled digital future.

The COVID-19 crisis highlights just how much more sophisticated and robust the 2020 internet is from what existed as recently as 2008 when the economy last collapsed, an internet ‘century’ ago. If a national lockdown had occurred back then, most of the tens of millions who now telecommute would have joined the nearly 20 million who got laid off. Nor would it have been nearly as practical for universities and schools to have tens of millions of students learning from home.

Analysts have widely documented massive increases in internet traffic from all manner of stay-at-home activities. Digital traffic measures have spiked for everything from online groceries to video games and movie streaming. So far, the system has ably handled it all, and the cloud has been continuously available, minus the occasional hiccup.

There’s more to the cloud’s role during the COVID-19 crisis than one-click teleconferencing and video chatting. Telemedicine has finally been unleashed. And we’ve seen, for example, apps quickly emerge to help self-evaluate symptoms and AI tools put to work to enhance X-ray diagnoses and to help with contact tracing. The cloud has also allowed researchers to rapidly create “data lakes” of clinical information to fuel the astronomical capacities of today’s supercomputers deployed in pursuit of therapeutics and vaccines. 

The future of AI and the cloud will bring us a lot more of the above, along with practical home diagnostics and useful VR-based telemedicine, not to mention hyper-accelerated clinical trials for new therapies. And this says nothing about what the cloud will yet enable in the 80 percent of the economy that’s not part of healthcare.

For all of the excitement that these new capabilities offer us though, the bedrock behind all of that cloud computing will remain consistent — and consistently increasing — demand for energy. Far from saving energy, our AI-enabled workplace future uses more energy than ever before, a challenge the tech industry rapidly needs to assess and consider in the years ahead.

The new information infrastructure

The cloud is vital infrastructure. That will and should reshape many priorities. Only a couple of months ago, tech titans were elbowing each other aside to issue pledges about reducing energy usage and promoting ‘green’ energy for their operations. Doubtlessly, such issues will remain important. But reliability and resilience — in short, availability — will now move to the top priority.

As Fatih Birol, Executive Director of the International Energy Agency (IEA) last month reminded his constituency, in a diplomatic understatement, about the future of wind and solar: “Today, we’re witnessing a society that has an even greater reliance on digital technology” which “highlights the need for policy makers to carefully assess the potential availability of flexibility resources under extreme conditions.” In the economically stressed times that will follow the COVID-19 crisis, the price society must pay to ensure “availability” will matter far more.

It is still prohibitively expensive to provide high reliability electricity with solar and wind technologies. Those that claim solar/wind are at “grid parity” aren’t looking at reality. The data show that overall costs of grid kilowatt-hours are roughly 200 to 300 percent higher in Europe where the share of power from wind/solar is far greater than in the U.S. It bears noting that big industrial electricity users, including tech companies, generally enjoy deep discounts from the grid average, which leaves consumers burdened with higher costs.

Put in somewhat simplistic terms: this means that consumers are paying more to power their homes so that big tech companies can pay less for power to keep smartphones lit with data. (We will see how tolerant citizens are of this asymmetry in the post-crisis climate.)

Many such realities are, in effect, hidden by the fact that the cloud’s energy dynamic is the inverse of that for personal transportation. For the latter, consumers literally see where 90 percent of energy is spent when filling up their car’s gas tank. When it comes to a “connected” smartphone though, 99 percent of energy dependencies are remote and hidden in the cloud’s sprawling but largely invisible infrastructure. 

For the uninitiated, the voracious digital engines that power the cloud are located in the thousands of out-of-sight, nondescript warehouse-scale data centers where thousands of refrigerator-sized racks of silicon machines power our applications and where the exploding volumes of data are stored. Even many of the digital cognoscenti are surprised to learn that each such rack burns more electricity annually than 50 Teslas. On top of that, these data centers are connected to markets with even more power-burning hardware that propel bytes along roughly one billion miles of information highways comprised of glass cables and through 4 million cell towers forging an even vaster invisible virtual highway system.

Thus the global information infrastructure — counting all its constituent features from networks and data centers to the astonishingly energy-intensive fabrication processes — has grown from a non-existent system several decades ago to one that now uses roughly 2,000 terawatt-hours of electricity a year. That’s over 100 times more electricity than all the world’s five million electric cars use each year.

Put in individual terms: this means the pro rata, average electricity used by each smartphone is greater than the annual energy used by a typical home refrigerator. And all such estimates are based on the state of affairs of a few years ago.

A more digital future will inevitable use more energy

Some analysts now claim that even as digital traffic has soared in recent years, efficiency gains have now muted or even flattened growth in data-centric energy use. Such claims face recent countervailing factual trends. Since 2016, there’s been a dramatic acceleration in data center spending on hardware and buildings along with a huge jump in the power density of that hardware.

Regardless of whether digital energy demand growth may or may not have slowed in recent years, a far faster expansion of the cloud is coming. Whether cloud energy demand grows commensurately will depend in large measure in just how fast data use rises, and in particular what the cloud is used for. Any significant increases in energy demand will make far more difficult the engineering and economic challenges of meeting the cloud’s central operational metric: always available.

More square feet of data centers have been built in the past five years than during the entire prior decade. There is even a new category of “hyperscale” data centers: silicon-filled buildings each of which covers over one million square feet. Think of these in real-estate terms as the equivalent to the dawn of skyscrapers a century ago. But while there are fewer than 50 hyper-tall buildings the size of the Empire State Building in the world today, there are already some 500 hyperscale data centers across the planet. And the latter have a collective energy appetite greater than 6,000 skyscrapers.

We don’t have to guess what’s propelling growth in cloud traffic. The big drivers at the top of the list are AI, more video and especially data-intense virtual reality, as well as the expansion of micro data centers on the “edge” of networks.

Until recently, most news about AI has focused on its potential as a job-killer. The truth is that AI is the latest in a long line of productivity-driving tools that will replicate what productivity growth has always done over the course of history: create net growth in employment and more wealth for more people. We will need a lot more of both for the COVID-19 recovery. But that’s a story for another time. For now, it’s already clear that AI has a role to play in everything from personal health analysis and drug delivery to medical research and job hunting. The odds are that AI will ultimately be seen as a net “good.”

In energy terms though, AI is the most data hungry and power intensive use of silicon yet created — and the world wants to use billions of such AI chips. In general, the compute power devoted to machine learning has been doubling every several months, a kind of hyper version of Moore’s Law. Last year, Facebook, for example, pointed to AI as a key reason for its data center power use doubling annually.

In our near future we should also expect that, after weeks of lockdowns experiencing the deficiencies of video conferencing on small planar screens, consumers are ready for the age of VR-based video. VR entails as much as a 1000x increase in image density and will drive data traffic up roughly 20-fold. Despite fits and starts, the technology is ready, and the coming wave of high-speed 5G networks have the capacity to handle all those extra pixels. It requires repeating though: since all bits are electrons, this means more virtual reality leads to more power demands than are in today’s forecasts.

Add to all this the recent trend of building micro-data centers closer to customers on “the edge.” Light speed is too slow to deliver AI-driven intelligence from remote data centers to real-time applications such as VR for conferences and games, autonomous vehicles, automated manufacturing, or “smart” physical infrastructures, including smart hospitals and diagnostic systems. (The digital and energy intensity of healthcare is itself already high and rising: a square foot of a hospital already uses some five-fold more energy than a square foot in other commercial buildings.)

Edge data centers are now forecast to add 100,000 MW of power demand before a decade is out. For perspective, that’s far more than the power capacity of the entire California electric grid. Again, none of this was on any energy forecaster’s roadmap in recent years.

Will digital energy priorities shift?

Which brings us to a related question: Will cloud companies in the post-coronavirus era continue to focus spending on energy indulgences or on availability? By indulgences, I mean those corporate investments made in wind/solar generation somewhere else (including overseas) other than to directly power one’s own facility. Those remote investments are ‘credited’ to a local facility to claim it is green powered, even though it doesn’t actually power the facility.

Nothing prevents any green-seeking firm from physically disconnecting from the conventional grid and building their own local wind/solar generation – except that to do so and ensure 24/7 availability would result in a roughly 400 percent increase in that facility’s electricity costs.

As it stands today regarding the prospects for purchased indulgences, it’s useful to know that the global information infrastructure already consumes more electricity than is produced by all of the world’s solar and wind farms combined. Thus there isn’t enough wind/solar power on the planet for tech companies — much less anyone else — to buy as ‘credits’ to offset all digital energy use.

The handful of researchers who are studying digital energy trends expect that cloud fuel use could rise at least 300 percent in the coming decade, and that was before our global pandemic. Meanwhile, the International Energy Agency forecasts a ‘mere’ doubling in global renewable electricity over that timeframe. That forecast was also made in the pre-coronavirus economy. The IEA now worries that the recession will drain fiscal enthusiasm for expensive green plans.

Regardless of the issues and debates around the technologies used to make electricity, the priority for operators of the information infrastructure will increasingly, and necessarily, shift to its availability. That’s because the cloud is rapidly becoming even more inextricably linked to our economic health, as well as our mental and physical health.

All this should make us optimistic about what comes on the other side of the recovery from the pandemic and unprecedented shutdown of our economy. Credit Microsoft, in its pre-COVID 19 energy manifesto, for observing that “advances in human prosperity … are inextricably tied to the use of energy.” Our cloud-centric 21st century infrastructure will be no different. And that will turn out to be a good thing.

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How Carl Pope helped drive a $500 million pledge to push the U.S. “Beyond Carbon” (Part 2)

Billionaire businessman and philanthropist Michael Bloomberg recently pledged to rapidly spend $500 million in a bid to push the U.S. “Beyond Carbon,” aiming to end this country’s use of coal and natural gas power in a generation or less.

In another recent piece, I featured an in-depth interview with Carl Pope, the veteran environmental leader who has essentially been the inspirational force behind Bloomberg’s evolution. The former New York City Mayor had never given a major gift to environmental causes as of a decade or so ago, until Pope “convinced” him to get involved.

Carl Mike Option 1

My previous piece was an attempt to understand the ethical vision influencing Bloomberg’s work, by looking at Pope’s personal story and the history of the environmental movement he has helped to shape. Below, Pope joins me again to look at the details of Bloomberg’s “Beyond Carbon” plan, including how he was able to persuade Bloomberg to take it on, and some areas of controversy that could arise as the $500 million is distributed.

Greg Epstein: You and Michael Bloomberg met around a decade ago or so, right?

Carl Pope: About 12 years ago, actually. 2007.

Epstein: Bloomberg had never given a major gift to an environmental group before he met you, and, as he writes in the book, you “convinced him” to get massively involved, to the tune now of many hundreds of millions of dollars. What do you think it is about you, the way that you approach things, or the work you do that made the two of you, in this relatively unlikely partnership, work so well?

Pope: We both like big ideas, and we both like to pursue them very pragmatically. We set very high expectations for what we want to get, and we’re willing to take necessarily small steps to get there. That’s one thing.

The second thing is, my original environmental frame was air pollution, [which] I worked on the first seven or eight years I was an environmentalist. Mike is a big public health advocate. So the fact that I was talking about saving people’s lives made a lot of sense to him.

Epstein: He talked about how you ‘showed him the numbers,’ back in 2011, on just how deadly coal actually is.

Pope: Yeah, that was the deal sealer.

Epstein: Interpersonally, what the interactions between you and him like?

Pope: We’re both public figures who are actually somewhat introspective, and so it works.

Epstein: I’ve read the “Beyond Carbon” plans as they’re presented by the Bloomberg organization. They do seem quite promising as far as broad, sweeping PR statements go.

But whether or not they will work is all in the details, right? You’re a detail-oriented person, as you just mentioned, so, what are some of the practical steps the plan calls for that you think deserve the most attention, beyond the headlines?

Pope: In A Climate of Hope, Mike and I articulated an approach to climate in which we gave our reasons for thinking that most climate leadership is going to come not from national governments but from businesses, cities, provinces, civic organizations, from the bottom up.

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The climate is our biggest threat. Carl Pope is fighting to change our fate

Michael Bloomberg is an unrepentant capitalist who, as he says in his 2017 book A Climate of Hope, is “not exactly your stereotypical environmentalist.” Yet over the past decade, Bloomberg has become arguably the biggest environmental philanthropist in the world — especially given the $500 million investment Bloomberg announced last month that he would soon make in rapidly moving the U.S. “Beyond Carbon,” off both coal and natural gas and to a “100% clean energy economy.” How did this happen?

It turns out one of the biggest factors in Bloomberg’s green transformation has been his friendship with Carl Pope, the longtime former head of the Sierra Club, whom Bloomberg first met about a decade ago, as Mayor of New York.

Carl Pope Headshot

Pope is not exactly a household name, but nonetheless at this point can probably be called one of the most influential environmental activists in history. He wears a leather jacket and a weathered-looking sweater on the cover of Climate of Hope alongside Bloomberg’s suit, tie, and flag pin.

The two co-authored the book — and not just in the sense that Pope ghost-wrote Bloomberg’s opinions, as happens regularly when busy political and cultural celebrities take on a lesser-known co-author for some glamour project they may barely even read. A Climate of Hope is an extended dialogue between Bloomberg and Pope, with the two alternating chapters throughout and at times even disagreeing on potentially important issues.

What there’s no disagreement on, however, is that Pope “convinced” his co-author to dive into massive environmental spending (a feat accomplished in part by showing the health-conscious Bloomberg the numbers on how lethal coal can be).

Pope is no stranger to controversy — perhaps unsurprising for a nonprofit leader who has raised money well into the nine figures. He’s a “pragmatist,” as he says many times in the interview below, which depending on who you ask either means compromise to the point of being compromised, or simply that he has a knack for actually getting things done where others merely talk.

His legacy has previously been associated with taking money from natural gas executives in a fundraising bid some saw as necessary and others called ethically tainted; with overlooking people’s polluting individual choices to buy large cars and even bigger homes; and with “looking forward to an active partnership” with Republican leaders when it was obvious they weren’t completely on board with key tenets of the environmental movement.

But Pope has also been equally or better known for pushing the Clinton/Gore administration to be better on emissions; preventing neoliberal environmentalists from adopting a nativist stance on immigration; championing a more diverse and inclusive environmental movement; and now, of course, with potentially ending the use of carbon fuel in America.

Despite 30+ years in the public eye, Carl Pope is a relatively private person who doesn’t seem to like to talk much about himself. So for starters below, I wanted to see if I could figure out what makes him tick.

Because if we could get into the heads of people who persuade billionaires to act against their short-term economic interests, with the bigger human picture in mind, maybe we could do it more often.

Then our conversation moved on to NASA, Ro Khanna, Tesla, AOC and the Green New Deal, and more. And in a soon to come follow up piece, I’ll talk with Pope about the details of the Beyond Carbon plan, including how he was able to persuade Bloomberg to take it on, and some areas of controversy that could arise as the $500 million is distributed.

All of this, after all, is part of what it means to think about the ethics of technology — Pope and Bloomberg’s work, love it or not, is certainly an attempt to reform or transform some of the most influential technologies human hands have ever touched.

How do we motivate people of all backgrounds and means to help make changes for the greener? How do we know what the right changes are to make? How do we grapple with the ethical dilemmas involved and the compromises that can seem to be required?

(Oh and by the way: in the weeks since I spoke with Pope, I have mostly been skipping big evening meals and eating more healthily in the afternoon. So at least there’s that!)

Carl Mike

Greg Epstein: I have enjoyed discovering you as —  I would even say as a historical figure, though important parts of your story are yet to be told.

I’d like to hear a bit about the key developments in your life that gave you the ethical perspective that you have.

Carl Pope: I can tell you some things about my childhood and my formation. Which particular ingredients formed my ethical perspective, I’m not sure I’ll be able to tell you, but I’ll tell you some things [that might] help.

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London’s mayor announces £1.6M clean tech incubator

 London’s Mayor Sadiq Khan has announced a clean tech incubator aimed at sparking a new startup cluster in the UK capital focused on helping to foster the development of low-carbon and clean-tech products which are aimed at tackling the causes and effects of climate change. Read More

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