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Top 20 Green Tech IdeasDirectorate of Planning for Agribusiness and Natural ResourcesDeputy of Investment PlanningIndonesia Investment Coordinating Board
2010
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Recycling e-Waste
e-Waste is the fastest growing part of the solid waste stream, and some 20 to 50 million metric tons of it are thrown out every year
There are ways to recycle e-waste, reducing the need to mine more of the metals that go into high-tech items, and preventing the environmental consequences of poorly processed electronics
CloudBlue, based in New Jersey, helps tech companies take care of their e-waste, arranging for direct pickup and processing, ensuring that valuable metals can be reused and recycled for future electronics
For customers like banks that have to worry about sensitive data that might be encoded on old computers, CloudBlue can also process the waste onsite
CloudBlue can ensure that no e-waste will ever end up in a landfill — or worse, poisoning a child in Africa or China
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Algae Biofuel
The biggest renewable energy business in the U.S is plain old corn ethanol, but study after study has shown that high levels of corn ethanol production simply aren't sustainable
One of the best options on the horizon is bio-fuel made from algae, which counters a lot of the problems with corn ethanol.
Algae do not need farmland to grow: tanks will do the job just fine anywhere there is spare land and a decent amount of sunshine
Algae also grow much faster than traditional crops, and the micro-organisms may be able to use wastewater or even saline water during their development, rather than fresh water.
Startups like Sapphire Energy and Algenol in California and Florida are passing the pilot phase and nearing commercial development; they just need a little government help
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Algae Food
For something that looks like pond scum, algae are extremely useful.
Solazyme is working to create algae biofuel for cars, trucks and planes. Unfortunately, that market has yet to materialize, and because fuel is such a low-margin business, companies like Solazyme will need to sell a lot of their product before they can begin making a profit.
But Solazyme's chemists stumbled on another use for their algae: food
The company's living products can be used to replace the eggs, butter and oil in cakes, cookies and more
Snacks that taste like snacks, but lower in fat calories and higher in protein
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Thin-Film Solar
Two factors will make solar power more competitive on the energy market. One is efficiency — the percentage of the sun's energy that a solar panel can convert into electricity. The other is price
Many solar panels in use today — the crystalline silicon arrays on rooftops — focus on efficiency while costing more.
But there's another way to make solar panels: thin-film. The technology uses much less silicon, which means that the average efficiency of those panels is less than arrays using crystalline silicon.
But the very fact that thin-film panels use less silicon makes them much cheaper and faster to produce.
That combination has helped thin-film companies like first Solar of Tempe, Arizona, and Nanosolar of San Jose emerge as early clean tech titans.
Publicly traded First Solar is one of the most successful renewable energy firms in the world today. The future of solar looks thin.
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Molten Salt Storage
Renewable energy has many advantages, but wind and solar face one major problem: intermittency. When the wind doesn't blow and the sun doesn't shine, there's no way to store the electricity they do produce during peak times if it's not being used. That's a serious obstacles since utilities need to provide enough electricity to meet demand at all times.
But utility-scale solar companies are working on ways to store the energy they produce during the brightest days. One option: molten salt.
It can be used in solar thermal, which employs powerful mirrors to focus the sun's heat to create steam, driving an electric turbine.
The surplus heat produced during the day can be used to warm up massive amounts of salt, which can absorb significant amounts of heat.
When the sun goes down — or when it's simply cloudy — that heat can be used to generate steam and run an electric turbine.
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Solar Tower
There are two ways to harness energy from the sun. One is through photovoltaic panels, which transform sunlight directly to electricity. The second form — called solar thermal or concentrated solar power — that has the most potential for utility-scale power generation.
In fact, there are already solar thermal plants operating in the deserts of Nevada and California, using low rows of curved mirrors to concentrate sunlight.
Bill Gross at eSolar thinks that he can improve on that fairly basic technology. Instead of rows of mirrors, eSolar uses vertical mirrored towers of that perfectly concentrate sunlight on a ground target.
Using sophisticated software, the mirrors perfectly track the sun as it crosses the sky, maximizing the amount of electricity that can be produced.
The result is a relatively compact but power utility-scale plant that gets the most out of that free source of energy called the sun.
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Custom Biofuels
First-generation biofuels are limited: corn ethanol packs less energy per gallon than petroleum, and new fuels like biodiesel often can't be used in car engines without expensive technical conversions. There is a trillion-dollar infrastructure already in place around petroleum, and changing it won't be easy or cheap.
But what if you could adapt biofuels to use our current infrastructure, not the other way around? That's what a handful of biotech companies are doing right now.
Amyris and LS9 are using the tools of biotechnology to produce new biofuels that are sustainable and ready for use in our cars and trucks right now.
The companies create custom microbes in the lab that can produce biofuels to order — even "green crude" that has most of the benefits of petroleum without the drawbacks.
The technology is still a long way from commercial scale, but it provides some of the best hopes for a biofuelled future.
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Electric Cars
Electric cars have been around since the dawn of the automobile. But the electric car lost out to gasoline-powered ones for good reasons: gasoline carries a lot of power per gallon, while batteries never had the capacity to move cars very far.
Even in the 1990s, with the introduction of improved electrics like GM's lamentedly discontinued EV1, battery-powered cars remained a fetish for those who value their carbon footprint over convenience.
GM's long-awaited Volt — not a pure electric but a plug-in hybrid — is finally set to go on sale at the end of 2010.
The Japanese car company Nissan is going one better with its all-electric Leaf and Ford and Toyota have electrics in the works as well.
Smaller startups are experimenting with ultra-efficient electric cars, while the innovative company Better Place is installing networks of battery-charging stations in Israel for its own electric transportation system, with a subscription payment system modeled on the wireless industry.
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Smart Meters
Our electrical devices may be 21st century, but the electrical grid we plug them into is strictly 20th. The grid is inefficient and prone to breakdowns.
Improving the grid is going to be a vital part of helping clean energy scale up: better transmission lines are needed to carry wind-generated electricity from the middle of the U.S. to the more heavily populated coasts.
But the first installment on a smarter gird will be smarter meters. Right now the electric meter in your home tells you only the most basic information.
The majority of utilities won't even know that homes have lost power in a blackout until enough annoyed customers call them.
But smart meters connected to a network can relay that sort of information instantly, giving utilities and customers alike a real-time picture of how much power is being used at any given moment. And as new appliances are networked into smart meters, we'll be able to use them much more efficiently.
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Lithium-Ion Batteries
The electronics of the 1990s — and most hybrid cars today — used nickel-ion batteries for power. They were an upgrade over the lead batteries used in the past, but they weren't strong enough to power electric cars for long distances.
Lithium-ion batteries are a potential game-changer. If you use a laptop or a mobile phone, chances are you already own a lithium-ion battery.
Lithium-ion batteries can pack more power in a smaller case, so the battery for GM's plug-in hybrid Volt is tiny compared to the gigantic power pack that had been used on its EV1.
A smaller battery is also lighter, which reduces the weight of the electric car and the power needed to drive it.
The price on lithium-ion batteries still needs to come down — a battery for a new electric car can cost more than $10,000. But battery-making companies like A123 Systems in Massachusetts are already emerging as the future titans of a clean energy economy.
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Fuel Cells
Inventors have tried to use hydrogen fuel cells as a cleaner way to create electricity commercially. Honda and other car companies have made hydrogen fuel cell-powered cars, but they've always been limited by the cost.
That's beginning to change, however, thanks to a California startup called Bloom Energy. The company exploded onto the public scene with the release of its Bloom Box, a system that uses fuel cell technology to provide off-the-grid power.
The Bloom Boxes — about half the size of a shipping container — use solid oxide fuel cells, which generate electricity by oxidizing natural gas.
The technology has existed for awhile, but Bloom figured out how to carry out the reaction at a relatively low temperature, making the Bloom Boxes safe to use in corporate offices by companies like Google and eBay that can use the lower carbon power as an off-the-grid back up to conventional grid electricity and as a way to reduce their own carbon footprint.
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Rooftop Wind Power
The startup Windtronics is developing mini-wind turbines that can be installed on any flat root, either alone or in larger arrays.
Each turbine measures about 6 ft. in diameter and looks like a large, circular window fan, but it can generate an average of 1,500 KW/h a year, with more or less depending on wind strength.
And unlike utility-scale turbines, the Windtronic turbine contains no rotating gearbox to generate electricity, and is thus much quieter.
In an ordinary wind turbine, the blades moves the gears, the gears turn a generator, and the generator creates electricity.
With a Windtronics model, the blades are equipped with magnets at the tips and are enclosed in a wheel that contains coiled copper, so the entire turbine is an electric generator.
That makes the Windtronics turbine silent — something your neighbors will appreciate.
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Tidal Power
Tides are the winds of the oceans, generating a tremendous amount of kinetic energy that can be tapped with the right kind of technology.
In fact, tides might be better than wind, since they're much more predictable. And while the best wind resources tend to be located far from major population centers, most of the big cities around the world are located right next to the water.
The problem has always been that building turbines and other infrastructure is significantly more expensive underwater than on land, since salts can erode equipment and maintenance is a challenge.
The technology works the same way a wind turbine does: the steady movement in and out of the tides turns an underwater turbine, which generates electricity. And as with wind, there are some parts of the world that are particularly rich in tidal potential, like the Bay of Fundy in Canada
New York City's tides are a lot calmer, but the city does have potential for tidal power, and companies like Verdant are tapping it.
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Green IT
Computers seem so clean, but of course computers need power, and right now most of our power comes from fossil fuels.
Computers and IT are now a small but rapidly growing source of carbon — about 2% of global emissions, a figure that could easily double within a decade.
That's where green IT comes in. Whether it's more energy-efficient laptops and server farms, or software that automatically powers down our desktops when they're not being used, there are ways to curb the IT sector's energy hunger ways without losing performance.
Software like Granola, for example, can run in the background of your operating system and tune up your computer's own energy-saving hardware, ensuring you're not wasting volts unnecessarily. There's no reason you can't get all the computing power you need without wasting power.
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Green Concrete
Making cement for concrete is extremely energy-intensive. That process generates a lot of carbon dioxide: manufacturing one metric ton of cement releases 650 to 920 kilograms of CO2.
The nearly 3 billion metric tons of cement that were produced worldwide last year accounted for about 5% of all CO2 emissions.
The company Hycrete had reformulated the products used to waterproof concrete in a way that allows for recycling in the future, reducing the lifetime energy footprint of a building.
The London-based startup Novacem is going further, working on a new cement production method that would actually absorb more CO2 than it releases, by substituting cabon-rich limestone with magnesium silicates that contain no stored carbon.
As the cement hardens, CO2 in the air actually reacts to make solid carbonates that strengthen the cement while holding onto the gas.
Novacem can't yet use its process on a commercial scale, but if it can, concrete could become carbon negative.
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Green Building Materials
Green architecture has gone from a niche interest to a major design industry. Massive skyscrapers like the new Bank of America headquarters in midtown Manhattan advertise their energy efficiency, particularly their score on the Leadership in Energy and Environmental Design (LEED) scale.
What MPG is for cars, LEED is for buildings. Sustainability has even become a point of competition among mega-mansion owners, with multi-millionaires in California jostling to build the greenest house in America.
Much of green architecture comes from design — making use of natural light and other features to cut down on energy waste; but smarter building materials can make a difference as well.
Companies like Serious Materials produce highly efficient windows, insulation and other building features that reduce the amount of heat lost to the outside.
Built right, "passive houses" can even be so energy efficient that they require no outside heat at all, bringing energy bills close to zero.
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Modular Nuclear Power
There's no ignoring the fact that nuclear is the only utility-scale, non-intermittent electricity source that doesn't emit carbon.
If you replaced all of the U.S.'s nuclear plants — which supply about a fifth of the nation's electricity — with coal plants, carbon emissions would skyrocket.
Nuclear power plants are incredibly expensive investments, and right now few utilities would take on the financial risk of building one, or get banks to lend them the necessary capital, even with additional government aid.
But what if you could shrink the size of a nuclear plant? That's what companies like NuScale Power and Babcock & Wilcox are trying to do.
By building a modular plant that might be a quarter the size of a the current multi-gigawatt operations, it's possible to reduce the capital expenditures needed to start construction and cut the risk that would be associated with an accident.
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Artificial Photosyntesis
Plants with green leaves are able to capture the sun's energy and turn it into useful chemical fuel in a process that is much, much more efficient than our best photovoltaic solar panels.
That's why there are a number of scientists working on creating artificial photosynthesis.
Daniel Nocera, an energy expert at the Massachusetts Institute of Technology, is pushing a form of artificial photosynthesis that would create electricity that would then be harnessed to produce hydrogen for use in fuel cells.
That's only one way to harness photosynthesis, but already startups like Joule Biotechnologies are looking for ways to take it commercial.
The future has to be solar-powered; the question will be how best to harness that free source of energy.
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Waste to Energy
One simple way is to burn trash, and use the heat to generate steam that can run an electric turbine.
But that method has significant drawbacks; not all garbage burns, of course, and the waste that does will often produce heavy emissions, including dangerous and sometimes carcinogenic dioxins.
So right now most of our non-recyclable waste — and a lot of waste that is recyclable — ends up buried beneath the ground.
But there are companies working on smarter ways to recycle our trash. Costaka has pioneered technology that can turn biomass waste such as grass or woodchips into gas and eventually into ethanol. Their process uses less water and has a smaller carbon footprint than traditional ethanol.
The Canadian company Enerkem has a similar process, but the firm has gone further, able to build standardized, easy-to-install plants that allow any municipality to begin turning garbage into cleaner biofuel.
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Biochar
Plants absorb carbon dioxide as long as they're alive, but once they're cut down or burned, that carbon is released back into the atmosphere.
Keeping trees standing — especially in tropical areas — is one way to save that carbon. But if plants are cut down, perhaps for agriculture, and you burn the residue in a controlled, low-oxygen atmosphere — a simple process called pyrolysis — you can create charcoal, a stable and solid form of carbon.
If you then mix the biochar with certain soils, you can also reduce the amount of methane and nitrous oxide, both of them greenhouse gases, that the soil would naturally release.
The result is a two-for-one carbon cutting special, and the potential is tremendous.
A recent study in Nature Geoscience found that biochar could offset 12% of global carbon emissions.
The challenge is that biochar has relatively little value on its own, so there's not much business case for making the product right now. That's one more reason a carbon price would be so useful.
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“You may have to look hard, but some very smart companies are doing some very creative things when it comes to the environment”
