Wind turbines are one of the fastest growing industries thanks to their ability to provide clean, renewable energy. And while most designs are trending towards larger and larger sizes and power yields, some are looking in the opposite direction. By equipping everyday objects with tiny windmills, we just might find our way towards a future where batteries are unnecessary.
Professor J.C. Chiao and his postdoc Dr. Smitha Rao of the University of Texas at Arlington are two individuals who are making this idea into a reality. Their new MEMS-based nickel alloy windmill is so small that 10 could be mounted on a single grain of rice. Aimed at very-small-scale energy harvesting applications, these windmills could recharge batteries for smartphones, and directly power ultra-low-power electronic devices.
These micro-windmills – called horizontal axis wind turbines – have a three-bladed rotor that is 1.8 mm in diameter, 100 microns thick, and are mounted on a tower about 2 mm tall mount. Despite their tiny size, the micro-windmills can endure strong winds, owing to being constructed of a tough nickel alloy rather than silicon, which is typical of most microelectromechanical systems (MEMS), and a smart aerodynamic design.
According to Dr. Rao, the problem with most MEMS designs is that they are too fragile, owing to silicon and silicon oxide’s brittle nature. Nickel alloy, by contrast, is very durable, and the clever design and size of the windmill means that several thousands of them could be applied to a single 200 mm (8 inch) silicon wafer, which in turn makes for very low cost-per-unit prices.
The windmills were crafted using origami techniques that allow two-dimensional shapes to be electroplated on a flat plane, then self-assembled into 3D moving mechanical structures. Rao and Chiao created the windmill for a Taiwanese superconductor company called WinMEMS, which developed the fabrication technique. And as Rao stats, they were interested in her work in micro-robotics:
It’s very gratifying to first be noticed by an international company and second to work on something like this where you can see immediately how it might be used. However, I think we’ve only scratched the surface on how these micro-windmills might be used.
Chiao claims that the windmills could perhaps be crafted into panels of thousands, which could then be attached to the sides of buildings to harvest wind energy for lighting, security, or wireless communication. So in addition to wind tunnels, large turbines, and piezoelectric fronds, literally every surface on a building could be turned into a micro-generator.
Powered by the wind indeed! And in the meantime, check out this video from WinMEMS, showcasing one of the micro-windmills in action:
There have been many new developments in the field of solar technology lately, thanks to new waves of innovation and the ongoing drive to make the technology cheaper and more efficient. At the current rate of growth, solar power is predicted to become cheaper than natural gas by 2025. And with that, so many opportunities for clean energy and clean living will become available.
Though there are many contributing factors to this trend, much of the progress made of late is thanks to the discovery of graphene. This miracle material – which is ultra-thin, strong and light – has the ability to act as a super capacitor, battery, and an amazing superconductor. And its use in the manufacture of solar panels is leading to record breaking efficiency.
Back in 2012, researchers from the University of Florida reported a record efficiency of 8.6 percent for a prototype solar cell consisting of a wafer of silicon coated with a layer of graphene doped with trifluoromethanesulfonyl-amide (TFSA). And now, another team is claiming a new record efficiency of 15.6 percent for a graphene-based solar cell by ditching the silicon all together.
And while 15.6 efficiency might still lag behind certain designs of conventional solar cells (for instance, the Boeing Spectrolabs mass-production design of 2010 achieved upwards of 40 percent), this represents a exponential increase for graphene cells. The reason why it is favored in the production of cells is the fact that compared to silicon, it is far cheaper to produce.
Despite the improvements made in manufacturing and installation, silicon is still expensive to process into cells. This new prototype, created by researchers from the Group of Photovoltaic and Optoelectronic Devices (DFO) – located at Spain’s Universitat Jaume I Castelló and the University of Oxford – uses a combination of titanium oxide and graphene as a charge collector and perovskite to absorb sunlight.
As well as the impressive solar efficiency, the team says the device is manufactured at low temperatures, with the several layers that go into making it being processed at under 150° C (302° F) using a solution-based deposition technique. This not only means lower potential production costs, but also makes it possible for the technology to be used on flexible plastics.
What this means is a drop in costs all around, from production to installation, and the means to adapt the panel design to more surfaces. And considering the rate at which efficiency is being increased, it would not be rash to anticipate a range of graphene-based solar panels hitting the market in the near future – ones that can give conventional cells a run for their money!
However, another major stumbling block with solar power is weather, since it requires clear skies to be effective. For some time, the idea of getting the arrays into space has been proposed as a solution, which may finally be possible thanks to recent drops in the associated costs. In most cases, this consists or orbital arrays, but as noted late last year, there are more ambitious plans as well.
Take the Japanese company Shimizu and it’s proposed “Luna Ring” as an example. As noted earlier this month, Shimizu has proposed creating a solar array some 400 km (250 miles) wide and 11,000 km (6,800 miles) long that would beam solar energy directly to Earth. Being located on the Moon and wrapped around its entirety, this array would be able to take advantage of perennial exposure to sunlight.
Cables underneath the ring would gather power and transfer it to stations that facing Earth, which would then beam the energy our way using microwaves and lasers. Shimizu believes the scheme, which it showed off at a recent exhibition in Japan, would virtually solve our energy crisis, so we never have to think about fossil fuels again.
They predict that the entire array could be built and operational by 2035. Is that too soon to hope for planetary energy independence? And given the progress being made by companies like SpaceX and NASA in bringing the costs of getting into space down, and the way the Moon is factoring into multiple space agencies plans for the coming decades, I would anticipate that such a project is truly feasible, if still speculative.
Combined with increases being made in the fields of wind turbines, tidal harnesses, and other renewable energy sources – i.e. geothermal and piezoelectric – the future of clean energy, clear skies and clean living can’t get here soon enough! And be sure to check out this video of the Luna Ring, courtesy of the Shimizu corporation:
Space is becoming a very interesting place, thanks to numerous innovations that are looking ahead to the next great leap in exploration. With the Moon and Mars firmly fixed as the intended targets for future manned missions, everything from proposed settlements and construction projects are being plotted, and the requisite tools are being fashioned.
For instance, the Shimizu Corporation (the designers of the Shimizu Mega-City Pyramid), a Japanese construction firm, has proposed a radical idea for bringing solar energy to the world. Taking the concept of space-based solar power a step further, Shimizu has proposed the creation of a “Luna Ring” – an array of solar cells around the Moon’s 11000 km (6800 mile) equator to harvest solar energy and beam it back to Earth.
The plan involves using materials derived from lunar soil itself, and then using them to build an array that will measure some 400 km (250 miles) thick. Since the Moon’s equator receives a steady amount of exposure to the Sun, the photovoltaic ring would be able to generate a continuous amount of electricity, which it would then beam down to Earth from the near side of the Moon.
It’s an ambitious idea that calls for assembling machinery transported from Earth and using tele-operated robots to do the actual construction on the Moon’s surface, once it all arrives. The project would involve multiple phases, to be spread out over a period of about thirty years, and which relies on multiple strategies to make it happen.
For example, the firm claims that water – a necessary prerequisite for construction – could be produced by reducing lunar soil with hydrogen imported from Earth. The company also proposes extracting local regolith to fashion “lunar concrete”, and utilizing solar-heat treatment processes to fashion it into bricks, ceramics, and glass fibers.
The remotely-controlled robots would also be responsible for other construction tasks, such as excavating the surrounding landscape, leveling the ground, laying out solar panel-studded concrete, and laying embedded cables that would run from the ring to a series of transmission stations located on the Earth-facing side of the Moon.
Power could be beamed to the Earth through microwave power transmission antennas, about 20 m (65 ft) in diameter, and a series of high density lasers, both of which would be guided by radio beacons. Microwave power receiving antennas on Earth, located offshore or in areas with little cloud cover, could convert the received microwave power into DC electricity and send it to where it was needed.
The company claims that it’s system could beam up to 13,000 terawatts of power around-the-clock, which is roughly two-thirds of what is used by the world on average per year. With such an array looming in space, and a few satellites circling the planet to pick up the slack, Earth’s energy needs could be met for the foreseable future, and all without a single drop of oil or brick of coal.
The proposed timeline has actual construction beginning as soon as 2035.
And naturally, when manned missions are again mounted into space, the crews will need the proper equipment to live, thrive and survive. And since much of the space suit technology is several decades old, space agencies and private companies are partnering to find new and innovative gear with which to equip the men and women who will brave the dangers of space and planetary exploration.
Consider the Biosuit, which is a prime example of a next-generation technology designed to tackle the challenges of manned missions to Mars. Created by Dava Newman, an MIT aerospace engineering professor, this Spiderman-like suit is a sleeker, lighter alternative to the standard EVA suits that weigh approximately 135 kilograms (300 pounds).
For over a decade now, Newman has been working on a suit that is specifically designed for Mars exploration. At this year’s TEDWomen event in San Francisco, she showcased her concept and demonstrated how its ergonomic design will allow astronauts to explore the difficult terrain of the Red Planet without tripping over the bulk they carry with the current EVA suits.
The reason the suit is sleek is because it’s pressurized close to the skin, which is possible thanks to tension lines in the suit. These are coincidentally what give it it’s Spiderman-like appearance, contributing to its aesthetic appeal as well. These lines are specifically designed to flex as the astronauts ends their arms or knees, thus replacing hard panels with soft, tensile fabric.
Active materials, such as nickel-titanium shape-memory alloys, allow the nylon and spandex suit to be shrink-wrapped around the skin even tighter. This is especially important, in that it gets closer Newman to her goal of designing a suit that can contain 30% of the atmosphere’s pressure – the level necessary to keep someone alive in space.
Another benefit of the BioSuit is its resiliency. If it gets punctured, an astronaut can fix it with a new type of space-grade Ace Bandage. And perhaps most importantly, traditional suits can only be fitted to people 5′ 5″ and taller, essentially eliminating short women and men from the astronaut program. The BioSuit, on the other hand, can be built for smaller people, making things more inclusive in the future.
Newman is designing the suit for space, but she also has some Earth-bound uses in mind . Thanks to evidence that showcases the benefits of compression to the muscles and cardiovascular system, the technology behind the Biosuit could be used to increase athletic performance or even help boost mobility for people with cerebral palsy. As Newman herself put it:
We’ll probably send a dozen or so people to Mars in my lifetime. I hope I see it. But imagine if we could help kids with CP just move around a little bit better.
With proper funding, Newman believes she could complete the suit design in two to three years. It would be a boon to NASA, as it appears to be significantly cheaper to make than traditional spacesuits. Funding isn’t in place yet, but Newman still hopeful that the BioSuit will be ready for the first human mission to Mars, which are slated for sometime in 2030.
In the meantime, enjoy this video of the TEDWomen talk featuring Newman and her Biosuit demonstration:
It’s no secret that wind power is one of main clean forms of energy that is being considered as a viable alternative to coal, oil and gas. But much like solar, tidal and geothermal, the method has some flaws that is preventing it from being adopted in a more widespread fashion. However, as an infinitely renewable source of energy, it likely just a matter of time before technical developments lead to its wholesale use.
The first challenge has to do with size. Currently, wind farms are massive operations, and many designers think they need to continue to get bigger in order to generate the kinds of electricity we currently need. However, a Netherlands-based startup named Ampyx Power is looking in another direction: an airborne wind turbine that they think could capture the same amount of energy as a large operation.
Basically, their design is a small glider plane attached by cable to a generator, which is then deployed into the air and flies in figure eights. As it moves, the glider pulls on the capable, and the generator converts the movement to electricity. Since it isn’t attached to a tower, it can soar nearly 2,000 feet in the air, catching stronger winds that produce about eight times more energy than the lower-altitude breezes that reach a normal wind turbine.
So in addition to being able to produce more power than a typical wind farm, it costs significantly less than its competitor. The average wind farm weighs about 120 metric tons, while the glider system weighs in at a mere 363 kilograms (800 pounds). And in addition to being cheaper than other renewables, the process may even be cheaper than coal.
As Wolbert Allaart, the startup’s managing director, put it:
We’re replacing tons of steel and concrete. It’s a huge materials reduction, and we can produce the same amount of power. That obviously has an effect on cost as well… The whole reason why we’re doing this is because we think we can get the cost of a kilowatt-hour well below the price of coal.
And Ampyx is hardly alone in developing the technology. In fact, their design is similar to California-based Makani Power’s glider. This company was acquired by Google earlier this year, while Ampyx raised the necessary capital via a crowdfunding campaign. And though there are some differences in the design and methods employed, both companies dream of a day when wind will replace coal and other dirty means.
Because the planes are so efficient, places that might not have worked for wind power in the past – like forests, where trees catch and redirect the wind – could be a fit for the system, so the market is wide open. And given his country’s growing interest in wind power, Allaart hopes to introduce it to the domestic market very soon:
In Holland, where we’re based, we now have a 4.3 billion Euro subsidy scheme for offshore wind. People are starting to wonder already, if we have a technology being developed in our own country that could provide offshore wind at more or less competitive price with coal, why on Earth are we still subsidizing this so heavily? How fast this grows will depend on political will.
Another very cool wind-related story comes from Jakarta, where a massive tower is being planned that will be capable of generating all its own power. It’s known as the Pertamina Energy Tower, the proposed headquarters of the Pertamina power company. And while the proposed building will be 99 stories in height, it will also gather all its power from wind, solar, and geothermal energy.
When it comes to its wind operations, the building’s height plays to its advantage. At the top of the building, a funnel captures wind, sucks it inside, and speeds it up to run a series of vertical wind turbines. In this respect, the building operates like a giant, vertical wind tunnel. Solar energy will also be incorporated through panels that will cover the roofs of other buildings on the new campus.
But perhaps the most impressive feat comes in the form of geothermal, a type of energy that’s uniquely suited for Indonesia because it’s a volcanic island chain. Geothermal systems in Indonesia can tap directly into superheated sources of subterranean steam with a single pipe, unlike typical systems that are more complicated and expensive to engineer.
Scott Duncan, the director of Pertamina’s architecture firm – Skidmore, Owings & Merrill LLP (SOM) – who led the project, describes it this way:
It would essentially provide an unlimited energy source for the tower and campus and could make the tower the world’s first energy-positive supertall building.
In addition to meeting this clean-energy trifecta, the design of the tower is focused on saving energy as much generating it. Sun-shading “leaves” on two sides of the building cut glare and shade the brightest sunlight while still keeping the inside of the offices bright enough to avoid most artificial lighting. Instead of power-sucking air conditioners, the building uses water-based radiant cooling systems to keep the temperatures even.
Along with other strategies, the energy-saving design elements mean that the campus – which will include a mosque, a performing arts and exhibition center, and sports facilities along with the office space – can keep energy use low enough that renewable power may be able to cover its entire energy needs. In short, the building could prove to be a model of energy-independence.
However, the motivation for this project go beyond the altruistic, and involve a good many practical considerations. For starters, Jakarta still has an unreliable power grid, and if the campus generates its own power, work and play won’t get interrupted. The buildings also won’t have to rely on diesel fuel generators if the city’s power goes down.
The technology is expected to be adopted elsewhere, particularly China where wind power is expanding all the time. Indonesia, despite its easy access to geothermal energy, is not the windiest place in the world. Cities that are strategically located along coastlines or in elevated regions would find the wind tunnel feature that much more useful, reducing their dependence on the other two forms of energy.
What’s more, this building is in many respects what one would call an Arcology, and just happens to be the second one being planned for construction in the world today. The other, un-coincidentally enough, is China’s Shanghai Tower, a building that is one-third green space and a transparent second skin that surrounds the city in a protective air envelope that controls its internal temperature.
And with global energy prices increasing, the sources of easily-accessible oil disappearing, and atmospheric CO2 levels steadily rising, we can expect to see more buildings like these ones going up all around the world. We’re also likely to see more creative and innovative forms of power generation popping up in our backyards. Much like peak oil, centralized grids and dependence on unclean energy is disappearing…
And in the meantime, enjoy this video of the Ampyx Power glider in action:
With all of the world’s current problems, poverty, underdevelopment, terrorism, civil war, and environmental degradation, it’s easy to overlook how things are getting better around the world. Not only do we no longer live in a world where superpowers are no longer aiming nuclear missiles at each other and two-thirds of the human race live beneath totalitarian regimes; in terms of health, mortality, and income, life is getting better too.
So, in honor of the New Year and all our hopes for a better world, here’s a gander at how life is improving and is likely to continue…
1. Poverty is decreasing: The population currently whose income or consumption is below the poverty line – subsisting on less than $1.25 a day – is steadily dropping. In fact, the overall economic growth of the past 50 years has been proportionately greater than that experienced in the previous 500. Much of this is due not only to the growth taking place in China and India, but also Brazil, Russia, and Sub-Saharan Africa. In fact, while developing nations complain about debt crises and ongoing recession, the world’s poorest areas continue to grow.
2. Health is improving:
The overall caloric consumption of people around the world is increasing, meaning that world hunger is on the wane. Infant mortality, a major issue arising from poverty, and underdevelopment, and closely related to overpopulation, is also dropping. And while rates of cancer continue to rise, the rate of cancer mortality continue to decrease. And perhaps biggest of all, the world will be entering into 2014 with several working vaccines and even cures for HIV (of which I’ve made many posts).
3. Education is on the rise:
More children worldwide (especially girls) have educational opportunities, with enrollment increasing in both primary and secondary schools. Literacy is also on the rise, with the global rate reaching as high as 84% by 2012. At its current rate of growth, global rates of literacy have more than doubled since 1970, and the connections between literacy, economic development, and life expectancy are all well established.
4. The Internet and computing are getting faster:
Ever since the internet revolution began, connection speeds and bandwidth have been increasing significantly year after year. In fact, the global average connection speed for the first quarter of 2012 hit 2.6 Mbps, which is a 25 percent year-over-year gain, and a 14 percent gain over the fourth quarter of 2011. And by the second quarter of 2013, the overall global average peak connection speed reached 18.9 Mbps, which represented a 17 percent gan over 2012.
And while computing appears to be reaching a bottleneck, the overall increase in speed has increased by a factor of 260,000 in the past forty years, and storage capacity by a factor of 10,000 in the last twenty. And in terms of breaking the current limitations imposed by chip size and materials, developments in graphene, carbon nanotubes, and biochips are promising solutions.
5. Unintended pregnancies are down:
While it still remains high in the developing regions of the world, the global rate of unintended pregnancies has fallen dramatically in recent years. In fact, between 1995 and 2008, of 208 billion pregnancies surveyed in a total of 80 nations, 41 percent of the pregnancies were unintended. However, this represents a drop of 29 percent in the developed regions surveyed and a 20 percent drop in developing regions.
The consequences of unintended pregnancies for women and their families is well established, and any drop presents opportunities for greater health, safety, and freedom for women. What’s more, a drop in the rate of unwanted pregnancies is surefire sign of socioeconomic development and increasing opportunities for women and girls worldwide.
6. Population growth is slowing: On this blog of mine, I’m always ranting about how overpopulation is bad and going to get to get worse in the near future. But in truth, that is only part of the story. The upside is while the numbers keep going up, the rate of increase is going down. While global population is expected to rise to 9.3 billion by 2050 and 10.1 billion by 2100, this represents a serious slowing of growth.
If one were to compare these growth projections to what happened in the 20th century, where population rose from 1 billion to just over 6, they would see that the rate of growth has halved. What’s more, rates of population growth are expecting to begin falling in Asia by 2060 (one of the biggest contributors to world population in the 20th century), in Europe by 2055, and the Caribbean by 2065.
In fact, the only region where exponential population growth is expected to happen is Africa, where the population of over 1 billion is expected to reach 4 billion by the end of the 21st century. And given the current rate of economic growth, this could represent a positive development for the continent, which could see itself becoming the next powerhouse economy by the 2050s.
7. Clean energy is getting cheaper:
While the price of fossil fuels are going up around the world, forcing companies to turn to dirty means of oil and natural gas extraction, the price of solar energy has been dropping exponentially. In fact, the per capita cost of this renewable source of energy ($ per watt) has dropped from a high of $80 in 1977 to 0.74 this past year. This represents a 108 fold decrease in the space of 36 years.
And while solar currently comprises only a quarter of a percent of the planet’s electricity supply, its total share grew by 86% last year. In addition, wind farms already provide 2% of the world’s electricity, and their capacity is doubling every three years. At this rate of increase, solar, wind and other renewables are likely to completely offset coal, oil and gas in the near future.
Summary:
In short, things are looking up, even if they do have a long way to go. And a lot of what is expected to make the world a better place is likely to happen this year. Who knows which diseases we will find cures for? Who knows what inspirational leaders will come forward? And who knows what new and exciting inventions will be created, ones which offer creative and innovative solutions to our current problems?
Who knows? All I can say is that I am eager to find out!
With supplies of easily accessible fossil fuels diminishing, pushing us towards dirtier sources of oil and natural gas (such as tar sands and frakking), researchers are looking for ways to make renewable energy more efficient and accessible. Towards this end, they are pushing the boundaries of solar cells and wind turbines are capable of, but the constraints of land and weather limit where vast solar or wind farms can be set up.
Luckily, a UK-based company known as New Wave Energy has spent the last few years developing the technology to produce an army of power-generating drone aircraft to overcome these very problems. Basically, each craft is a 20x20m (65ft) flat surface fitted with solar panels and turbines to generate power from the sun and wind, and four small propellers that keep it aloft.
The drones would be capable of flying at altitudes of up to 15,240 meters (50,000 feet), putting them far above the clouds that can obscure the sun. The propellers would allow the craft to track the course of the sun to remain in optimal position for as long as possible. At these altitudes, the wind is also more consistent and powerful, which means smaller turbines can be used in place of the giant towers necessary down near the ground.
In terms of transmitting that power, the key is in the use of microwaves. In essence, power from the drones would be beamed down as a low-energy microwave and collected by antenna arrays on the ground. These antennas can then be used to turn the electromagnetic radiation into usable DC power and then send it to where it is needed.
One of the benefits of this design is that the proposed drone power plants wouldn’t need to land to refuel themselves. Supposedly, they will be able to power themselves entirely with the energy generated on-board, and still produce 50kW of power. This that means several thousand drones would be needed to power a large city of 205,000 homes.
However, these swarms of robotic power plants aren’t just a way to replace the power infrastructure we already have. They could be used to augment our current power supplies as demand increases, removing the need to expand on large, expensive power plants. Also, they bring power to remote areas with poor service, or to restore power in regions affected by natural disasters.
Thus, the cost of building and deploying the drones will determine whether or not that’s feasible. At present, the company plans to raise about $500,000 on Kickstarter to fund the construction of a prototype for testing and marketing. If this campaign does turn out to be successful, the first flying power plant could be aloft within six months.
Combined with other improvements that are making wind and solar power more efficient and affordable, and future prospects for space-based solar power (SBSP) that are being made possible thanks to space startups like Google X, we could be looking at a near-future where solar and wind meet the lion’s share of our energy requirements.
One of the most recurring talking points in the Climate Change debate is the issue of renewable energy. Particularly, those who take issue with proposed changes for dealing with the problem continue to cite how solar, wind and tidal power are not viable replacements at this juncture. While this talking point is a convenient way of dismissing needing reforms, it neglects two self-evident realities.
For one, it ignores the immense amount of progress being made in the fields of renewable energy. Whereas inefficiency and high costs remained as stumbling blocks in previous decades, an exponential drop in costs and a rise in efficiency has made solar increasingly attractive for power companies in recent years. Wind and tidal are in similar situations, with countries like Scotland and the United Arab Emirates leading the way in making them profitable.
Second, it ignores the fact that developed nations continue to stymie growth in renewables by the continued way in which they commit billions to subsidizing oil and coal. According to a new report from the Overseas Development Institute, public subsidies for fossil fuels totaled $523 billion in 2011. That’s six times the level of support for the renewable energy industry, despite those technologies being less mature than oil and coal.
Among richer countries, the top 11 heaviest carbon emitters spent $74 billion in subsidies in 2011, with Russia, the United States, Australia, Germany, and the United Kingdom leading the way. In the U.S., these included a $1 billion fuel tax exemption for farmers, $1 billion for the Strategic Petroleum Reserve, and $500 million for fossil fuel R&D.
In so doing, these governments are:
…shooting themselves in both feet [by subsidizing] the very activities that are pushing the world towards dangerous climate change… [and] creating barriers to investment in low-carbon development.
According to the British think-tank, this works out a spending of $112 per adult in these nations. But of course, the richest nations are not the only offenders, which nations like Pakistan, Egypt, and Indonesia spending more than twice as much on fossil fuel subsidies as on health. The ODI says the poorest 20% of households typically receive just 7% of overall handouts.
But the ODI may be underestimating the true size of the subsidies in the U.S., depending on how you look at it. Earlier this year, the International Monetary Fund calculated subsidies at $502 billion, a figure which includes the true cost of carbon emissions calculated at a price of $25 a ton. By that measure, global subsidies equal $1.9 trillion.
The report also advises that governments should cut handouts to oil and coal as soon as they can and begin looking after the genuinely poor:
Phasing out fossil fuel subsidies would create a win-win scenario. It would eliminate the perverse incentives that drive up carbon emissions, create price signals for investment in a low-carbon transition and reduce pressure on public finances.
A timely and sound recommendation, and one which cuts to the heart of the matter. In order to address the problem of Climate Change, we must not only adopt better methods for meeting our needs, we must acknowledge the truth of the issue. At the same time, we must acknowledge how ending these subsidies, or redistributing them, would alter the current balance of power on the whole issue of energy.
It’s one thing to claim that alternative methods are unviable when the playing field is level, but since it is not, the argument is essentially hypocrisy. By continuing to finance fossil fuels and coal, we are ensuring that clean energy will remain underdeveloped as an alternative, and hence undermining any chance it has at becoming a true alternative.
So the next time someone tells you that solar or other means of renewable energy are at least 50 years away, or that gas and coal are the only economical means of meeting our energy needs, be sure to ask them why we need to spend half a trillion dollars on them annually.
Every year, IT giant Google holds an online competition open to students aged 13-18 from around the globe to come up with new and challenging scientific ideas. And this year, one the winners just happens to hail from my hometown of Victoria, British Columbia. Her name is Ann Makosinki, a 15 year old high school student who invented a way to power a flashlight using only the warmth of your hand.
She claimed a trophy made of Lego for the 15-16 age category at an awards gala that was held on Monday, Sept. 23rd. Her prizes were a $25,000 scholarship and a “once-in-a-lifetime experience” from either CERN (the European Organization for Nuclear Research), LEGO or Google. Quite the impressive accomplishment for a 11th grader, but then again, Makosinki has been a scientist at heart ever since she was a little kid.
For starters, when other children were playing with toy cars and dolls, she busied herself with transistors and microcircuits. What’s more, by Grade 6, she began submitting projects to science fairs and began showing an interest in alternative energy. Still, Makosinki was surprised to be getting an award, given her competition. As she said:
I’m in shock, I’m in shock. It’s actually kind of embarrassing because I didn’t even change [before the awards ceremony]. I didn’t even comb my hair or anything. I must have looked like an absolute mess on stage because I didn’t expect to go up at all.
As for the invention itself, it is easy to see why she won. Basically, it is an LED flashlight that relies on the thermoelectric effect to generate electricity when held. This is done through a series of devices that are known as Peltier tiles, which produce electricity when heated on one side and cooled on the other. The tiles are fixed to the outside of the flashlight while the tube itself is hollow.
When held one side of the Peltier tiles are heated by the warmth of the person’s hand, air flowing through the hollow tube helps keep the other side cool. This combination of body heat and air cooling allows enough power to be generated to maintain a steady beam of light for 20 minutes. And all without the need for batteries and the resulting ewaste when they go dead.
Makosinki came up with the idea while researching different forms of alternative energy a few years ago. Already, she had experimented with Peltier tiles for her Grade 7 science fair project. While researching her project, she thought of them again as a way to potentially capture the thermal energy produced by the human body. After doing some calculations, she found that the amount of energy produced by a person’s hand was theoretically sufficient to power an LED light.
However, putting it into practice proved somewhat more difficult. After buying some Peltier tiles on eBay, she tested them and found that while they generated more than enough power, the voltage produced was only a fraction of what she needed. She rectified this problem after doing some further research, where she discovered that the addition of transformers could be used to boost the voltage.
She spent months doing research on the internet, experimenting with different circuits and even building her own transformers, which still didn’t provide enough voltage. In the end, she came across an article on the web about energy harvesting that suggested an affordable circuit that would provide the voltage she needed when used with a recommended transformer. Finally, the circuit worked.
Makosinski admitted there were points in the experiment when she thought it would never work. But as she said:
You just kind of have to keep going. This took quite awhile ’cause I had to do it during the school year as well and I had homework, plays, whatever that I was also doing.
After making it to the Google Science Fair, she and her colleagues spent the day presenting at Google’s headquarters in Mountain View, California. Here, the 15 judges – which included scientists from a variety of fields, science journalists, an astronaut, and a former Google Science Fair winner – witnessed their creations and tried to determine which held the most promise.
The other winners included Viney Kumar, an Australia student who captured the 13-14 age category for an Android app that warns drivers of an approaching emergency vehicle more than a minute in advance, in order to help clear a path for it. And then there was Elif Bilgin of Turkey, a 16-year old who took home the Scientific American Science in Action Prize and the Voter’s Choice Award for inventing a way to make plastic from banana peels.
The Grand Prize for the 17-18 age category went to Eric Chen, a 17 year old student from San Diego who is researching a new kind of anti-flu medicine using a combination of computer modelling and biological studies. He received the top prize of a $50,000 scholarship and a 10-day trip to the Galapagos Islands.
Alas, Makosinki felt the best part of the competition was getting to meet the other finalists in person at last.
It’s just so inspiring to see other people who are kind of like me and kind of want to make a difference in the community not just by talking about it but by actually doing stuff.
What’s next for the young inventor? Personally, I hope Makosinki and her fellow prize winners will be forming their own research group and looking for new and exciting ways to come up with renewable energy, recycling, vaccinations, and electronics. What do you think Makonsinky, Kumar, Bilgin, Chen? That’s what Andraka and his fellow finalists did after winning ISEF 2012, and they seem to be doing pretty good. So… hintedy, hint hint!
And be sure to enjoy this video of Ann Makosinki showing off her invention, courtesy of Technexo:
With every passing year, solar power is getting cheaper and more efficient. And with every development that brings costs down and increases electrical yields, the day that it comes to replace fossil fuels and coal as the primary means of meeting our power needs gets that much closer. And with this latest development, this changeover may be coming sooner than expected.
It comes from North Carolina State University where researchers have developed a new system for strengthening the connections between stacked solar cells which could allow cells to operate at concentrations of up to 70,000 suns while minimizing wasted energy. This is especially good news seeing as how stacked cells are already an improvement over conventional solar cells.Stacked solar cells are made up of several cells that are placed one on top of the other, an arrangement that allows up to 45 percent of the absorbed solar energy to be converted into electricity. This is a significant improvement over single-junction solar cells which have a theoretical maximum conversion rate of 33.7 percent, and is made possible by the fact a stack formation prevents heat from being lost between panels.
The team at NCSU discovered that by inserting a very thin film layer of gallium arsenide into the connecting junction of stacked cells, they can eliminate energy loss ever further. The idea was inspired by the fact that cells typically start to break down at the connection junctions once they reach concentrations of 700 suns. With the addition of gallium arsenide in these spots, the connections become stronger, and all without sacrificing absorption.
Dr. Salah Bedair, a professor of electrical engineering at NCSU and senior author of the paper on this research:
Now we have created a connecting junction that loses almost no voltage, even when the stacked solar cell is exposed to 70,000 suns of solar energy. And that is more than sufficient for practical purposes, since concentrating lenses are unlikely to create more than 4,000 or 5,000 suns worth of energy.
At the moment, this technology is geared towards large scale solar power operations. Stacked cells are usually used in conjunction with optical concentration devices, such as Fresnel lenses, and mounted on a dual-axis solar trackers that keep the cell facing the Sun’s rays during daylight. So basically, we’re not likely to be seeing this technology available for local use. But it would be surprising if domestic consumers weren’t likely to benefit from it all the same.
As Dr. Bedair explained, the adoption of the technology will mean lower costs for the energy industry, and smaller arrays which will mean less land that needs to be set aside for use:
This [system] should reduce overall costs for the energy industry because, rather than creating large, expensive solar cells, you can use much smaller cells that produce just as much electricity by absorbing intensified solar energy from concentrating lenses. And concentrating lenses are relatively inexpensive.
What’s more, gallium arsenide is not exactly cheap to produce at the time. However, with constant refinements being made in industrial production processes, we can expect the cost of these to come down as well. As with everything else with solar power and renewable energy, its only a matter of time…
All over the world, the goal of bringing development to impoverished communities and nations – but in ways that won’t cause additional harm to the natural environment – remains problematic. As the cases of China and India demonstrate, the world’s fastest growing economies in the 21st century, rapid industrialization may bring economic development, but it comes with a slew of consequences.
These include urban sprawl, more emissions from cars and public transit, and the poisoning of waterways through toxic runoff, chemicals and fertilizers. With seven billion people living in the world today, the majority of which live in major cities and are dependent on fossil fuels, it is important to find ways to encourage growth that won’t make a bad situation worse.
But to paraphrase an old saying, crisis is the mother of creative solutions. And amongst forward-looking economist and developers, a possible solution is take the latest advancements in solar, wind, tidal power and biofuels, and tailor them to meet the needs of local communities. In so doing, it is hoped that the developing world could skip over the industrial phase, reaping the benefits of modernization without all the dirty, unhealthy consequences.
Two such men are Juan Rodriguez – a young man who was studying for his business administration at the Universidad Francisco Marroquin in and cut his teeth working for major multinationals like Pampers, Pepto Bismol and Pantene – and his childhood friend Manuel Aguilar, a Harvard graduate with a degree in astrophysics who had gone on to manage a global hedge fund.
Three years ago, the two agreed that they were looking for something else and began investigating renewable energy. The result was Quetsol, a company that uses solar energy to improve the quality of life of poor communities living off the electrical grid. In Rodriguez’s and Aguilar’s native Guatemala, such poverty is widespread, with close to 20% of the population living without electricity and relying primarily on candles for light.
This picture of poverty is not exactly news. But after spending a year visiting close to 100 such communities, Rodriguez and Aguilar began to get a clear picture of why solar hadn’t yet succeeded. As Rodriguez put it:
Going to a community and talking about solar power isn’t like going into a community and talking about space travel. It is something that people have already seen, because NGOs have donated solar systems to these communities for decades. In many cases, the systems worked perfectly, but eventually the batteries died, and nobody was there to service them.
There solution was to start from the bottom up, using the free-market principle of adapting their approach to meet local needs. This would involve identifying communities before visiting them, taking into account how many people were living without electricity, and what the housing situation was like. When they then visited these communities, they sought out community leaders and held public meetings to learn about them and present their ideas.
Buildings relationships with local communities was a challenge, but so was creating a product for a market whose needs ranged from basic lighting and cell phone charging to powering a refrigerator all day. What they found was that unelectrified communities were relying on terribly inefficient means, ranging from diesel generators to walking to the nearest electrified community to plug in a phone.
What was resulted was a Solar Kit, consisting of a 10W Solar Panel, a control box with 7 Amp Battery, 2 LED Bulbs (and a third optional bulb), and a universal cell phone charger. This kit has the ability to provide five hours of electricity to a house made up of two rooms that measure roughly 25 square meters (225 square feet) each. This is the typical design of homes in rural Guatemala, with one room serving as the bedroom and the other as the kitchen.
With that done, they began working on their sales strategy. Initially, this consisted of working with microfinance credit institutions to help families and communities purchase their solar kits. But after watching too many credit applications get rejected, they took a page from the telecom companies that have made cell phones ubiquitous in Guatemala, Basically, they switched to a pay-as-you-go plan.
Today, Quetsol employs a staff of 20 people and boasts board members like Google’s Tom Chi. There product line has also expanded, with the Q1 Solar Kit being supplemented by the Q3, a heavier model that boasts a 75W solar panel, an 85 Amp Battery, and five LED bulbs. The Q2 Kit – a middle of the road model with a 30W panel, 34 amp battery and 3 bulbs – is soon to be released.
But most importantly of all, they have electrified more than 3,500 homes in Guatemala thus far. But that is just a drop in the bucket compared to their long-term goal. Basically, the organization is viewing Guatemala as a stepping stone to all of Latin America as well as Africa by 2015. By 2016, they’d like to tackle the nearly 700 million off-the-grid homes in Asia.
Might sound ambitious, but Rodriguez and Marroquin feel they have the business acumen and social entrepreneurial savvy to pull it off. And given their background and business model, I’d say they are about right. Combined with other technologies that merge local needs with clean, efficient, and renewable means, development in the developing world might actually be an eco-friendly possibility.
Wind turbines are one of the fastest growing industries thanks to their ability to provide clean, renewable energy. And while most designs are trending towards larger and larger sizes and power yields, some are looking in the opposite direction. By equipping everyday objects with tiny windmills, we just might find our way towards a future where batteries are unnecessary.
These micro-windmills – called horizontal axis wind turbines – have a three-bladed rotor that is 1.8 mm in diameter, 100 microns thick, and are mounted on a tower about 2 mm tall mount. Despite their tiny size, the micro-windmills can endure strong winds, owing to being constructed of a tough nickel alloy rather than silicon, which is typical of most microelectromechanical systems (MEMS), and a smart aerodynamic design.
The windmills were crafted using origami techniques that allow two-dimensional shapes to be electroplated on a flat plane, then self-assembled into 3D moving mechanical structures. Rao and Chiao created the windmill for a Taiwanese superconductor company called WinMEMS, which developed the fabrication technique. And as Rao stats, they were interested in her work in micro-robotics:
Stories by Williams 