The House that One Man Can Lift. Sanctuary Magazine Showcases This and More.

Tuesday, October 5, 2010

The House that One Man Can Lift. Sanctuary Magazine Showcases This and More.

by Warren McLaren
Magnetic Island house exterior photo
Magnetic Island house exterior Photo: Robin Gauld for Sanctuary magazine issue 12
When it came time for our architecture writer, Lloyd, to select the Best Shelter Magazine for TreeHugger's 2010 Best of Green Awards in Design and Architecture he quickly made his choice: Sanctuary Magazine, from Australia's Alternative Technology Association (ATA). Indeed he gushed, "so much beautiful stuff -- stunningly photographed and presented I just want to pack up and move to Australia. [...] The magazine's website is full of excerpts and info, but the magazine is a joy to hold."
And it is no accident that Lloyd is so enamoured. For TreeHugger was conceived as a vehicle to make green design and sustainable lifestyles attractive to a mainstream audience. Sanctuary magazine does that so effectively for eco-architecture. It's twelveth issue recently hit the news stands, continuing the thread of lush photography and green residential design. We look at some of the highlights below.
Sanctuary magazine covers image
Images: Sanctuary magazine
Six houses are profiled, with sumptuous imagery, informative descriptions and backed up with a simple list of their 'sustainable features' such as the material used, the type of glazing, rainwater harvesting systems, lighting, landscaping, etc.
But probably the nub of info that most intrigues me is that the respective home owners have, in most cases, been trusting enough to provide Sanctuary magazine with project costings. I think this is an important consideration, for it is very easy to throw a barrowload of money at a home, and say "there, look it's 'green.'" It's another matter entirely to achieve sound environmental results on a tight budget. Thus Sanctuary's published costings keep the eye candy honest.
Brisbane house interior photo
Photo: Christopher Federick Jones for Sanctuary magazine issue 11
Similarly, new houses tend to get the lion's share of attention when it comes for green housing media coverage. But Sanctuary consistently has a collection of renovations to show what clever eco thinking can impart to existing dwellings.
And the most recent issues of the magazine have also stepped outside of the pure green house reviews and covered related information. In the current edition you can get up to speed on energy ratings, reupholstering furniture, thermal window blinds, ceiling fans and landscaping. In the previous issue, the focus was on how to make a cool pantry that would give a fridge a run for its money, along with discussions of greener concrete, lawns, how to buy recycled kitchens and understanding housing ventilation.
But all this wonderful information is really just the backdrop to the reviewed houses.
Issue 12 showcases half a dozen homes, but the one that most captured my imagination was a Magnetic Island residence, with corrugated iron cladding, a material so ubiquitous in early Australian buildings. Here it is used in a tropic dwelling that has won a bunch of awards, including from the Australian Institute of Architects. In fact, the team behind its design, Troppo Architects, were this year, the first Australian firm to win the Global Award for Sustainable Architecture.
Magnetic Island house interior photo
Magnetic Island house interior Photo: Robin Gauld for Sanctuary magazine issue 12
Although sited in the humid tropics, the house avoids need of any air conditioning, through the judicious placement of three separate buildings connected by passive venting outdoor breezeways and backed up with insect screened adjustable louvre windows, and ceiling fans. Large eaves help keep direct sun at bay, while a lap pool also adds a cooling feature.
There is almost as much outside deck area as there is enclosed house, allowing the dwelling to appear larger than its 107 square metres (1,151 sq ft) suggest.
This three bedroom, two bathroom house was constructed by one man. All the materials are therefore relatively lightweight and easily transportable and managed. The exposed steel frame was bolted together rather than welded, so it can all be disassembled at the end of a useful life. The house itself is raised off the ground to minimise site disturbance (although we're not sure how this design feature applies to the lap pool). The builder used leftover construction materials to create furniture for the house.
The lighting is LED and this is powered via a grid connected 3kW Kyocera polycrystalline photovoltaic solar array. (See more pix on the Troppo Architect's website.)
The other homes highlighted in the twelveth issue of Sanctuary magazine each have their own unique green design features. Like sliding walls that convert otherwise private rooms into expansive open space. An idea similarly explored by another house whose entire eastern wall swings open like a massive door to turn a room into an open air pavilion. Or the house whose internal thermal mass uses rammed earth construction, with the twist of employing recycled concrete aggregate.
Sanctuary magazine is a print magazine, not available online, although excerpts of articles from back issues do appear on the magazine's website.

Stanford Unveils Solar Cells Thinner Than Light Wavelengths


Stanford Unveils Solar Cells Thinner Than Light Wavelengths

ultra thin solar cells, stanford university solar cells, solar 
cells wavelength, stanford solar cell, Shanhui Fan solar cell, Shanhui 
Fan wavelength cell
One problem with solar cells is that the thicker and more powerful they are, the more expensive they are to make. However engineers at Stanford recently announced that they have developed a new type of solar cell thinner than the wavelengths of light that could absorb 10 times the amount of sunlight that current cells do. The engineers believe that by configuring the thicknesses of several thin layers of films, an organic polymer cell could transform the solar energy industry.
“The longer a photon of light is in the solar cell, the better chance the photon can get absorbed,” Fan added, who is also senior author of the paper describing the work called . “We all used to think of light as going in a straight line,” Fan said. “For example, a ray of light hits a mirror, it bounces and you see another light ray. That is the typical way we think about light in the macroscopic world. But if you go down to the nanoscales that we are interested in, hundreds of millionths of a millimeter in scale, it turns out the wave characteristic really becomes important.”
With that in mind, if a solar cell can be made that is around 400 to 700 nanometers thin (billionths of a meter), it can produce a remarkable amount of energy. The potential for this technology is enormous — not only would nano-thin solar cells save money in materials, but by using organic polymers over silicon they make the cells cheaper to buy and easier to install due to their thickness.

Wave Power Lights Up U.S. Electrical Grid For First Time


Wave Power Lights Up U.S. Electrical Grid For First Time

sustainable design, renewable energy, opt, wave power, wave 
energy, powerbuoy, oaho, marine corps, hawaii
We write a lot about wave power here at Inhabitat, but functional wave farms are few and far between. Now Ocean Power Technologies has hooked up its PB40 PowerBuoy to the grid at the Marine Corps Base in Hawaii, marking the first time waves have provided energy to the U.S. electrical grid.
sustainable design, renewable energy, opt, wave power, wave 
energy, powerbuoy, oaho, marine corps, hawaii
Unlike many tidal power devices, the PowerBuoy generates energy from the rising and falling of the waves. A 10 MW PowerBuoy station occupies 12.5 hectares of ocean.
The Hawaii-based PowerBuoy was first deployed three-quarters of a mile off the Oahu coast in December 2009. With the new Marine Corps hookup, OPT hopes to prove that the PowerBuoy can produce utility-grade renewable energy. If all goes well with the Marine Corps station, we can expect more wave power to hit the U.S. soon — OPT already signed a stakeholder agreement for a utility-scale wave energy project in Oregon.

Magnetic Energy Device Could Mean 40% Power Savings


Magnetic Energy Device Could Mean 40% Power Savings

smart grid, components of a smart grid, smart meters, buy smart 
meters, new power grid, where to buy smart meters, how smart meters 
work, magnetic energy, Magnetic Energy Recovery Switch
The US Navy is on their way to having 40% of their power come from renewable sources by 2020 and a big part of that move is helping their buildings save energy. They’ve got their researchers hard at work devising new technology and one solution that recently emerged from the U.S. Office of Naval Research Global has us marveling at its ingenuity. It is a magnetic energy regulation device that controls the flow of energy to lighting sources. The device also captures residual magnetic energy given off by energy transmitters which it redirects back into the lighting — total savings can be up to 40% at peak times.
The device not only conserves electricity, but produces far less heat and produces less electromagnetic interference than conventional technologies” said Dr. Chandra Curtis, program officer in ONR Global’s Tokyo office. She noted that she was excited about this device providing savings across the power grid. In practice in barracks at a Navy base in Tokyo, Japan the device proved to work wonderfully in all intended aspects and significantly reduced power consumption over time.
Curtis and her team are working on a proposal for a larger test installation at the same barracks in Tokyo that would include a break room, printing press room, laundry room, gymnasium and several offices. The device was originally tested in an area that required 24 hour lighting, but using it in these varied spaces would show its efficacy in different situations. The tests should run into 2011 if approved.

Canada Becomes First Country to Ban Toxic BPA

Canada Becomes First Country to Ban Toxic BPA

bpa, bisphenol a, canada, environment canada, epa, green designPhoto by Steven Depolo
As avid Inhabitat readers knowBPA is a nasty substance. The organic compound, found in everything from reusable water bottles to soup cans, is thought to cause both hormonal and neurological issues. But the anti-BPA movement is growing strong — so strong, in fact, that Canada just moved to ban the substance altogether.
bpa, bisphenol a, canada, environment canada, epa, green design
Canada banned BPA-containing plastic baby bottles in 2008, but the new move will see BPA removed from all products on store shelves. As a result, Canada will become the first country in the world to declare BPA as a toxic substance. There’s no word on when the ban will take effect, but the North American chemical industry is reportedly angry with Environment Canada’s decision to abolish the stuff.
Even though the U.S. hasn’t made any moves to ban BPA outright, the Canadian ban could reverberate across the border — and that’s a good thing for anyone concerned about their health.
 

Liquid Energy: New Microbe Tech Turns Sun and CO2 Into Fuel


Liquid Energy: New Microbe Tech Turns Sun and CO2 Into Fuel

Joule Biotechnologies, microbes renewable energy fuel, bacteria 
renewable energy fuel, bacteria CO2 sunlight fuel, microbes bacteria CO2
 sunlight fuel, cyanobacteria
Biofuel startup Joule Unlimited has announced that it has engineered microbes that require only sunlight and CO2 to produce ethanol, diesel, or other hydrocarbons. The company formally announced that it has obtained a patent for a genetically modified version of cyanobacteria that converts carbon dioxide, dirty water and sunlight into a liquid hydrocarbon that is functionally equivalent to regular diesel.

According to the patent, the engineered cyanobacteria contains “a recombinant acyl ACP reductase (AAR) enzyme and a recombinant alkanal decarboxylative monooxygenase (ADM) enzyme.”   What this concoction of cyanobacteria and enzymes does is allow for hydrocarbon production in a single step, converting captured sunlight into ‘liquid energy’, that can be either ethanol or diesel.
Joule Biotechnologies, microbes renewable energy fuel, bacteria 
renewable energy fuel, bacteria CO2 sunlight fuel, microbes bacteria CO2
 sunlight fuel, cyanobacteria
“This patent award represents a critical milestone for our IP strategy and validates the truly revolutionary nature of our process, which has the potential to yield infrastructure-compatible replacements for fossil fuels at meaningful scale and highly-competitive costs, even before subsidies,” said Bill Sims, President and CEO, Joule. “Our vision since inception has been to overcome the limitations of biomass-based technologies, from feedstock costs and logistics to inefficient, energy-intensive processing. The result is the world’s first platform for converting sunlight and waste CO2 directly into diesel, requiring no costly intermediates, no use of agricultural land or fresh water, and no downstream processing.”
Formerly known as Joule Biotechnologies, the company, which is based in Cambridge, Massachusetts, announced late last year that it had developed technology which could produce the equivalent of 25,000 gallons of ethanol per acre per year and 15,000 gallons of diesel per acre per year of drop-in hydrocarbon fuels, using only sunlight, CO2 and  water as inputs. The Solar Converter along with the new bacteria and a technology known as helioculture is the basis of this claim. Pilot production on diesel begins later this year.
While the project is still in its pilot testing phase, it’s already producing 10,000 gallons of ethanol a year, or 40 percent of its goal, on its pilot lines in Leander, Texas. It is expected that production will begin by the end of the year with commercial production commencing in 2012.  If it is successful, not only could it mean cheap biofuel (selling at $30 a barrel, compared to $70 for oil), but it could mean a fully sustainable form of fuel that doesn’t need food crops to create it. Fuel could literally be created out of thin air!

House-in-a-Can Recycles Grain Silos Into Housing

House-in-a-Can Recycles Grain Silos Into Housing

by Lloyd Alter
house in a can architecture recycled photo
All images via Austin-Mergold
Grain silos, made from corrugated and galvanized steel, are among the cheapest and most efficient enclosures one can buy; that's why Bucky Fuller played with them during World War II, with his Dymaxion Deployment Units.
Updating the idea, Geoff Manaugh of BLDGBLOG brings us Austin + Mergold's House-In-A-Can, recycling these grain silos into housing, from single family to condo.
house in a can architecture recycled photo silos
The architects describe them with some marketing flair:
36-foot in diameter American grain dryer with 2000 SF single family starter home inside. Instantly assembled off-the-shelf 14 GA galvanized corrugated steel exterior a 2000 SF developer house inside. Optional greenhouse. Buy 5 get one free!!!
house in a can architecture recycled photo plans
They can be arranged in a number of configurations.
house in a can architecture recycled photo model
Manaugh calls the models "delightfully absurd and inspiring" and suggests further iterations:
A thesis presentation performed as a series of metal cans extruded outward into models of inhabitable architecture... Cinema-In-A-Can. Library-In-A-Can. Gym-In-A-Can. Dome-In-A-Can Republic.
More at House-in-a-can via BLDGBLOG

6 Inspiring Examples of Groundbreaking Green Technology


6 Inspiring Examples of Groundbreaking Green Technology

Green technology isn’t just about wind turbinessolar panels and alternative fuel anymore. A few inspiring individuals out there are breaking new ground with innovative ideas that no one’s ever explored before. From a printer that can spit out whole buildings made of stone to an entire city that flips the discomfort of the summer heat into an energy-saving advantage for the wintertime to a company that decided solar panels don’t have to be ugly, heavy or even rectangular. Read on to check out some of our favorite examples of emerging technology in the field of green!
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ivy, spray on solar cells, inspiring technology, out of the box 
technology, groundbreaking technology, new technology, sustainable 
technology, eco technology, powerleap, 3d printer, building printer, 
piezoelectric, shoe generator

3-D Printer Creates Entire Buildings From Solid Rock

3D printers are nothing new – but how about a printer that can whip up entire life-size stone buildings?! That’s exactly what designer Enrico Dini’s prototype D-Shape printer does. Instead of ink, the device uses layers of sand, and Dini reports that the process is four times faster than conventional building, costs about one-third to one-half the price of Portland cement, and creates much less waste.
science city, honggerberg campus, green technology, smit, solar 
ivy, spray on solar cells, inspiring technology, out of the box 
technology, groundbreaking technology, new technology, sustainable 
technology, eco technology, powerleap, 3d printer, building printer, 
piezoelectric, shoe generator

Transparent Solar Spray Transforms Windows Into Watts

Photovoltaic panels transform the sun’s rays into energy we can use, but they’re bulky and not the most attractive in terms of design. Well one Norwegian company called EnSol AS has cast aside the notion that PVs need to take up extra space — or even be in a solid state. They’ve developed a remarkable new spray-on solar film consisting of metal nanoparticles embedded in a transparent composite matrix that allows you to turn ordinary windows into solar panels. The best part? The spray is clear so you can still see right through your windows!
science city, honggerberg campus, green technology, smit, solar 
ivy, spray on solar cells, inspiring technology, out of the box 
technology, groundbreaking technology, new technology, sustainable 
technology, eco technology, powerleap, 3d printer, building printer, 
piezoelectric, shoe generator

POWERleap Harnesses Energy From Foot Steps!

While other green tech companies look to outside sources like the sun and wind when they think about alternative power, POWERleap decided to completely flip the script by tapping the energy inside – of ourselves! Their piezoelectric floor tiling system that converts the energy from human foot traffic into electricity could be applied to train stations, sidewalks or even inside homes to harness the wasted energy from our footsteps into power for the grid.
science city, honggerberg campus, green technology, smit, solar 
ivy, spray on solar cells, inspiring technology, out of the box 
technology, groundbreaking technology, new technology, sustainable 
technology, eco technology, powerleap, 3d printer, building printer, 
piezoelectric, shoe generator

‘Solar Ivy’ Photovoltaic Leaves Climb to New Heights

Who says photovoltaic panels have to be an eyesore? After all, if they could somehow be integrated as a decorative element on homes and buildings, more people might be willing to install them on more surface area. Well, that’s exactly the approach that Brooklyn-based SMIT (Sustainably Minded Interactive Technology) took with their “Solar Ivy”, a system of paper-thin, leaf-shaped solar panels that generate energy by sparkling in the sunlight. These pretty PVs consist of layers of thin-film material on top of polyethylene with a piezoelectric generator attached to each one, and are definitely miles away from the big, boxy panels we’re used to seeing.
science city, honggerberg campus, green technology, smit, solar 
ivy, spray on solar cells, inspiring technology, out of the box 
technology, groundbreaking technology, new technology, sustainable 
technology, eco technology, powerleap, 3d printer, building printer, 
piezoelectric, shoe generator

Shoe Generator Harvests Power from Walking

Walking is already one of the greenest forms of transportation but one researcher at Louisiana Tech University thought it could be made even more eco-friendly — so he designed a shoe that converts the wearer’s footsteps into electricity. The piezo power shoe contains a small generator in its sole that can charge batteries or power small electronics. Bet your Nikes can’t do that.
science city, honggerberg campus, green technology, smit, solar 
ivy, spray on solar cells, inspiring technology, out of the box 
technology, groundbreaking technology, new technology, sustainable 
technology, eco technology, powerleap, 3d printer, building printer, 
piezoelectric, shoe generator

Science City Stores Warm Air from Summer to Heat Buildings in Winter

Isn’t it sad that in many parts of the world people use a ton of energy cooling buildings in the summer and then use almost as much power heating up the same spaces just a few months later? It may sound crazy but what if there was a way to save the summer’s hot air and use it to warm buildings throughout the winter? Well some smart thinkers at Honggerberg Campus in Switzerland are doing just that. Their campus, called Science City is installing systems that will allow it to harness natural heat during the warmer months, pump it underground and store it until the winter when it be pushed back up into buildings and act as a heating system. The system is the first of its kind.

World’s Largest Wave Energy Site Now Installed in UK

World’s Largest Wave Energy Site Now Installed in UK

wave hub, wave hub wave energy, wave hub RDA, wave hub cornwall, 
wave hub installation, wave hub global wave energy
The Wave Hub, a groundbreaking renewable energy project that is set to become the UK’s first offshore facility dedicated to wave energy, has been installed off the North Coast of Cornwall. Four wave energy generation devices will connect their arrays into the Hub, allowing developers to transmit and then sell their renewable energy to the UK’s electricity distribution grid. The total capacity of the hub will be 20 MWe (megawatt electrical).
The project that has cost £42 million ($64 million) will essentially be a ’socket’ sitting on the seabed for wave energy converters to be plugged into. It is hoped Wave Hub’s construction will make the South West of England a leading player in the global marine energy industry. Wave Hub will also see the construction 0f a sub-station built at Hayle 10 miles away.  It will be situated adjacent to a connection point on the distribution network. From there, a cable will be taken through a 200m duct beneath the sand dunes and then across the sea bed to an eight square kilometre area within which the devices will be moored.
wave hub, wave hub wave energy, wave hub RDA, wave hub cornwall, 
wave hub installation, wave hub global wave energy
The South West Regional Development Agency (RDA) has put £12.5 million into the project with £20 million coming from the European Regional Development Fund (ERDF) Convergence Programme. Another £9.5 million will come from the UK government. The scheme is expected to be operational next year and has already signed up its first wave device developer – Ocean Power Technologies Limited. Fred Olsen Limited, WestWave and Oceanlinx are said to be the other three companies.
Stephen Peacock, executive director of Enterprise and Innovation at the South West Regional Development Agency (RDA), said, “This milestone is the culmination of more than six years’ work by the RDA and its partners and will catapult south-west England and the UK to the forefront of wave energy development. Our aim is to create an entirely new low-carbon industry in the south west and hundreds of quality jobs.”
Energy and climate change minister, Lord Hunt, welcomed news of the construction and said that it demonstrated huge scope for wave and tidal energy around the UK’s shores. ”The south west is the UK’s first low-carbon economic area, building on its regional business opportunities and skills,” he said. “The combination of its wealth of natural marine resource and its high level of expertise in marine technology makes it an ideal location for the Wave Hub.”
However while Wave Hub may be a source of national pride as well as renewable power, no-one is more proud than the RDA’s Wave Hub General Manager Guy Lavender who said, “Seeing Wave Hub lowered into the water was the culmination of more than seven years’ hard work by hundreds of people and the fact that it was designed and built in this country is testimony to the skills and experience that the UK already has in the fledgling marine renewables industry.”

Bürstner Trailer Has Lessons For Living In Smaller Spaces

Bürstner Trailer Has Lessons For Living In Smaller Spaces

by Lloyd Alter
averso trailer caravan living with less small spaces photo interior
 bed up
Those designing for small spaces can learn a lot from boats and travel trailers, particularly from European designs. Caravanning is a high-end luxury activity in Europe and some of the models put luxury yachts to shame. This Bürstner Averso Plus is pretty luxe, and has is advertised as the first ever with a drop-down bed. The image above is set up for dining, with the bed pulled up to the ceiling and the "chic starry sky" of LEDs visible.
averso trailer caravan living with less small spaces photo 
bed down
Here is is dropped down over the table, which is also on a telescoping base.
averso trailer caravan living with less small spaces photo 
section
A lot of boats and travel trailers have drop-down tables where the cushions from the back of the seating are put on the table, becoming a bed, but this looks a lot more comfortable and faster, too.
averso trailer caravan living with less small spaces photo 
kitchen
it is all rather nicely fitted out with lots of storage;
averso trailer caravan living with less small spaces photo 
batrhoom
There are lessons in the bathroom as well, where the entire room becomes the shower stall, saving a lot of space. No idea what the thing costs, but it's on Born Rich, so it is probably expensive. More at Bürstner

Inspiring Green Technology That Has the Power to Heal


Inspiring Green Technology That Has the Power to Heal

One can’t deny the ever-increasing role that technology plays in our lives. While some people are averse to the spread of technology, many of us recognize the positive impact that it can have on our future and the quality of our lives. In the field of medicine, there are many scientists, doctors, engineers, and designers that are constantly pushing the bounds of what’s possible in terms of human health — and the results are inspiring. Read on for some of our favorite examples of awe-inspiring and green medical revelations!

Photovoltaic Device Gives Sight to the Blind

There is no better example of how we can use technology to create a brighter future than using photovoltaics to help the blind see. Researchers at Stanford University recently developed a new artificial retina implant that actually uses the power of the sun to help give sight to the blind. Previous implants were problematic because of the challenges associated with providing enough electricity to the chip. Fortunately, with the development of miniature photovoltaic cells, these new implants now have the power to get the job done.
technology, photovoltaics, Solar-powered Chip, medical, design for
 health, e-waste, artifical retina implant, solar power, e-waste 
recycling

LCD Televisions Transformed into Infection Fighting Medicine

One downfall to adopting new technology is the issue of “disposing” or “not disposing” of the old stuff — e-waste has become a real problem that needs a real solution. Scientists at the University of York have gone above and beyond finding a way to properly dispose of this waste — they’ve discovered how to recycle discarded LCD televisions into an amazing infection-fighting substance. York’s Department of Chemistry and its team of researchers successfully transformed the key element of LCD television sets – polyvinyl-alcohol (PVA) – into an anti-microbial material that can fight infections – now that’s what e-waste recycling should be.
technology, photovoltaics, Solar-powered Chip, medical, design for 
health, e-waste, artifical retina implant, solar power, e-waste 
recycling

Implantable Solar-powered Chip Monitors Blood Sugar Levels

Most diabetics have forever had to deal with the uncomfortable, but unavoidable need to monitor their own glucose levels by drawing blood. Lucky for them, the Glucowizzard may have eliminated much of the discomfort associated with the finger pricking ritual. This solar-powered device is a rice-sized implantable glucose sensor that is inserted under the patient’s skin. The device continuously monitors glucose levels and only needs to be replaced once each year.
technology, photovoltaics, Solar-powered Chip, medical, design for
 health, e-waste, artifical retina implant, solar power, e-waste 
recycling

Medical Dressing Uses Nanotechnology to Treat Infection

Researchers at the University of Bath and the Southwest UK Paediatric Burns Center have redefined the future of wound dressing. Their amazing dressing not only stops you from bleeding…. it can also detect disease-causing pathogens. As soon as these pathogens are detected, nano-capsules in the dressing release antibiotics and change color to indicate that the medicine has been released
technology, photovoltaics, Solar-powered Chip, medical, design for
 health, e-waste, artifical retina implant, solar power, e-waste 
recycling

Living, Breathing “Lung Chip” Provides Alternative to Animal Testing

Testing chemicals to determine how safe or unsafe they are for the human body is an important part of ensuring our health. Unfortunately, there is no easy way to go about this, and animal testing is a horrific endeavor altogether. Seeking to provide a solution to this quandary, researchers at Harvard’s Wyss Institute have developed a synthetic human lung-on-a-chip. Their transparent bite-sized device cleverly mimics how a real lung breathes, and how it allows pathogens into the blood stream. With access to inspiring gadgets like this one, the ethically dubious practice of animal testing could soon be history.

America’s First Zero Energy School to Open


America’s First Zero Energy School to Open

by Andrew Michler
Sherman Carter Barnhart Architects , zero energy school, zero 
energy building, first zero energy, green building, daylighting, 
geothermal heating cooling architecture, ground source heat pump, 
Kentucky green school,
Richardsville Elementary, a new LEED Platinum School in Kentucky, is getting extra credit by being the first zero energy school in the nation! Opening this month to much anticipation, the facility is a cornucopia of green building strategies and efficient technologies. The bread and butter of the school’s success are tremendous efficiency gains coupled with a 300 kW thin-film solar arraySherman Carter Barnhart Architects have done and astonishing job of reducing the building’s energy consumption to one fourth of a typical school without breaking the bank.
The 72,000 square-foot school uses insulating concrete forms (ICF) with a highly insulated roof to reduce reliance upon heating and cooling equipment. The windows are shaded by light shelves that reflect sun into the celestry windows, providing ample daylighting. Nanogel translucent panels line the celestry window in the main hall. Their ability to provide lots of glare free daylight is paired with super-insulated performance. A ground-source heat-pump helps provide for the building’s heating and cooling needs, and exposed pipes, meters and a floor motif teach the students about the system. In fact, each hallway showcases an environmental theme or technology — solar panels, heat pumps, recycling, and water conservation.
Sherman Carter Barnhart Architects , zero energy school, zero 
energy building, first zero energy, green building, daylighting, 
geothermal heating cooling architecture, ground source heat pump, 
Kentucky green school,
The energy production comes from a huge thin film solar array that is glued to the roof top. The array was chosen for its simplified installation and because it could easily conform to the radius of the roof. Green construction materials used include a bamboo floor in the gym and reused building materials from the deconstructed school that was replaced. The kitchen uses new technologies that eliminate the need for a hood. The entire project breaks down to less than $200 a square foot, proving that great design and green building don’t require a huge cost burden. In fact, with all said and done, this could be the cheapest school to run in America!

Pop-Up Village for Haiti Made From 900 Shipping Containers

Pop-Up Village for Haiti Made From 900 Shipping Containers

vilaj vilaj, luck mervil, haiti, shipping container housing, 
earthquake disaster relief
Haitian Canadian musician Luck Mervil is leading the charge to help rebuild Haiti with houses made from repurposed shipping containers. Mervil is behind the Montreal organization Vilaj Vilaj, which wants to use 900 shipping containers to build an entirely new village west of Port-au-Prince fit for 5,000 people. The organization aims to build sustainable and long-term housing in Haiti — and eventually elsewhere — with the help of local Haitians.
Mervil, who has put his own career aside to work on this important project, expects the entire community to cost around $25 million and has been ardently working to raise the funds. The new village will be built on a parcel of previously uninhabited land near Leogane, a coastal city west of Port-au-Prince. A prototype shipping container house was built in Canada in 10 days for between $8,000 and $10,000, and Mervil expects the costs to be much lower in Haiti.
The village will consist of a series of 900 shipping containers grouped together in a grid and separated by open space, parks, and playing fields. Both 40 and 20-foot containers will be used to construct durable, long-term and hurricane and earthquake resistant homes. Each home will offer roughly 320 sq feet of living space with running water and bathrooms. The village will also be self-sufficient, with space for companies to set up shop so that villagers can work and support themselves.

 

MIT’s Solar Funnel Concentrates Solar Energy 100 Times

MIT’s Solar Funnel Concentrates Solar Energy 100 Times

by Timon Singh
mit solar funnel, mit nanotubes, solar funnel nanotubes, strano 
solar funnel, nanotube antenna strano, nanotube antenna, solar funnel, 
mit nanoturbe antenna, mit solar funnel, mit michael strano,
A group of chemical engineers at MIT have devised a way to collect solar energy 100 times more concentrated than a traditional photovoltaic cell. If their ’solar funnel’ venture proves to be a success, it could drastically alter how solar energy is collected in the future — there will no longer be a need for massive solar arrays or extensive space to generate significant and sufficient amounts of power. The engineers’ research has determined that carbon nanotubes – hollow tubes made up of carbon atoms — will be the primary instrument in capturing and focusing light energy, allowing for not just smaller, but more powerful solar arrays.
The antenna itself is incredibly small – it consists of a fibrous rope about 10 micrometers (millionths of a meter) long and four micrometers thick, containing about 30 million carbon nanotubes. The prototype made by Strano’s team consisted of a fiber made of two layers of nanotubes, each with different electrical properties.
When a photon strikes the surface of the solar funnel, it excites an electron to a higher energy level, which is specific to the material. The relationship between the energized electron and the hole it leaves behind is called an exciton, and the difference in energy levels between the hole and the electron is known as the bandgap.
The inner layer of the antenna contains nanotubes with a small bandgap, and nanotubes in the outer layer have a higher bandgap. Excitons like to flow from high to low energy, and in the solar funnel’s case means they can flow from the outer layer to the inner layer where they can exist in a lower energy state. When light strikes the antenna, all of the excitons flow to the center of the antenna where they are concentrated and the photons are converted to an electrical current. Like with all solar cells however, its efficiency depends on the materials utilized for the electrode.
mit solar funnel, mit nanotubes, solar funnel nanotubes, strano 
solar funnel, nanotube antenna strano, nanotube antenna, solar funnel, 
mit nanoturbe antenna, mit solar funnel, mit michael strano,
Strano’s team is the first to construct nanotube fibers in which the properties of different layers can be controlled — an achievement made possible by recent advances in separating nanotubes with different properties. It is not just the higher rate of concentrated energy that makes the solar funnels a breakthrough — by utilizing carbon nanotubes, solar cells can be constructed at a lower-cost than traditional silicon-based solar cells.
While the cost of carbon nanotubes was once prohibitive, it has come down in recent years as chemical companies build up their manufacturing capacity. “At some point in the near future, carbon nanotubes will likely be sold for pennies per pound, as polymers are sold,” says Strano. “With this cost, the addition to a solar cell might be negligible compared to the fabrication and raw material cost of the cell itself, just as coatings and polymer components are small parts of the cost of a photovoltaic cell.”
In theory, with this new technology, not only could the solar funnels be used to generate power, but they could be used in applications where light needs to be concentrated — such as telescopes or night-vision goggles. The design behind the solar funnel is quite innovative, by capturing the light in a tube, Strano’s solar funnel, also know as an nanotube antenna, boosts the number of photons that can be transformed into energy, but in a similar process to that of tradition solar cells.
Strano’s team is now reportedly working on ways to minimize the energy lost as excitons flow through the fiber, as well as new antennas that would lose only 1 percent of the energy they absorb versus the standard 13 percent.

Cambridge University Produces Cheap Plastic Organic Solar Cell

Cambridge University Produces Cheap Plastic Organic Solar Cell

university of cambridge cavendish, organic photovoltaic cell, 
organic solar cell, organic solar plastic cell, cavendish laboratory 
carbon trust
The University of Cambridge has developed a low cost organic solar cell that has the potential to transform solar production. This new material is made of organic plastic and could be used on awnings, umbrellas and other plastic devices to generate energy.
The university team has reportedly come up with a commercial model that combines efficiency improvements, a longer lifespan, low-cost (and low-toxicity) raw materials, a cost-effective manufacturing process, and a product line that focuses on economies of scale and ease of installation. If this can be done, then cheaply produced solar cells have the ability to transform poorer countries and their energy demands.
The university’s Cavendish Laboratory and the Carbon Trust have formed a joint venture company to develop organic solar PV technology, which has been financed with a £4.5 million initial investment from the Trust and specialty chemicals firm Rhodia. Cavendish Labs have reportedly fine-tuned the capability for fabricating large-scale plastic electronic devices on flexible materials using roll-to-roll processes. The new company will be able to focus on developing organic photovoltaics (OPV) on flexible rolls, enabling them to be used more readily and discretely on buildings – and potentially other objects – than conventional rigid photovoltaic panels.
Not only can organic photovoltaic plastic be molded for any purpose, but it can be spray-painted on objects, be it buildings, cars or otherwise. There are also investigations in to creating a silicon-based solar paint, but if organic photovoltaic paint can be produced first, and more cheaply, then it could transform the solar market. Instead of acres of solar cells, cities could be transformed using solar plastics, not to mention the more environmental alternative – bioplastics, which are made from waste-water instead of petroleum.

Water and water filtration


New Nanotech Purifier Filters Water 80,000 Times Faster

by Cameron Scott
nanotechnology, water, drinking water, yi cui, sarah heilshorn, 
stanford university, sustainable design, global development, health
A new water filter that employs cotton dipped in nano-sized silver wires and copper tubes works 80,000 times faster than filters that simply block bacteria from getting through. The filter, developed by Stanford University researchers for use in developing countries, efficiently conducts a tiny charge of electricity, zapping 98 percent of all bacteria.
Millions of people die in rural and undeveloped areas every year from exposure to contaminated drinking water. The challenge is to create processes that work cheaply and reliably and uses materials that are light enough to transport. The pass-through filter is less likely to fail due to clogging or becoming infested with the bacteria it’s intended to kill: if bacteria cling to it, the silver kills them. And because its nano-materials are especially efficient conductors of electricity, the filter can get the jolt it needs from a small solar panel, a hand crank or 12-volt car batteries.
Unfortunately, when it comes to drinking water, 98 percent isn’t an adequate kill rate, so water would have to be filtered more than once. But since the filter works 80,000 times faster, there’s plenty of time for that.


 
Environmental Health Issues
Water

Cancer & Chlorine
Is the chlorine in our drinking water acting as catalyst triggering tumor development both in atherosclerosis and cancer? The addition of chlorine to our drinking water started in the late 1890’s and had wide acceptance in the United States by 1920. Joseph Price, M. D, wrote a fascinating yet largely ignored book in the late 1960’s, entitled Coronaries Cholesterol. Chlorine, Dr Price believes, is the primary and essential cause of atherosclerosis is chlorine. "Nothing can negate the incontrovertible fact the basic cause of atherosclerosis and resulting entities, such as heart attacks and most common forms of stokes is chlorine. The chlorine contained in processed drinking water." (1)
This conclusion is based on experiments using chlorine in the drinking water of chickens. The results: 95% of the chickens given chlorine added to distilled water developed atherosclerosis within a few months.
Atherosclerosis, heart attacks and the resulting problems of hardening of the arteries and plaque formation is really the last step in a series of biochemical malfunctions. Price points out it takes ten to twenty years before symptoms in humans become evident In many ways, this is reminiscent of cancer which can take twenty to thirty years to develop.
Can chlorine be linked to cancer too? In the chlorination process itself, chlorine combines with natural organic matter decaying vegetation to form potent cancer causing trihalomethanes (THM’s) or haloforms. Trihalomethanes collectively include such carcinogens as chloroforms, bromoforms carbon tectachloride, bischlorothane and others. The amount of THM’s in our drinking water is theoretically regulated by the EPA. Although the maximum amount allowed by law is 100 ppb, a 1976 study showed 31 of 112 municipal water systems exceeded this limit. (2)
According to some studies by 1975, the number of chemical contaminants found in finished drinking water exceeded 300. (3) In 1984 over 700 chemicals had been found in our drinking water The EPA has targeted 129 as posing the greatest threat to our health, Currently the EPA enforces federal standards for 34 drinking water contaminants. In July, 1990 they proposed adding 23 new ones and expects this list increasing to 85 in 1992. (4)
Another report claims the picture is much worse. According to Troubled Waters on Tap "over 2100 contaminants have been detected in U. S. drinking water since 1974 with 190 known or suspected to cause adverse health effects at certain concentration levels. In total, 97 carcinogens and suspected carcinogens, 82 mutagens and suspected mutagens, 28 acute and chronic toxic contaminants and 23 tumor promoters have been detected in U. S. drinking water since 1974. The remaining 90% of the organic matter present in drinking water has not been identified by testing to-date.
Compounds in these concentration could pose serious toxic effects, either alone or in combination with other chemicals found in drinking water. Overall, available scientific evidence continues to substantiate the link between consumption of toxins in drinking water and serious public health concerns, Studies have strengthened the association between ingestion of toxins and elevated cancer mortality risks"(5)
Studies in New Orleans, Louisiana; Eric County, New York, Washington County Maryland, Ohio County, Ohio reveal high levels of haloforms or THM ‘s in drinking water The result – higher levels of cancer. (6) (7) (8) (9)
‘The continued use of chlorine as the main drinking water disinfectant in the United States only adds to the organic chemical contamination of drinking water supplies. The current federal standard regulation of trihalomethanes do not adequately protect water consumers from the multitude of other organic chlorination by-products that have been shown in many studies to be mutagenic and toxic’(5)
"Chlorine is so dangerous" according to biologist/chemist Dr. Herbert Schwartz," that Is should be banned. Putting chlorine In the water is like starting a time bomb. Cancer heart trouble, premature senility, both mental and physical are conditions attributable to chlorine, treated water supplies. It is making us grow old before our time by producing symptoms of ageing such as hardening of the arteries. I believe if chlorine were now proposed for the first time to be used in drinking water it would be banned by the Food and Drug Administration."(10)
Many municipalities are experimenting with a variety of disinfectants to either take the place of chlorine or to be used in addition, as a way of cutting down on the amount of chlorine added to the water However these alternatives such as chlorine dioxide, bromine chloride, chloromines, etc., are just as dangerous as chlorine. We’ re replacing one toxic chemical with another.
On the positive side, some cities are starting to use aeration carbon filtration, ultraviolet light and ozone as safe alternatives to chemical disinfectants. But the number of cities and the number of people getting water from these methods is minimal.
How can chlorination be linked to heart disease and cancer? In Super Nutrition for Healthy Hearts Dr Richard Passwater shows how "the origin of heart disease is akin to the origin of cancer" Chlorination could very well be a key factor linking these two major diseases Chlorine creates THM's and haloforms. These potent chemical pollutants can trigger the production of excess free radicals in our bodies. Free radicals cause cell damage. Excess free radicals can cause normal smooth muscle cells in the arterial wall to go haywire, to mutate. The fibrous plaque consequently formed is essentially a benign tumor. (11) Unfortunately, this tumor is linked with the origin of heart disease.
If your drinking water is chlorinated, don’t drink it You can purchase very effective filters which will remove 99% of the THM’s or purchase proper bottled spring water. Just this simple safeguard may save thousands from heart disease and cancer - the two major degenerative killers in the United States.
  1. Price JM. Coronaries Cholesterol/Chlorine. NY: Pyramid, 1969.
  2. Maugh TH. New Study Links Chlorination and Cancer Science 1983; 211 (February 13): 694.
  3. Wilkins JR, Reiches NA, Kruse CW. Organic Chemical Contaminants in Drinking Water and Cancer AM. J. Epidemology 1979; 114: 179-190.
  4. U.S Water News. EPA Seeking to Expand Number of Drinking Water Contaminants to 34. August 1990: 8
  5. Conacher D. Troubled Waters on Tap Organic Chemicals in Public Drinking Water Systems and the Failure of Regulation. Wash D. C: Center for Study of Responsive Law, 1988: 114.
  6. Page T, Harris RH, Epstein SS. Drinking Water and Cancer Morality in Louisiana. Science 1976; 193: 55-57.
  7. Gottlieb DG, Osborne RH. Premiminary Report on Nationwide Study of Drinking Water and Cardiovascular Diseases. J. Environmental Pathology and Toxicology. 1980; 3: 65-76.
  8. Carlo GL, Mettlin CJ. Cancer Incidence and Trihalomethane Concentrations in a Public Water System. AM. J. Public Health 1980; 70 (May): 523-525
  9. Wilkins JR, Comstock GW. Source of Drinking Water at Home and Site-Specific Cancer Incidence in Washington County, Maryland. AM J. Epidemology. 1981; 114: 178-190.
  10. Dons Bach KW, Walker M. Drinking Water. Huntingdon Beach, CA: Int’l Institute of Natural Health Sciences, 1981.
  11. Passwater R. Supernutrition for Healthy Hearts. NY: Jova 1978.
Source: - Healthy Water, Martin Fox, PH.d.

More Solar

MIT Creates Self-Assembling Solar Cells That Repair Themselves

by Jaymi Heimbuch
mit solar cell photo
MIT's Test Cell Patrick Gillooly, MIT

Solar cells are intended to mimic the photosynthesis of plants -- converting light into energy in the most efficient manner possible. But what other characteristics of plants could be handy for the renewable energy sector to mimic? How about the self-assembly of chloroplast, the component of plants that do all the vital photosynthesis. Leaves repair themselves after sun damage again and again to keep up their ability to convert light into energy. Now, MIT researchers believe they've discovered how to use this self-assembly to restore solar cells damaged by the sun.
Popular Science writes, "To recreate this unique regenerative ability, the MIT team devised a novel set of self-assembling molecules that use photons to shake electrons loose in the form of electricity. The system contains seven different compounds, including carbon nanotubes that provide structure and a means to conduct the electricity away from the cells, synthetic phospholipids that form discs that also provide structural support, and other molecules that self-assemble into "reaction centers" that actually interact with the incoming photons to release electrons."
These compounds can assemble themselves into structures able to harvest solar energy at an efficiency of about 40%. As they loose efficiency from damage, a surfacant can be spread across them to break down the compounds, then when it is filtered out, the cells reassemble good as new. The researchers think they can eventually boost the efficiency even higher, and perhaps provide solar cells that are virtually indestructible.
MIT is constantly coming out with new possibilities for the solar industry, from solar concentrators that improve both efficiency and designs, to printing thin film solar cells on paper. And now, perhaps, solar cells that bring us even closer to completely mimicking leaves.

SkyFuel’s SkyTrough is World’s Most Efficient Solar Concentrator

skyfuel skytrough, skyfuel efficiency, skytrough efficiency, nrel 
skytrough, Skyfuel claim, skytrough concentrator
When it comes to producing solar power, efficiency is the key – efficiency of the panels, efficiency of the system’s collectors and, according to SkyFuel, efficiency of the solar concentrator technology. Solar concentrators are increasingly being used in the industry, due to their efficiency in providing cheap solar energy. By harnessing the sun’s energy, a solar concentrator can provide the necessary heat for dozens of homes and thus save electricity. As such, the systems are more efficient than regular solar generators as captured power is not just converted into electricity. But according to SkyFuel, a U.S.-based company, their SkyTrough solar concentrator technology has a thermal efficiency of 73% at 350˚C (662˚F). More than just a shallow claim, their statement has been confirmed by the National Renewable Energy Laboratory (NREL), which has certified the SkyTrough solar concentrator technology to have the highest efficiency in its class!
Performance of the optical elements of the SkyTrough was measured at the Optical Efficiency Test Loop in Golden, Colorado. The test facility was designed to allowed the study of the optical performance independent of the receiver’s heat loss characteristics. Optical efficiency is a direct gauge of the design elements unique to the SkyTrough’s mirror reflectance, parabolic accuracy, receiver alignment to the focal line of the trough, and the system’s tracking precision. ”The SkyTrough solar collector is a new, low-weight design that takes advantage of the patented reflector film jointly developed by SkyFuel and NREL,” said Chuck Kutscher, Principal Engineer and Manager of NREL’s Thermal Systems Group.
In a statement from SkyFuel, the company’s Chief Technology Officer Randy Gee said, “A lot of thoughtful engineering went into the SkyTrough, so we were confident our efficiency would be high, but NREL’s confirmation really validates our technology. We couldn’t be more pleased with NREL’s assessment.”
Parabolic trough solar concentrators, such as the SkyTrough, are designed to harness the sun’s energy to make steam for electricity generation. The more efficiently that a trough can harness the sun’s energy and convert it to steam, the more electricity it will be able to make. In the SkyTrough’s case, nearly three quarters of the solar radiation is thus converted into thermal energy, and then into electricity – a very high figure for solar power production. The fact that the thermal-to-electricity loss is only 27% is quite remarkable considering the large losses of efficiency that occur within the industry.

Global Solar rolls out stick-on solar panels

Glue may be the magic ingredient to making solar power cheaper.
Solar company Global Solar introduced a line of flexible solar modules which are designed for flat commercial rooftop buildings.
Rather than install racking systems to hold heavy glass-covered solar panels, the company's PowerFlex BIPV modules can be adhered onto a roof or built right into roofing materials. The modules are quicker to installer, lighter, and don't require any penetrations into the roof, according to the company.
The installed cost of Global Solar modules is about the same as traditional polycrystalline silicon panels with racks, said Jean-Noel Poirier, the vice president of marketing and business development. But because there is no need for spacing between racks, the flexible thin-film modules can cover more roof space and generate more power, he said.
The company plans to sell its solar modules--long strips of solar panels which almost 19 feet long and one and a half feet wide--through roof membrane manufacturers. The solar cells are made from a combination of copper, indium, selenium, and gallium (CIGS) and perform comparatively well in areas that don't have direct sun, Poirier said.
The company plans to get certification for the modules, which are being evaluated by roofing membrane companies now, by the end of the year and start production early next year.
Global Solar, one of many solar companies developing CIGS solar cells and modules, now has 75 megawatts worth of production capacity at two plants in Tucson, Arizona and Berlin, Germany. Until now, the company has supplied solar cells to panel manufacturers, but the company is now manufacturing its own modules for building-integrated photovoltaics, said CEO Jeff Britt.

New Black Silicon Solar Cells are Cheap and Absorb More Sun

efficient solar cells, increased efficiency for solar cells, how 
to increase solar efficiency
While the reflective and shiny solar panels that researchers have been making thus far look pretty, they’re no match for the National Renewable Energy Laboratory’s (NREL) recently discovered black silicon solar cell. The scientists at NREL discovered that etching thousands of tiny holes into a silicon wafer causes it to be almost black and thus able to absorb almost all of the sun’s rays, and more absorbent solar cells mean more efficient panels.
We recently reported on researchers that are using off the shelf dyes to help solar cells absorb a wider range of light but this experiment goes even further. No color can stand up to black when it comes to absorbing . Black doesn’t bounce anything back – it hoards all photons for itself. The researchers got the idea from a team in Munich that had carefully placed a thin layer of gold and some fancy chemicals on their silicon to turn it black.
By mixing gold and chemicals into a cocktail and spraying it on silicon, they were able to create a black silicon wafer in under 3 minutes at room temperature. At 100 degrees Fahrenheit they can do it in less than a minute — this bodes well for mass manufacturing. They call their black silicon wet-etched, because the chemical and gold mixture is wet when applied and etches holes into the substance. Their next effort — and its a big one — is engineering a workable solar panel around their etched silicon.

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