Saturday, May 28, 2011

Teaching algae to make fuel

Many kinds of algae and cyanobacteria, common water-dwelling microorganisms, are capable of using energy from sunlight to split water molecules and release hydrogen, which holds promise as a clean and carbon-free fuel for the future. One reason this approach hasn’t yet been harnessed for fuel production is that under ordinary circumstances, hydrogen production takes a back seat to the production of compounds that the organisms use to support their own growth.

But Shuguang Zhang, associate director of MIT’s Center for Biomedical Engineering, and postdocs Iftach Yacoby and Sergii Pochekailov, together with colleagues at Tel Aviv University in Israel and the National Renewable Energy Laboratory in Colorado, have found a way to use bioengineered proteins to flip this preference, allowing more hydrogen to be produced.

“The algae are really not interested in producing hydrogen, they want to produce sugar,” Yacoby says — the sugar is what they need for their own survival, and the hydrogen is just a byproduct. But a multitasking enzyme, introduced into the liquid where the algae are at work, both suppresses the sugar production and redirects the organisms’ energies into hydrogen production. The work is described in a paper being published online this week in the Proceedings of the National Academy of Sciences, and was supported in part by a European Molecular Biology Organization postdoctoral fellowship, the Yang Trust Fund and the U.S. Department of Energy’s National Renewable Energy Laboratory.

Adding the bioengineered enzyme increases the rate of algal hydrogen production by about 400 percent, Yacoby says. The sugar production is suppressed but not eliminated, he explains, because “if it went to zero, it would kill the organism.”

The research demonstrates for the first time how the two processes carried out by algae compete with each other; it also shows how that competition could be modified to favor hydrogen production in a laboratory environment. Zhang and Yacoby plan to continue developing the system to increase its efficiency of hydrogen production.

“It’s one step closer to an industrial process,” Zhang says. “First, you have to understand the science” — which has been achieved through this experimental work. Now, developing it further — through refinements to produce a viable commercial system for hydrogen-fuel manufacturing — is “a matter of time and money,” Zhang says. “We’ve had minimal money to come this far,” he says. “”With more money, we could do it faster”

Postdoc Iftach Yacoby, left, and Shuguang Zhang, associate director of MIT’s Center for Biomedical Engineering, stand in front of their experimental setup.
Photo: Patrick Gillooly
Ultimately, such a system could be used to produce hydrogen on a large scale using water and sunlight. The hydrogen could be used directly to generate electricity in a fuel cell or to power a vehicle, or could be combined with carbon dioxide to make methane or other fuels in a renewable, carbon-neutral way, the researchers say.

Bengt Nordén, chair of the physical chemistry department at the Chalmers University of Technology in Gothenburg, Sweden, says, “The results are convincing, although it is difficult to judge, at this stage, how useful this system could be for practical energy purposes.”

Nordén adds, “Hydrogen will no doubt be the future’s fuel,” either in pure form or combined to make methane. This particular method of making hydrogen, he says, “is a both simple and environmentally friendly bio-inspired system.”

In the long run, “the only viable way to produce renewable energy is to use the sun, [either] to make electricity or in a biochemical reaction to produce hydrogen,” Yacoby says. “I believe there is no one solution,” he adds, but rather many different approaches depending on the location and the end uses.

This particular approach, he says, is simple enough that it has promise “not just in industrialized countries, but in developing countries as well” as a source of inexpensive fuel. The algae needed for the process exist everywhere on Earth, and there are no toxic materials involved in any part of the process, he says.

“The beauty is in its simplicity,” he says.

Friday, May 27, 2011

Snaptu: Alarming lack of science behind European wireless tech health alert

As we reported yesterday, the Council of Europe has released a report that recommends that its member states treat the radiation used in wireless communication as a potential health hazard, one on par with cigarettes and genetically modified foods. …


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Thursday, May 26, 2011

Snaptu: NASA gives up on Mars rover Spirit recovery

CAPE CANAVERAL, Florida (Reuters) - NASA is giving up on recovering its Mars rover Spirit, which it said likely fell victim to the planet's frigid winter after seven years of work, officials said on Tuesday.


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Monday, May 23, 2011

A Legacy of Lasers

Science & Technology: A Legacy of Lasers

Ever since 1960, when physicists Charles Townes and Arthur L. Schawlow of Bell Labs received the first patent for "Light Amplification by Stimulated Emission of Radiation," Lawrence Livermore National Laboratory (LLNL) has been engaged in the study and use of lasers. And for much of that time, Livermore has been home to the world's largest lasers.

Nova Laser ChamberTHEN: Inside the Nova laser chamber. Nova, which operated at Livermore from the mid-1980s through the 1990s, produced 30 kilojoules of energy and 25 terawatts of power, making it the world's most powerful laser at the time.

Just a few weeks after Theodore Maiman demonstrated the laser for the first time at Hughes Aircraft in Malibu, California, in 1960 (see How Lasers Work), visionary scientists at LLNL recognized the possibility of using lasers to produce fusion energy. The Lab's first laser fusion project, built in 1962, studied the possibility of using powerful, short laser pulses to compress and ignite a small amount of deuterium-tritium fuel in a process dubbed inertial confinement fusion (ICF) (see How to Make a Star).

Even though the lasers of the 60s were minuscule by today's standards, LLNL started evaluating the construction of high-power lasers and laser-driven implosion schemes. The most noteworthy system in those years was named Long Path, LLNL's first neodymium-doped glass disk and multi-pass laser (neodymium is a bright, silvery rare-earth metal used as the active lasing element).

Interior of the NIF Target ChamberNOW: Inside the 118,000-kilogram target chamber of the National Ignition Facility. Completed and dedicated in 2009, NIF is designed to generate up to 1.8 megajoules and 500 terawatts of ultraviolet laser energy, making Livermore once again home to the world's most powerful laser facility.Beginning in 1972, Livermore scientists designed, built and operated a series of increasingly energetic and powerful solid-state systems. It all started with the "4 pi" system and continued with Janus, Cyclops, the two-beam Argus, the 20-beam Shiva, the two beams of Novette, the 10-beam Nova, Petawatt and Beamlet (see "Empowering Light: Historic Accomplishments in Laser Research," Science & Technology Review, September 2002).

And now, the National Ignition Facility continues that tradition. Declared operational in March 2009, NIF offers numerous unique capabilities, including the most energy of any laser facility in the world.

With its ability to provide a variety of laser pulse shapes and lengths, including the proposed ultrashort, petawatt (1015 watt) pulses (see Petawatt Lasers), NIF also will offer more power than any other laser facility. NIF will be about 20 times more powerful than the Nova laser and will deliver about 60 times more energy. When Nova operated with ultraviolet light, it produced 30 kilojoules of energy and 25 terawatts of power. In contrast, the 192-beam NIF will generate up to 1.8 megajoules and 500 terawatts of ultraviolet laser energy.

LLNL technology has supplied the seed for other large glass laser efforts in the United States, including the Omega laser at the University of Rochester in New York and the Z-Beamlet laser now at Sandia National Laboratory in Albuquerque, NM. Lasers in Japan, France, the United Kingdom, Germany and other countries around the world also use LLNL-developed technology.

 

Friday, May 20, 2011

Snaptu: Planets Without Orbits? Astronomers Make 'Exciting' Discovery

NEW YORK — Are these planets without orbits? Astronomers have found 10 potential planets as massive as Jupiter wandering through a slice of the Milky Way galaxy, following either very wide orbits or no orbit at all. And scientists think they are more…


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Wireless flexible keyboard

The freeKEY combines wireless freedom and complete functionality into the essential tool for getting the most out of any iPad, iPhone, DROID or other Bluetooth supported device.

The freeKEY makes typing with your device easy and efficient. You no longer have to struggle while completing emails or getting work done away from your desktop computer.

Flexible and water resistant, the freeKEY tucks away into your purse or messenger bag pocket while taking up hardly any room. Along with your iPad, the innovative design of the freeKEY enables it to be used with your iPad 2, iPhone, tablet, laptop and more.

wireless flexible keyboard

bluetooth wireless keyboardbluetooth wireless keyboardsflexible keyboard wireless flexible keyboard

Scosche

 

Foldable Notebook with Flexible OLED Screen

Brilliant! The Feno is a folding notebook. Typically we expect a hinge between the display and keyboard, but the Feno has an additional hinge within the display! This not only makes the size more compact but also explores future use of flexible OLED screens. The pice de rsistance is the pop-out mouse! Just pop it out and you are good to go!

Future technology  Foldable Notebook

Designer: Niels van Hoof

Future technology  Foldable Notebook   Future technology  Foldable Notebook Future technology  Foldable Notebook Future technology  Foldable Notebook

 

Tuesday, May 10, 2011

Future touch screen technology Future touch screen technology

Can you imagine organizing your daily schedule with a few touches on your bathroom mirror? Chatting with far-away relatives through interactive video on your kitchen counter? Reading a classic novel on a whisper-thin piece of flexible glass?

The video depicts a world in which interactive glass surfaces help you stay connected through seamless delivery of real-time information – whether you're working, shopping, eating, or relaxing.

Future touch screen technology 1

Future touch screen technology 4Future touch screen technology 2Future touch screen technology 3


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Sateesh.smart

Future Wallet

The Vista Wallet is the first real specialized device just designed for your spending of hard earned cash. In the 21st Century we are always connected, always available, and we can retrieve knowledge and information as soon as it's discovered. Banking and shopping are still stuck in earlier times, still obeying early closing times when money used to be counted, they still take 24 – 48 hours to clear a check and you only get monthly bank statements. Today's consumer's deserve more, as a society we are working longer hours and still have the most debt of any generation.

Future Wallet 2

The problem is a lack of an emotional connection with the spending of money that they never see. The Vista Wallet will empower the consumer allowing them to check their balances online, use analysis software so the wallet can advise on purchases and even see if it would be better to wait until next pay check. For the shopper it allows connectivity that brings a hybrid 21st century form of shopping with "scan and shop", where online and real world shopping collides in the most environmentally and consumer friendly form. Finally the Wallet will embrace "real money", using real money and using this concept as a metaphor for the device. The vista wallet will reinvent consumer spending habits and shopping for the good of the consumer.

Future Wallet 3 Future Wallet 4 Future Wallet 5 Future Wallet 1



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Sateesh.smart

Eco Biolamp!

Our world needs smart solution of green energy resource in the future, mainly the electricity. An eco friendly energy resource that is taken from nature will create health environment where the human live. Here is an innovative Biolamp concept from Hungarian industrial designer Peter Horvath. This Biolamp is designed in order to convert the CO2 into fuel that can generate the street lamp in entire city road. This Biolamp is a smart solution in creating eco environment in the city.

Future technology Eco  Biolamp

The Biolamp consists of a liquid, alga combined with water that transforms CO2 into O2­. This street lamp called Biolamp is also completed with a pump for sucking the smog.

Future technology Eco  Biolamp Future technology Eco  Biolamp

..............sateesh.smart

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