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From: Savant8/17/2017 2:42:51 PM
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Xenotransplantation retroviral free pigs & Pig 2.0

msn.com


eGenesis

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To: Savant who wrote (1156)8/17/2017 2:50:55 PM
From: Savant
   of 1179
 
Beyond Y10K..... The way our world/Universe will end
msn.com

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To: Savant who wrote (1157)8/17/2017 3:03:05 PM
From: Savant
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Rare films of nuclear bomb tests...digitized for study.

Note the number of ships surrounding the blast, about 2 min into the video....hope no one was aboard

msn.com

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From: Savant8/25/2017 11:37:14 AM
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Nanotubule yarn, generates electricity when stretched...v.efficient in re:output vs weight

arstechnica.com

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From: Savant8/28/2017 7:49:48 PM
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Quantum messaging in seawater...possibly up to 900m...& beyond
msn.com

Scientists have achieved quantum communication in sea water, showcasing a futuristic concept for 'encrypted' underwater information exchange.





In a bid to devise methods for 'unhackable' ways of underwater communication, a team of researchers from Shanghai Jiao Tong University sent information between entangled particles through sea water.




The idea of quantum (secure) communication is not new and several scientists are already working on it, but this is the first instance where information has been transposed in water. The researchers have managed to communicate across a 3.3m long tank of seawater and they say the same mechanism could also be used to send 'unhackable' messages through 900m of open sea water.

To achieve this feat, the scientists followed the concept of quantum entanglement – the idea of linking two distant particles to the point where manipulation of one particle leads to an immediate and automatic reaction from its counterpart. They utilised water's well-known capability of scattering light and a prism to create the entangled particles. Put simply, a beam of light was shot into a crystal to split into a pair linked photons, with exactly opposite polarisation.

With both particles at opposite ends of the tank, the team demonstrated that despite being distant, they were able to transpose accurate information over 98% of the time.

The possible applications of the technique are evident, with the best one being integration with submarines for secure communications. In The Optical Society, the researchers wrote: "Our results confirm the feasibility of a seawater quantum channel, representing the first step towards underwater quantum communication."

The experiment is clearly promising, but as these are nascent stages, it still remains to be seen whether scientists will be able to build on this breakthrough into a future of 'quantum communication' across greater distances.



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From: Savant8/28/2017 8:28:38 PM
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More will be found, but so far>>

25 unexplained archaeological finds...some frequently mentioned, some not so often

livescience.com

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From: Savant8/30/2017 1:54:42 PM
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MIT Achieves Breakthrough in Nuclear Fusion
New experiments with helium-3 in a magnetic confinement tokamak have produced exciting results for the future of fusion energy, including a tenfold increase in ion energy.

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From: Savant9/11/2017 1:26:08 AM
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ZERGNET zergnet.com

& a whole lot more

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From: Savant9/12/2017 11:43:15 AM
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FOIP facial recognition integrated w/ voice, also head tracking/

I can see politician avatars in the future...and talking heads, in general

msn.com

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From: Savant9/19/2017 10:45:01 AM
   of 1179
 
Solar-to-fuel system recycles CO2 to make ethanol and ethylene


September 18, 2017


Schematic of a solar-powered electrolysis cell which converts carbon dioxide into hydrocarbon and oxygenate products with an efficiency far higher than natural photosynthesis. Power-matching electronics allow the system to operate over a … moreScientists at the Department of Energy's Lawrence Berkeley National Laboratory (Berkeley Lab) have harnessed the power of photosynthesis to convert carbon dioxide into fuels and alcohols at efficiencies far greater than plants. The achievement marks a significant milestone in the effort to move toward sustainable sources of fuel.

Many systems have successfully reduced carbon dioxide to chemical and fuel precursors, such as carbon monoxide or a mix of carbon monoxide and hydrogen known as syngas. This new work, described in a study published in the journal Energy and Environmental Science, is the first to successfully demonstrate the approach of going from carbon dioxide directly to target products, namely ethanol and ethylene, at energy conversion efficiencies rivaling natural counterparts.

The researchers did this by optimizing each component of a photovoltaic-electrochemical system to reduce voltage loss, and creating new materials when existing ones did not suffice.

"This is an exciting development," said study principal investigator Joel Ager, a Berkeley Lab scientist with joint appointments in the Materials Sciences and the Chemical Sciences divisions. "As rising atmospheric CO2 levels change Earth's climate, the need to develop sustainable sources of power has become increasingly urgent. Our work here shows that we have a plausible path to making fuels directly from sunlight."

That sun-to-fuel path is among the key goals of the Joint Center for Artificial Photosynthesis (JCAP), a DOE Energy Innovation Hub established in 2010 to advance solar fuel research. The study was conducted at JCAP's Berkeley Lab campus.

The initial focus of JCAP research was tackling the efficient splitting of water in the photosynthesis process. Having largely achieved that task using several types of devices, JCAP scientists doing solar-driven carbon dioxide reduction began setting their sights on achieving efficiencies similar to those demonstrated for water splitting, considered by many to be the next big challenge in artificial photosynthesis.

Another research group at Berkeley Lab is tackling this challenge by focusing on a specific component in a photovoltaic-electrochemical system. In a study published today, they describe a new catalyst that can achieve carbon dioxide to multicarbon conversion using record-low inputs of energy.


Not just for noon
For this JCAP study, researchers engineered a complete system to work at different times of day, not just at a light energy level of 1-sun illumination, which is equivalent to the peak of brightness at high noon on a sunny day. They varied the brightness of the light source to show that the system remained efficient even in low light conditions.

When the researchers coupled the electrodes to silicon photovoltaic cells, they achieved solar conversion efficiencies of 3 to 4 percent for 0.35 to 1-sun illumination. Changing the configuration to a high-performance, tandem solar cell connected in tandem yielded a conversion efficiency to hydrocarbons and oxygenates exceeding 5 percent at 1-sun illumination.



At left is a surface view of a bimetallic copper-silver nanocoral cathode taken from a scanning electron micrograph. To the right is an energy-dispersive X-ray image of the cathode with the copper (in pink/red) and silver (in green) highlighted. Credit: Gurudayal/Berkeley Lab"We did a little dance in the lab when we reached 5 percent," said Ager, who also holds an appointment as an adjunct professor at UC Berkeley's Materials Science and Engineering Department.

Among the new components developed by the researchers are a copper-silver nanocoral cathode, which reduces the carbon dioxide to hydrocarbons and oxygenates, and an iridium oxide nanotube anode, which oxidizes the water and creates oxygen.

"The nice feature of the nanocoral is that, like plants, it can make the target products over a wide range of conditions, and it is very stable," said Ager.

The researchers characterized the materials at the National Center for Electron Microscopy at the Molecular Foundry, a DOE Office of Science User Facility at Berkeley Lab. The results helped them understand how the metals functioned in the bimetallic cathode. Specifically, they learned that silver aids in the reduction of carbon dioxide to carbon monoxide, while the copper picks up from there to reduce carbon monoxide further to hydrocarbons and alcohols.

Seeking better, low-energy breakups

Because carbon dioxide is a stubbornly stable molecule, breaking it up typically involves a significant input of energy.

"Reducing CO2 to a hydrocarbon end product like ethanol or ethylene can take up to 5 volts, start to finish," said study lead author Gurudayal, postdoctoral fellow at Berkeley Lab. "Our system reduced that by half while maintaining the selectivity of products."

Notably, the electrodes operated well in water, a neutral pH environment.

"Research groups working on anodes mostly do so using alkaline conditions since anodes typically require a high pH environment, which is not ideal for the solubility of CO2," said Gurudayal. "It is very difficult to find an anode that works in neutral conditions."

The researchers customized the anode by growing the iridium oxide nanotubes on a zinc oxide surface to create a more uniform surface area to better support chemical reactions.

"By working through each step so carefully, these researchers demonstrated a level of performance and efficiency that people did not think was possible at this point," said Berkeley Lab chemist Frances Houle, JCAP deputy director for Science and Research Integration, who was not part of the study. "This is a big step forward in the design of devices for efficient CO2 reduction and testing of new materials, and it provides a clear framework for the future advancement of fully integrated solar-driven CO2-reduction devices."

Explore further: Copper catalyst yields high efficiency CO2-to-fuels conversion

More information: Gurudayal Gurudayal et al, Efficient solar-driven electrochemical CO2 reduction to hydrocarbons and oxygenates, Energy Environ. Sci. (2017). DOI: 10.1039/c7ee01764b

Journal reference: Energy and Environmental Science

Provided by: Lawrence Berkeley National Laboratory

Read more at: https://phys.org/news/2017-09-solar-to-fuel-recycles-co2-ethanol-ethylene.html#jCp

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