Lifeboat Foundation

And today a clear lesson in why jumping the gun and not using appropriate engineering safety in regenerative medicine is reckless and dangerous. The steady and scientific path is always the best way when health is on the line. The current system needs streamlining for sure and projects like Lifespan.io are helping to create a progressive environment but ensuring appropriate safety is observed. We must be careful in healthcare and this story reminds us why.

Three women suffered severe eye damage at a Florida clinic, exposing gaps in protections for people seeking unproven treatments.

If all the solar incident on Mars were to be captured with 100% efficiency, then Mars would warm to Earth-like temperatures in about 10 years. However, the efficiency of the greenhouse effect is plausibly about 10%, thus the time it would take to warm Mars would be ~100 years. This assumes, of course, adequate production of super greenhouse gases over that entire time. The super greenhouse gases desired for use on Mars would be per fluorinated compounds (PFCs) as these are not toxic, do not destroy ozone, will resist degradation by ultraviolet life, and are composed of elements (C, S, and F) that are present on Mars. Fluorine has been detected on Mars by Curiosity.

The Warming Phase of a terraforming project on Mars results in a planet with a thick CO₂ atmosphere. The thickness is determined by the total releasable CO₂ present on Mars.

The temperatures would become well above freezing and liquid water is common. An Earth-like hydrological cycle is maintained. Photosynthetic organisms can be introduced as conditions warm and organic biomass is thus produced. A rich flora and fauna are present. A natural result of this is the biological consumption of the nitrate and perchlorate in the.

Continue reading “Warming Mars and thickening its atmosphere can be done in 10-100 years” »

Controlling the organization of nanoparticles into patterns in ultrathin polymer films can be accomplished with entropy instead of chemistry, according to a discovery by Dr. Alamgir Karim, UA’s Goodyear Tire and Rubber Company Professor of Polymer Engineering, and his student Dr. Ren Zhang. Polymer thin films are used in a variety of technological applications, for example paints, lubricants, and adhesives. Karim and Zhang have developed an original method—soft-confinement pattern-induced nanoparticle segregation (SCPINS)—to fabricate polymer nanocomposite thin films with well-controlled nanoparticle organization on a submicron scale. This new method uniquely controls the organization of any kind of nanoparticles into patterns in those films, which may be useful for applications involving sensors, nanowire circuitry or diffraction gratings, with proper subsequent processing steps like thermal or UV sintering, that are likely required but the self-organization into directed patterns.

This work, “Entropy-driven segregation of polymer -grafted nanoparticles under confinement,” has been published in the February 2017 issue of Proceedings of the National Academy of Sciences (PNAS).

Intuitively, entropy is associated with disorder of a system. However, for colloidal matter, it has been shown that a system can experience transitions which increase both entropy and visible order. Inspired by this observation, Karim and Zhang investigated the role of entropy in directed organization of polymer-grafted nanoparticles (PGNPs) in polymer thin films. By simply imprinting the blend films into patterned mesa-trench regions, nanoparticles are spontaneously enriched within mesas, forming patterned microdomain structures which coincide with the topographic pattern. This selective segregation of PGNPs is induced by entropic penalty due to the alteration of the grafted chain conformation when confined in ultrathin trench regions.

Researchers from The University of Manchester have shown it is possible to build a new super-fast form of computer that “grows as it computes”.

Professor Ross D King and his team have demonstrated for the first time the feasibility of engineering a nondeterministic universal Turing machine (NUTM), and their research is to be published in the prestigious Journal of the Royal Society Interface.

The theoretical properties of such a computing machine, including its exponential boost in speed over electronic and quantum computers, have been well understood for many years – but the Manchester breakthrough demonstrates that it is actually possible to physically create a NUTM using DNA molecules.

“The industry reports that, for the first time ever, solar was the number one source of new generating capacity, beating out wind and gas.”

Read more

NASA scientists have proposed a bold plan that could give Mars its atmosphere back and make the Red Planet habitable for future generations of human colonists.

By launching a giant magnetic shield into space to protect Mars from solar winds, the space agency says we could restore the Red Planet’s atmosphere, and terraform the Martian environment so that liquid water flows on the surface once again.

Mars may seem like a cold, arid wasteland these days, but the Red Planet is thought to have once had a thick atmosphere that could have maintained deep oceans filled with liquid water, and a warmer, potentially habitable climate.

Continue reading “NASA Wants to Launch a Giant Magnetic Field to Make Mars Habitable” »

Virginia Tech’s Visual Arts Department and Engineering Department have been joining forces to design ESCHER, a firefighting robot.

ESCHER was originally created at the beginning of 2015 in the Terrestrial Robotics Engineering and Controls Laboratory. ESCHER is short for Electronic Series Compliant Humanoid for Emergency Response.

“The special application for this project is the idea that ESCHER could go on naval ships and fight fires and go places that would normally be hazardous to humans,” said Meaghan Dee, assistant professor and chair of Visual Communications. “If you think of something like the Fukushima Disaster, you could have just sent in a robot, and that’s what these emergency robots are designed to do.”

Continue reading “In the face of danger: ESCHER, Virginia Tech’s firefighting robot primed for extreme heat conditions” »

Washington State University researchers have developed a unique, 3D manufacturing method that for the first time rapidly creates and precisely controls a material’s architecture from the nanoscale to centimeters. The results closely mimic the intricate architecture of natural materials like wood and bone.

They report on their work in the journal Science Advances and have filed for a patent.

The work has many high-tech engineering applications.

Continue reading “Novel 3D manufacturing leads to highly complex, bio-like materials” »

(sth/T.L.) – Luxembourg’s government and Tokyo-based space lunar robotic exploration company ispace Inc. on Thursday signed a Memorandum of Understanding (MoU) in the context of the SpaceResources.lu initiative with focus on developing miniaturized technology to discover, map, and utilize resources on the Moon.

Japanese start-up ispace was created by Hakuto, a finalist team of Google’s prestigious innovation competition Google Lunar XPRIZE. The company already works together with the Luxembourg Institute of Science and Technology (LIST) and will continue to do so.

Continue reading “Space Mining: Luxembourg and lunar robotic company ispace shoot for the moon” »