This is the first GIF of an Atom, shot with a new Quantum Laser Camera.
You’re looking at the first ever direct observation and recording of an atom and its orbital structure.
Hydrogen atoms make up 75% of the mass in the universe, but they’ve always been too small to actually see.
A team of scientists held a hydrogen atom in a static field and shot a laser at it, causing it to shoot out electrons at a lens which magnified its wave pattern 20,000 times so a microscopic camera could see it.
The images were shot by Aneta Stodolna and the team of geniuses at The Institute for Atomic and Molecular Physics, and published in their paper ”Hydrogen Atoms under Magnification: Direct Observation”, helping confirm 30 years of theoretical predictions.
(giffed by me)
(via warrenellis)
Biological transistor enables computing within living cells
When Charles Babbage prototyped the first computing machine in the 19th century, he imagined using mechanical gears and latches to control information. ENIAC, the first modern computer developed in the 1940s, used vacuum tubes and electricity. Today, computers use transistors made from highly engineered semiconducting materials to carry out their logical operations.
And now a team of Stanford University bioengineers has taken computing beyond mechanics and electronics into the living realm of biology. In a paper to be published March 28 in Science, the team details a biological transistor made from genetic material — DNA and RNA — in place of gears or electrons. The team calls its biological transistor the “transcriptor.”
“Transcriptors are the key component behind amplifying genetic logic — akin to the transistor and electronics,” said Jerome Bonnet, PhD, a postdoctoral scholar in bioengineering and the paper’s lead author.
The creation of the transcriptor allows engineers to compute inside living cells to record, for instance, when cells have been exposed to certain external stimuli or environmental factors, or even to turn on and off cell reproduction as needed.
“Biological computers can be used to study and reprogram living systems, monitor environments and improve cellular therapeutics,” said Drew Endy, PhD, assistant professor of bioengineering and the paper’s senior author.
The biological computer
In electronics, a transistor controls the flow of electrons along a circuit. Similarly, in biologics, a transcriptor controls the flow of a specific protein, RNA polymerase, as it travels along a strand of DNA.
“We have repurposed a group of natural proteins, called integrases, to realize digital control over the flow of RNA polymerase along DNA, which in turn allowed us to engineer amplifying genetic logic,” said Endy.
Using transcriptors, the team has created what are known in electrical engineering as logic gates that can derive true-false answers to virtually any biochemical question that might be posed within a cell.
They refer to their transcriptor-based logic gates as “Boolean Integrase Logic,” or “BIL gates” for short.
Transcriptor-based gates alone do not constitute a computer, but they are the third and final component of a biological computer that could operate within individual living cells.
Despite their outward differences, all modern computers, from ENIAC to Apple, share three basic functions: storing, transmitting and performing logical operations on information.
Last year, Endy and his team made news in delivering the other two core components of a fully functional genetic computer. The first was a type of rewritable digital data storage within DNA. They also developed a mechanism for transmitting genetic information from cell to cell, a sort of biological Internet.
It all adds up to creating a computer inside a living cell.
Boole’s gold
Digital logic is often referred to as “Boolean logic,” after George Boole, the mathematician who proposed the system in 1854. Today, Boolean logic typically takes the form of 1s and 0s within a computer. Answer true, gate open; answer false, gate closed. Open. Closed. On. Off. 1. 0. It’s that basic. But it turns out that with just these simple tools and ways of thinking you can accomplish quite a lot.
“AND” and “OR” are just two of the most basic Boolean logic gates. An “AND” gate, for instance, is “true” when both of its inputs are true — when “a” and “b” are true. An “OR” gate, on the other hand, is true when either or both of its inputs are true.
In a biological setting, the possibilities for logic are as limitless as in electronics, Bonnet explained. “You could test whether a given cell had been exposed to any number of external stimuli — the presence of glucose and caffeine, for instance. BIL gates would allow you to make that determination and to store that information so you could easily identify those which had been exposed and which had not,” he said.
By the same token, you could tell the cell to start or stop reproducing if certain factors were present. And, by coupling BIL gates with the team’s biological Internet, it is possible to communicate genetic information from cell to cell to orchestrate the behavior of a group of cells.
“The potential applications are limited only by the imagination of the researcher,” said co-author Monica Ortiz, a PhD candidate in bioengineering who demonstrated autonomous cell-to-cell communication of DNA encoding various BIL gates.
Building a transcriptor
To create transcriptors and logic gates, the team used carefully calibrated combinations of enzymes — the integrases mentioned earlier — that control the flow of RNA polymerase along strands of DNA. If this were electronics, DNA is the wire and RNA polymerase is the electron.
“The choice of enzymes is important,” Bonnet said. “We have been careful to select enzymes that function in bacteria, fungi, plants and animals, so that bio-computers can be engineered within a variety of organisms.”
On the technical side, the transcriptor achieves a key similarity between the biological transistor and its semiconducting cousin: signal amplification.
With transcriptors, a very small change in the expression of an integrase can create a very large change in the expression of any two other genes.
To understand the importance of amplification, consider that the transistor was first conceived as a way to replace expensive, inefficient and unreliable vacuum tubes in the amplification of telephone signals for transcontinental phone calls. Electrical signals traveling along wires get weaker the farther they travel, but if you put an amplifier every so often along the way, you can relay the signal across a great distance. The same would hold in biological systems as signals get transmitted among a group of cells.
“It is a concept similar to transistor radios,” said Pakpoom Subsoontorn, a PhD candidate in bioengineering and co-author of the study who developed theoretical models to predict the behavior of BIL gates. “Relatively weak radio waves traveling through the air can get amplified into sound.”
Public-domain biotechnology
To bring the age of the biological computer to a much speedier reality, Endy and his team have contributed all of BIL gates to the public domain so that others can immediately harness and improve upon the tools.
“Most of biotechnology has not yet been imagined, let alone made true. By freely sharing important basic tools everyone can work better together,” Bonnet said.
(via thescienceofreality)
There’s a lot of debris floating around in space, and researchers at the Lawrence Livermore National Lab are using supercomputers, optical sensors and other technology to track even small objects that could damage important satellites.
John Henderson, a space scientist at LLNL, explains:
“Everybody uses GPS to get from here to there. We have satellite television, we have weather reports, farmers use satellite data for monitoring crops. If you have a piece of satellite debris whacking into a satellite, in the worst case you now lose that capability. In February of 2009, that actually happened where there was an Iridium communications satellite that collided with a dead Russian Kosmos satellite and so that basically took out a $100 million dollar satellite.
There’s somewhere between 100,000 to 200,000 pieces of debris that we would like to be tracking. And so the supercomputing capabilities that we have here at Livermore are one way to keep track of that.”
Synthetic Biology Explained
Stephen Hawking’s Aliens
Europa: Sea Life
A squid-like creature feeds on the bottom of the salty ocean thought to exist below the icy crust of this moon of Jupiter. Europa is the only large body, other than Earth, that may have large volumes of water capable of supporting life. If organisms exist in this perpetually dark sea, they may exhibit characteristics of deep sea creatures in Earth’s oceans, including bioluminescence and a nutrient chain based around hydrothermal vents.
Terrestrial Planet: Herbivore
On an imaginary Earth-like world, alien grazers use enormous vacuum-like trunks to extract food from the rocky surface. Organisms on distant terrestrial planets may well be strange in appearance and behavior, but the biochemical pathways and bodily structures required for life are most likely constant — within a certain range — across the universe. With an atmosphere and gravity similar to our own, these alien animals feed and move much like their living counterparts on Earth.
Terrestrial Planet: Herbivore
The design for this alien herbivore includes eyes placed on the sides of the head, a feature shared by most plant-eating animals on Earth to give them a wider field of view and early warning about predators. Eyes of alien animals would be most sensitive to the peculiar wavelengths created by the unique combination of stellar type and planetary atmosphere.
Terrestrial Planet: Predator
A trio of alien hunters prepares to attack a herd of plant-eaters. Like most carnivores on Earth, these imaginary alien creatures have binocular vision and bodies built for speed and quick reaction. These creatures also have membranes between the fore and hind limbs for gliding and a pair of venom-loaded stingers used to bring down prey.
Terrestrial Planet: Hunting
In this hypothetical hunting scene, alien predators finish off one of the large grazers with repeated poison stinger strikes. The ground surface in this view is actually a vertical cliff face (notice one of the predators falling to its death down to the river valley below). After the kill, the predators will follow the grazer’s falling carcass and feed down on the valley floor.
Ultra Low Temperature Planet
Another planetary extreme where life might be possible are worlds where the average temperatures are down around the levels of liquid nitrogen (colder than minus 300 degrees Fahrenheit). Such extremes would require organic components and physiologies radically different than those found on terrestrial planets largely dependent on liquid water. Theoretically, if energy is available in some form that can sustain biological activity — even at such low temperatures — life may be possible.
Gas Giant: Atmosphere Aliens
With gas giants like Jupiter and Saturn such a common type of planet, many scientists — and fiction writers — have wondered if life could evolve and survive in such dense, violent atmospheres. This imaginary skyscape shows what one of these gas creatures may look like even though a plausible mechanism for the origin of life in such conditions is beyond the scope of current biochemical investigations.
Spacefaring Aliens
Along with indigenous aliens, the universe probably also has a fair share of life forms that have mastered the challenges of space travel. Here a fleet of “nomadic” aliens enters a wormhole opened with technologies that are beyond human comprehension.
(via thescienceofreality)
(via thats-so-meme)
