Is that all this means?
Sending construction robots into outer space will help pave the way for human exploration, but there are some real challenges that lie ahead.
In the life extension movement, longevity escape velocity (sometimes referred to as Actuarial escape velocity[1]) is a hypothetical situation in which life expectancy is extended longer than the time that is passing. For example, in a given year in which longevity escape velocity would be maintained, technological advances would increase life expectancy more than the year that just went by.
Life expectancy increases slightly every year as treatment strategies and technologies improve. At present, more than one year of research is required for each additional year of expected life. Longevity escape velocity occurs when this ratio reverses, so that life expectancy increases faster than one year per one year of research, as long as that rate of advance is sustainable.[2][3][4]
The concept was first publicly proposed by David Gobel, co-founder of the Methuselah Foundation (MF). The idea has been championed by biogerontologist Aubrey de Grey[5] (the other co-founder of the MF), and futurist Ray Kurzweil,[6] who named one of his books, Fantastic Voyage: Live Long Enough to Live Forever, after the concept. These two claim that by putting further pressure on science and medicine to focus research on increasing limits of aging, rather than continuing along at its current pace, more lives will be saved in the future, even if the benefit is not immediately apparent.[2].
Hayley Harrison Photo 3
Posted in futurism
“As an entrepreneur I like to know the next two or three things I might start a company on. For me it was robotics, bio-hacking, and quantum.”–whurley.
Earlier this year, we celebrated a first in the field of quantum physics: scientists were able to ‘teleport’ a qutrit, or a piece of quantum information based on three states, opening up a whole host of new possibilities for quantum computing and communication.
Up until then, quantum teleportation had only been managed with qubits, albeit over impressively long distances. This proof-of-concept study suggests future quantum networks will be able to carry much more data and with less interference than we thought.
If you’re new to the idea of qutrits, first let’s take a step back. Simply put, the small data units we know as bits in classical computing can be in one of two states: a 0 or a 1. But in quantum computing, we have the qubit, which can be both a 0 and 1 at the same time (known as superposition).
All evidence points to the fact that the singularity is coming (regardless of which futurist you believe).
But what difference does it make? We are talking about a difference of just 15 years. The real question is, is the singularity actually on its way?
At the World Government Summit in Dubai, I spoke with Jürgen Schmidhuber, who is the Co-Founder and Chief Scientist at AI company NNAISENSE, Director of the Swiss AI lab IDSIA, and heralded by some as the “father of artificial intelligence” to find out.
He is confident that the singularity will happen, and rather soon. Schmidhuber says it “is just 30 years away, if the trend doesn’t break, and there will be rather cheap computational devices that have as many connections as your brain but are much faster,” he said.
An international research group has applied methods of theoretical physics to investigate the electromagnetic response of the Great Pyramid to radio waves. Scientists predicted that under resonance conditions, the pyramid can concentrate electromagnetic energy in its internal chambers and under the base. The research group plans to use these theoretical results to design nanoparticles capable of reproducing similar effects in the optical range. Such nanoparticles may be used, for example, to develop sensors and highly efficient solar cells. The study was published in the Journal of Applied Physics.
While Egyptian pyramids are surrounded by many myths and legends, researchers have little scientifically reliable information about their physical properties. Physicists recently took an interest in how the Great Pyramid would interact with electromagnetic waves of a resonant length. Calculations showed that in the resonant state, the pyramid can concentrate electromagnetic energy in the its internal chambers as well as under its base, where the third unfinished chamber is located.
These conclusions were derived on the basis of numerical modeling and analytical methods of physics. The researchers first estimated that resonances in the pyramid can be induced by radio waves with a length ranging from 200 to 600 meters. Then they made a model of the electromagnetic response of the pyramid and calculated the extinction cross section. This value helps to estimate which part of the incident wave energy can be scattered or absorbed by the pyramid under resonant conditions. Finally, for the same conditions, the scientists obtained the electromagnetic field distribution inside the pyramid.
On September 20, the initial designs for the complex were presented at an event at the New York Public Library in midtown Manhattan. British firm Adjaye Associates won the contract to design the center, which will consist of three large buildings arranged around a central garden, under which will sit a museum and education center.
“We were led towards these powerful plutonic forms with a clear geometry, three cubes sitting on a plinth — though not aligned, they each have different orientations,” Sir David Adjaye told designboom. Each of the three buildings share a similar silhouette, but the facades have different architectural design and detailing, communicating the shared origins of the three religions, as well as their cultural and historical differences.
Adjaye, who also designed the Nobel Peace Centre in Oslo and the National Museum of African American History in D.C., says he saw the garden, “as a powerful metaphor, this safe space where community, connection and civility combine.”
Circa 2016
A set of new laser systems and proposed upgrades at the Department of Energy’s (DOE) Lawrence Berkeley National Laboratory (Berkeley Lab) will propel long-term plans for a more compact and affordable ultrahigh-energy particle collider.
Progress on these laser systems and laser-driven accelerators could also provide many spinoffs, such as a new tool to hunt for radioactive materials, and a miniaturized and highly tunable free-electron laser system enabling a range of science experiments.
These efforts are outlined in a DOE-sponsored workshop report that focuses on a set of 10-year road maps designed to kick-start R&D driving a next-generation particle collider for high-energy physics. The ultimate goal is a machine capable of exploring physics beyond the reach of CERN’s Large Hadron Collider (LHC). Today’s most powerful collider, the LHC enabled the discovery of the Higgs boson that resulted in the 2013 Nobel Prize in physics.