Posts Tagged ‘Einstein’
“Men have become the tools of their tools”*…
Visionary philosopher Bernard Stiegler argued that it’s not our technology that makes humans special; rather, it’s our relationship with that technology. Bryan Norton explains…
It has become almost impossible to separate the effects of digital technologies from our everyday experiences. Reality is parsed through glowing screens, unending data feeds, biometric feedback loops, digital protheses and expanding networks that link our virtual selves to satellite arrays in geostationary orbit. Wristwatches interpret our physical condition by counting steps and heartbeats. Phones track how we spend our time online, map the geographic location of the places we visit and record our histories in digital archives. Social media platforms forge alliances and create new political possibilities. And vast wireless networks – connecting satellites, drones and ‘smart’ weapons – determine how the wars of our era are being waged. Our experiences of the world are soaked with digital technologies.
But for the French philosopher Bernard Stiegler, one of the earliest and foremost theorists of our digital age, understanding the world requires us to move beyond the standard view of technology. Stiegler believed that technology is not just about the effects of digital tools and the ways that they impact our lives. It is not just about how devices are created and wielded by powerful organisations, nation-states or individuals. Our relationship with technology is about something deeper and more fundamental. It is about technics.
According to Stiegler, technics – the making and use of technology, in the broadest sense – is what makes us human. Our unique way of existing in the world, as distinct from other species, is defined by the experiences and knowledge our tools make possible, whether that is a state-of-the-art brain-computer interface such as Neuralink, or a prehistoric flint axe used to clear a forest. But don’t be mistaken: ‘technics’ is not simply another word for ‘technology’. As Martin Heidegger wrote in his essay ‘The Question Concerning Technology’ (1954), which used the German term Technik instead of Technologie in the original title: the ‘essence of technology is by no means anything technological.’ This aligns with the history of the word: the etymology of ‘technics’ leads us back to something like the ancient Greek term for art – technē. The essence of technology, then, is not found in a device, such as the one you are using to read this essay. It is an open-ended creative process, a relationship with our tools and the world.
This is Stiegler’s legacy. Throughout his life, he took this idea of technics, first explored while he was imprisoned for armed robbery, further than anyone else. But his ideas have often been overlooked and misunderstood, even before he died in 2020. Today, they are more necessary than ever. How else can we learn to disentangle the effects of digital technologies from our everyday experiences? How else can we begin to grasp the history of our strange reality?…
[Norton unspools Stiegler’s remarkable life and the development of his thought…]
… Technology, for better or worse, affects every aspect of our lives. Our very sense of who we are is shaped and reshaped by the tools we have at our disposal. The problem, for Stiegler, is that when we pay too much attention to our tools, rather than how they are developed and deployed, we fail to understand our reality. We become trapped, merely describing the technological world on its own terms and making it even harder to untangle the effects of digital technologies and our everyday experiences. By encouraging us to pay closer attention to this world-making capacity, with its potential to harm and heal, Stiegler is showing us what else is possible. There are other ways of living, of being, of evolving. It is technics, not technology, that will give the future its new face…
Eminently worth reading in full: “Our tools shape our selves,” from @br_norton in @aeonmag.
Compare and contrast: Kevin Kelly‘s What Technology Wants
* Henry David Thoreau
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As we own up, we might send phenomenological birthday greetings to Immanuel Kant; he was born on this date in 1724. One of the central figures of modern philosophy, Kant is remembered primarily for his efforts to unite reason with experience (e.g., Critique of Pure Reason [Kritik der reinen Vernunft], 1781), and for his work on ethics (e.g., Metaphysics of Morals [Die Metaphysik der Sitten], 1797) and aesthetics (e.g., Critique of Judgment [Kritik der Urteilskraft], 1790).
But Kant made important contributions to mathematics and astronomy. For example: his argument that mathematical truths are a form of synthetic a priori knowledge was cited by Einstein as an important early influence on his work. And his description of the Milky Way as a lens-shaped collection of stars that represented only one of many “island universes,” was later shown to be accurate by Herschel.
Act so as to treat humanity, whether in your own person or in that of another, at all times also as an end, and not only as a means.
“The metric system did not really catch on in the States, unless you count the increasing popularity of the nine-millimeter bullet”*…
Nearly everywhere in the world, folks use the metric system to measure things; here in the U.S. we use the Imperial system. (Note that Britain should really be a dark shade of green– i.e. a little yellow, mixed with a lot of blue. Brits may regularly use inches, ounces, miles, and pounds in everyday life, but have officially been Metric since 1965.)
Mike Sowden (amusingly and informatively) recounts the history of the metric system, then muses on why Imperial measures– the mile, the inch, the cubit, the ell– have staying power…
… Yes, all of these lack precision, so they’re useless for modern science, and would be incredibly dangerous if used for engineering purposes. But they also tell a story of people’s relationship with the space they moved through.
A lexis of movement – perhaps in a similar fashion to the language of landscape that writer Robert MacFarlane has done so much to retrieve.
This is why I’m on the fence about Imperial now. There’s no question that Metric is necessary as a standardised, exact form used to make cars that don’t shake themselves to bits, planes that don’t fall out the sky and spacecraft that can launch themselves to interplanetary targets with mind-blowing accuracy.
But the versions of Imperial still being used by people in everyday life deserve their place in the world too.
Anyone brought up thinking and feeling temperature in Fahrenheit can tell us Celsius-reared folk something different about how we can experience the world. Anyone cooking in pounds will be thinking about food a little differently (“well, it’s just 2 cups, isn’t it?”). All these things are tiny windows into new ways of seeing what we think we already know…
In defense of an old way of measuring: “Why Go Imperial in a World Gone Metric?” from @Mikeachim.
See also: “The real reasons the US refuses to go metric,” and explainer from Verge Science on the last big attempt to turn the US towards Metric, why it failed, and the ways scientists and manufacturers have snuck it in anyway.
* Dave Barry
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As we muse on measurement, we might pause, on Pi Day, for a piece of pi(e)…
… in celebration of Albert Einstein’s birthday; he was born on this date in 1879.
“Everything should be made as simple as possible, but not simpler.”
“Reality is merely an illusion, albeit a very persistent one”*…
In an excerpt from his new book, The Rigor of Angels: Borges, Heisenberg, Kant, and the Ultimate Nature of Reality, the estimable William Egginton explains the central mystery at the heart of one of the most important breakthroughs in physics–quantum mechanics…
For all its astonishing, mind-bending complexity– for all its blurry cats, entangled particles, buckyballs, and Bell’s inequalities– quantum mechanics ultimately boils down to one core mystery. This mystery found its best expression in the letter Heisenberg wrote to Pauli in the fevered throes of his discovery. The path a particle takes ‘only comes into existence through this, that we observe it.’ This single, stunning expression underlies all the rest: the wave/particle duality (interference patterns emerge when the particles have not yet been observed and hence their possible paths interfere with one another); the apparently absurd liminal state of Schrodinger’s cat ( the cat seems to remain blurred between life and death because atoms don’t release a particle until observed); the temporal paradox (observing a particle seems to retroactively determine the path it chose to get here); and, the one that really got to Einstein, if the observation of a particle at one place and time instantaneously changes something about the rest of reality, then locality, the cornerstone of relativity and guarantee that the laws of physics are invariable through the universe, vanishes like fog on a warming windowpane.
If the act of observation somehow instantaneously conjures a particle’s path, the foundations not only of classical physics but also of what we widely regard as physical reality crumble before our eyes. This fact explains why Einstein held fast to another interpretation. The particle’s path doesn’t come into existence when we observe it. The path exists, but we just can’t see it. Like the parable of the ball in the box he described in his letter to Schrodinger, a 50 percent chance of finding a ball in any one of two boxes does not complete the description of the ball’s reality before we open the box. It merely states our lack of knowledge about the ball’s whereabouts.
And yet, as experiment after experiment has proven, the balls simply aren’t there before the observation. We can separate entangled particles, seemingly to any conceivable distance, and by observing one simultaneously come to know something about the other–something that wasn’t the case until the exact moment of observing it. Like the beer and whiskey twins, we can maintain total randomness up to a nanosecond before one of them orders, and still what the one decides to order will determine the other’s drink, on the spot, even light-years away.
The ineluctable fact of entanglement tells us something profound about reality and our relation to it. Imagine you are one of the twins about to order a drink (this should be more imaginable than being an entangled particle about to be observed, but the idea is the same). From your perspective you can order either a whiskey or a beer: it’s a fifty-fifty choice; nothing is forcing your hand. Unbeknownst to you, however, in a galaxy far, far away, your twin has just made the choice for you. Your twin can’t tell you this or signal it in any way, but what you perceive to be a perfectly random set of possibilities, an open choice, is entirely constrained. You have no idea if you will order beer or whiskey, but when you order it, it will be the one or the other all the same. If your twin is, say, one light-year away, the time in which you make this decision doesn’t even exist over there yet. Any signals your sibling gets from you, or any signals you send, will take another year to arrive. And still, as of this moment, you each know. Neither will get confirmation for another year, but you can be confident, you can bet your life’s savings on it–a random coin toss in another galaxy, and you already know the outcome.
The riddles that arise from Heisenberg’s starting point would seem to constitute the most vital questions of existence. And yet one of the curious side effects of quantum mechanics’ extraordinary success has been a kind of quietism in the face of those very questions. The interpretation of quantum mechanics, deciding what all this means, has tended to go unnoticed by serious physics departments and the granting agencies that support them in favor of the ‘shut up and calculate’ school, leading the former to take hold mainly in philosophy departments, as a subfield of the philosophy of science called foundations of physics. Nevertheless, despite such siloing, a few physicists persisted in exploring possible solutions to the quantum riddles. Some of their ideas have been literally otherworldly.
In the 1950s, a small group of graduate students working with John Wheeler at Princeton University became fascinated with these problems and kept returning to them in late-night, sherry-fueled rap sessions. Chief among this group was Hugh Everett III, a young man with classic 1950s-style nerd glasses and a looming forehead. Everett found himself chafing at the growing no-question zone that proponents of the Copenhagen interpretation had built around their science. Why should we accept that in one quantum reality, observations somehow cause nature to take shape out of a probabilistic range of options, whereas on this side of some arbitrary line in the sand we inhabit a different, classical reality where observations meekly bow to the world out there? What exactly determines when this change takes place? ‘Let me mention a few more irritating features of the Copenhagen Interpretation,’ Everett would write to its proponents: ‘You talk of the massiveness of macro systems allowing one to neglect further quantum effects … but never give any justification for this flatly asserted dogma.’…
A fascinating sample of a fascinating book: “Quantum Mechanics,” from @WilliamEgginton via the invaluable @delanceyplace.
Further to which, it’s interesting to recall that, in his 1921 The Analysis Of Mind, Bertrand Russell observed:
What has permanent value in the outlook of the behaviourists is the feeling that physics is the most fundamental science at present in existence. But this position cannot be called materialistic, if, as seems to be the case, physics does not assume the existence of matter…
via Robert Cottrell
See also: “Objective Reality May Not Exist, Quantum Experiment Suggests” (source of the image above).
* Albert Einstein
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As we examine existence, we might spare a thought for Otto Frisch; he died on this date in 1979. A physicist, he was (with Otto Stern and Immanuel Estermann) the first to measure the magnetic moment of the proton. With his aunt, Lise Meitner, he advanced the first theoretical explanation of nuclear fission (coining the term) and first experimentally detected the fission by-products. Later, with his collaborator Rudolf Peierls, he designed the first theoretical mechanism for the detonation of an atomic bomb in 1940.
“Protons give an atom its identity, electrons its personality”*…
If the electron’s charge wasn’t perfectly round, it could reveal the existence of hidden particles– and launch a “new physics.” But, as Zack Savitsky reports, a new measurement approaches perfection…
Imagine an electron as a spherical cloud of negative charge. If that ball were ever so slightly less round, it could help explain fundamental gaps in our understanding of physics, including why the universe contains something rather than nothing.
Given the stakes, a small community of physicists has been doggedly hunting for any asymmetry in the shape of the electron for the past few decades. The experiments are now so sensitive that if an electron were the size of Earth, they could detect a bump on the North Pole the height of a single sugar molecule.
The latest results are in: The electron is rounder than that.
The updated measurement disappoints anyone hoping for signs of new physics. But it still helps theorists to constrain their models for what unknown particles and forces may be missing from the current picture…
More at “The Electron Is So Round That It’s Ruling Out Potential New Particles,” from @savagitsky in @QuantaMagazine.
* Bill Bryson
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As we ponder perfection, we might spare a thought for Jean Baptiste Perrin; he died on this date in 1942. A physicist, he studied the Brownian motion of minute particles suspended in liquids (sedimentation equilibrium), and verified Albert Einstein’s explanation of the phenomenon– thereby confirming the atomic nature of matter… for which he was awarded the Nobel Prize for Physics in 1926.
“You must not fool yourself, and you are the easiest person to fool”*…
The quest for room-temperature superconducting seems a bit like the hunt for the Holy Grail. A superconductor is a material that will transmit electricity with no resistance– thus very quickly and with no loss. (Estimates of loss in the U.S. electric grid, most of it due to heat loss from resistance in transmission, range from 5-10%; at the low end, that’s enough to power all seven Central American countries four times over.) Beyond that (already extraordinary) benefit, superconductivity could enable high-efficiency electric motors, maglev trains, low-cost magnets for MRI and nuclear fusion, a promising form of quantum computing (superconducting qubits), and much, much more.
Superconductivity was discovered in 1911, and has been the subject of fervent study ever since; indeed, four Nobel prizes have gone to scientists working on it, most recently in 2003. But while both understanding and application have advanced, it has remained the case that superconductivity can only be achieved at very low temperatures (or very high pressures). Until the mid-80s, it was believed that it could be established only below 30 Kelvin (-405.67 degrees Farenheit); by 2015, scientists had gotten that up to 80 K (-316 degrees Farenheit)… that’s to say, still requiring way too much cooling to be widely practical.
So imagine the excitement earlier this month, when…
In a packed talk on Tuesday afternoon at the American Physical Society’s annual March meeting in Las Vegas, Ranga Dias, a physicist at the University of Rochester, announced that he and his team had achieved a century-old dream of the field: a superconductor that works at room temperature and near-room pressure. Interest was so intense in the presentation that security personnel stopped entry to the overflowing room more than fifteen minutes before the talk. They could be overheard shooing curious onlookers away shortly before Dias began speaking.
The results, published in Nature, appear to show that a conventional conductor — a solid composed of hydrogen, nitrogen and the rare-earth metal lutetium — was transformed into a flawless material capable of conducting electricity with perfect efficiency.
While the announcement has been greeted with enthusiasm by some scientists, others are far more cautious, pointing to the research group’s controversial history of alleged research malfeasance. (Dias strongly denies the accusations.) Reactions by 10 independent experts contacted by Quanta ranged from unbridled excitement to outright dismissal…
Interesting if true– a paper in Nature divides the research community: “Room-Temperature Superconductor Discovery Meets With Resistance,” from @QuantaMagazine.
* Richard Feynman
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As we review research, we might pause, on Pi Day, for a piece of pi(e)…
… in celebration of Albert Einstein’s birthday; he was born on this date in 1879.
“Everything should be made as simple as possible, but not simpler.”
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