Posts Tagged ‘falsification’
“The importance of experimental proof, on the other hand, does not mean that without new experimental data we cannot make advances”*…
Adam Becker explains why demanding that a theory is falsifiable or observable, without any subtlety, will hold science back…
The Viennese physicist Wolfgang Pauli suffered from a guilty conscience. He’d solved one of the knottiest puzzles in nuclear physics, but at a cost. ‘I have done a terrible thing,’ he admitted to a friend in the winter of 1930. ‘I have postulated a particle [the neutrino] that cannot be detected.’
Despite his pantomime of despair, Pauli’s letters reveal that he didn’t really think his new sub-atomic particle would stay unseen. He trusted that experimental equipment would eventually be up to the task of proving him right or wrong, one way or another. Still, he worried he’d strayed too close to transgression. Things that were genuinely unobservable, Pauli believed, were anathema to physics and to science as a whole.
Pauli’s views persist among many scientists today. It’s a basic principle of scientific practice that a new theory shouldn’t invoke the undetectable. Rather, a good explanation should be falsifiable – which means it ought to rely on some hypothetical data that could, in principle, prove the theory wrong. These interlocking standards of falsifiability and observability have proud pedigrees: falsifiability goes back to the mid-20th-century philosopher of science Karl Popper, and observability goes further back than that. Today they’re patrolled by self-appointed guardians, who relish dismissing some of the more fanciful notions in physics, cosmology and quantum mechanics as just so many castles in the sky. The cost of allowing such ideas into science, say the gatekeepers, would be to clear the path for all manner of manifestly unscientific nonsense.
But for a theoretical physicist, designing sky-castles is just part of the job. Spinning new ideas about how the world could be – or in some cases, how the world definitely isn’t – is central to their work. Some structures might be built up with great care over many years and end up with peculiar names such as inflationary multiverse or superstring theory. Others are fabricated and dismissed casually over the course of a single afternoon, found and lost again by a lone adventurer in the troposphere of thought.
That doesn’t mean it’s just freestyle sky-castle architecture out there at the frontier. The goal of scientific theory-building is to understand the nature of the world with increasing accuracy over time. All that creative energy has to hook back onto reality at some point. But turning ingenuity into fact is much more nuanced than simply announcing that all ideas must meet the inflexible standards of falsifiability and observability. These are not measures of the quality of a scientific theory. They might be neat guidelines or heuristics, but as is usually the case with simple answers, they’re also wrong, or at least only half-right.
alsifiability doesn’t work as a blanket restriction in science for the simple reason that there are no genuinely falsifiable scientific theories. I can come up with a theory that makes a prediction that looks falsifiable, but when the data tell me it’s wrong, I can conjure some fresh ideas to plug the hole and save the theory.
The history of science is full of examples of this ex post facto intellectual engineering…
[Becker recount’s The Story of Herschel’s discovery on Uranus, the challenge it posed to Newtonian gravity, and Einstein’s ultimately saving theory; then returns to Pauli and to Bohr’s attempts to use it to refute the principle of conservation of energy; and finally explores the disagreement among, Boltzmann, Maxwell and Clauisus (on the one hand) and Mach (on the other) over atomic theory. He then considers competing theories for similar outcomes (that’s to say, theories that are observationally identical)…]
… the choices we make between observationally identical theories have a big impact upon the practice of science. The American physicist Richard Feynman pointed out that two wildly different theories that have identical observational consequences can still give you different perspectives on problems, and lead you to different answers and different experiments to conduct in order to discover the next theory. So it’s not just the observable content of our scientific theories that matters. We use all of it, the observable and the unobservable, when we do science. Certainly, we are more wary about our belief in the existence of invisible entities, but we don’t deny that the unobservable things exist, or at least that their existence is plausible.
Some of the most interesting scientific work gets done when scientists develop bizarre theories in the face of something new or unexplained. Madcap ideas must find a way of relating to the world – but demanding falsifiability or observability, without any sort of subtlety, will hold science back. It’s impossible to develop successful new theories under such rigid restrictions. As Pauli said when he first came up with the neutrino, despite his own misgivings: ‘Only those who wager can win.’…
We need madcap ideas: “What is good science?,” from @FreelanceAstro in @aeonmag.
Apposite: Charles Sanders Peirce on “abduction”
* Carlo Rivelli, Reality Is Not What It Seems
###
As we ponder proof, we might spare a thought for Donald William Kerst; he died on this date in 1993. A physicist, he helped develop the experimental approach (and apparatus) that let Enrico Fermi confirm the existence of Pauli’s neutrino (among many other discoveries).
Kerst specialized in plasma physics, and worked on advanced particle accelerator concepts (accelerator physics). He developed the Betatron (1940), the first device to accelerate electrons (“beta particles”) to speeds high enough to have sufficient momentum to produce nuclear transformations in atoms. It influenced all subsequent particle accelerators.
“In so far as a scientific statement speaks about reality, it must be falsifiable: and in so far as it is not falsifiable, it does not speak about reality.”*…
If you ask philosophically minded researchers – in the Anglophone world at least – why it is that science works, they will almost always point to the philosopher Karl Popper (1902-94) for vindication. Science, they explain, doesn’t presume to provide the final answer to any question, but contents itself with trying to disprove things. Science, so the Popperians claim, is an implacable machine for destroying falsehoods.
Popper spent his youth in Vienna, among the liberal intelligentsia. His father was a lawyer and bibliophile, and an intimate of Sigmund Freud’s sister Rosa Graf. Popper’s early vocations draw him to music, cabinet making and educational philosophy, but he earned his doctorate in psychology from the University of Vienna in 1928. Realising that an academic post abroad offered escape from an increasingly antisemitic Austria (Popper’s grandparents were all Jewish, though he himself had been baptised into Lutheranism), he scrambled to write his first book. This was published as Logik der Forschung (1935), or The Logic of Scientific Discovery, and in it he put forward his method of falsification. The process of science, wrote Popper, was to conjecture a hypothesis and then attempt to falsify it. You must set up an experiment to try to prove your hypothesis wrong. If it is disproved, you must renounce it. Herein, said Popper, lies the great distinction between science and pseudoscience: the latter will try to protect itself from disproof by massaging its theory. But in science it is all or nothing, do or die.
Popper warned scientists that, while experimental testing might get you nearer and nearer to the truth of your hypothesis via corroboration, you cannot and must not ever proclaim yourself correct. The logic of induction means that you’ll never collect the infinite mass of evidence necessary to be certain in all possible cases, so it’s better to consider the body of scientific knowledge not so much true as not-yet-disproved, or provisionally true. With his book in hand, Popper obtained a university position in New Zealand. From afar, he watched the fall of Austria to Nazism, and commenced work on a more political book, The Open Society and its Enemies (1945). Shortly after the war, he moved to the UK, where he remained for the rest of his life.
For all its appealing simplicity, falsification was quickly demolished by philosophers, who showed that it was an untenable way of looking at science. In any real experimental set-up, they pointed out, it’s impossible to isolate a single hypothetical element for disproof. Yet for decades, Popperianism has nonetheless remained popular among scientists themselves, in spite of its potentially harmful side-effects. Why should this be?
…
The notion that science is all about falsification has done incalculable damage not just to science but to human wellbeing. It has normalised distrust as the default condition for knowledge-making, while setting an unreachable and unrealistic standard for the scientific enterprise. Climate sceptics demand precise predictions of an impossible kind, yet seize upon a single anomalous piece of data to claim to have disproved the entire edifice of combined research; anti-vaxxers exploit the impossibility of any ultimate proof of safety to fuel their destructive activism. In this sense, Popperianism has a great deal to answer for.
When the constructive becomes “deconstructive”– Charlotte Sleigh (@KentCHOTS) explains how a powerful cadre of scientists and economists sold Karl Popper’s “falsification” idea to the world… and why they have much to answer for: “The abuses of Popper.”
See also: “Why ‘Trusting the Science’ Is Complicated.”
* Karl Popper, The Logic of Scientific Discovery
###
As we re-engage with epistemology, we might recall that it was on this date in 1997 that Ian Wilmut, Keith Campbell, and their colleagues at the Roslin Institute (part of the University of Edinburgh, Scotland) announced that they had successfully cloned a sheep, Dolly, who had been born on July 5, 1996. Dolly lived her entire life at the Institute, where (bred with a Welsh mountain ram) she gave birth to six lambs. She died in February, 2003.
You must be logged in to post a comment.