how do particles know when they are being observed?

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how do particles know when they are being observed?

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Anonymous 0 Comments

The philosophy of non-duality (Advaita Vedanta) postulates that it’s because observer and observed are not two separate things. Reality is one indivisible infinite whole.

Anonymous 0 Comments

information=energy

To “observe” is essentially taking energy away. a particle doesn’t know it’s being observed, but taking energy away settles the particle in an energy state. But that’s not the five year old explaintion.

For the five year old, kinda like Red Light/Green Light. If something is moving too fast we can’t see it. To see it it needs to slow down.

Anonymous 0 Comments

Imagine you had to detect the exact position of an atom. To do so, you’d need to bounce something off of it to figure out where exactly it is. A solid candidate for something to bounce off of it would be a photon.

The problem is photons have a frequency, which means that sometimes you miss the atom entirely when you try to measure it. You can reduce the odds of missing it by using a photon with a shorter frequency (and thus more momentum).

However, one of the problems with bouncing photons off of atoms is they transfer momentum into the atoms when they do (much like billiards), which changes the atom’s velocity. So the more accurate you try to be, the more momentum you end up transferring into the atom. So, by “observing” the atom, you’ve actually interacted with it and changed it.

All our observation of quantum phenomena follow this pattern in some form or fashion.

Anonymous 0 Comments

Sean Carrol’s Mindscape on YouTube is a good resource. He is a proponent of the “Many Worlds” theory in which the universe splits every time a quantum event happens (yes, thats happening an unbelievable number of times per second). But if you have some time kill, he is probably the best person to listen to as his entire career is built on quantum particles being observed and doing something because of it.

The TL;DR of these quantum theories is “fields” theories – that most particles you are talking about “act” differently when the Wave AKA Schrodinger equation gets triggered and collapses into a particle. Electrons are one of the things considered to be a wave function, not a bouncing dot. Things like photons and all sorts of things are fields of energy that, when they get observed, collapse into a particle.

That is important to understand for a few reasons:

– Some people don’t believe in fields theory to the extent that others do. There are people who believe electrons ARE particles that teleport or quantum tunnel or whatever and that they are merely seeing something ***we dont understand yet.*** (not that we understand quantum phenomena to a happy degree yet).

– Some people believe EVERYTHING is one big wave instead of a lot of small waves that move through the universe. That we are all already connected and the entire universe split before you ever looked as there were only so many ways that wave could collapse so it split into all possible version and you are just in the version where it is the way it is now. so ***you are not observing a split, it already happened***. You just feel like you observed it, but it had little to do with you.

There are mature theories out there but my amateur ass can only come up with those two as the fundamental ones. I don’t think there is any kind of wide held belief that particles “know” anything and the “Conscious brain” theory of observation isn’t a widely held one because thats super unscientific. The measuring tool one makes more sense because you are somehow interfering and this is why you’ll read about tools that measure tools and they measure different part at different time of when a particle traveled. There was an article like 2 weeks ago about a particle that would have been on one side or the other of a split and one tool measure one thing and another measured another so they wouldn’t be collapsing it into just the type of thing one or the other could measure. That shit? They just don’t know.

One of the reason’s they have a hard time with this is because of quantum entanglement. They have the rule “nothing is faster than light, including information” and when you flip a quantum state, the other one, supposedly, flips instantly and that violates everything. However, they said if you were on mars and someone on earth flipped it, theyd have to send a message to you at the speed of light to tell you what theirs was to verify that yours was indeed the opposite and you wouldn’t KNOW, FOR SURE, that it worked until you got the information it happened. So when we talk about quantum information and collapse and observation, the information being transmitted by the event needs to be taken into account and that there may be something more fundamental happening we just don’t have the ability to quantify at this point.

Anonymous 0 Comments

You think of light as just something we do to see. But light comes in tiny little packets called photons, like marbles. In order to see other tiny particles, we have to shine light on them. The marbles come out of the light source, bounce off the object and back to our eyes. Just like marbles though, when our photon marble hits the object, it changes which way it’s going and how fast.

Anonymous 0 Comments

In quantum physics “observing” actually means “measuring”

In the Double Slit experiment it’s not enough to just look at the slits. You have to measure which hole it went through. This measurement affects the experiment, as you have to interact with the particle to know where it is.

Anonymous 0 Comments

At a really basic level, the only way we can observe particles is by bouncing something off them or touching them somehow (like how we have to bounce photons off an object in order for our eyes to see it). So it’s not that the particles “know” they’re being observed, it’s that in order to observe them, we have to affect them somehow, and affecting them alters their behavior.

Anonymous 0 Comments

We “observe” an atom by observing energy or matter that has already bumped into that atom. We observe it by lighting it, warming it, or pinching it in some way. The real problem is trying to study one lonely atom, floating in cold space in the dark, without changing its speed or direction or temperature, since small particles are even changed by simple light. It’s like a police officer who pulls you out of traffic, asks for your license, and shines a flashlight in your face. You’re no longer going your original speed and direction, and you’re blushing red. You have been “observed”, and it’s the method of observing you that changes you because you are sensitive to those things. We don’t have a way to hide from atoms and observe them with anything they don’t react to because they react to just everything.

Anonymous 0 Comments

They don’t “know”, but in order to observe them, we have to interact with them (often by slamming them into another particle and measuring the energy and such that’s released), and the interaction changes their energy/spin/position.

It’s not like with a microorganism where you can just… look at it through a microscope.

Anonymous 0 Comments

The short answer is “we don’t really know”. The Quantum Mechanics allows you to predict your observations (and is very good at it), but doesn’t answer the question „what really happens” (assuming this question is meaningful.

Observing a particle means it gets entangled with the observation apparatus. Why does it have to pick a classical state then is an object of interpretations of quantum mechanics. None of these was confirmed yet. Examples of interpretations are:

**Objective collapse** — when the quantum system becomes sufficiently large, something happens (e.g. because of gravity) that causes the system to fall into a classical state (this, however implies that information travels faster than light).
**Many world** — there is no collapse. Everything stays in superposition. Including the observer. There is a version of you that observes every possible outcome of the quantum experiment.
**Superdeterminism** — everything is determined. Including the fact if you decide to make an observation or not.

You can look at visualizations of some QM interpretations here: https://www.youtube.com/watch?v=XQ25E9gu4qI