In modern photon entanglement experiments process of http://en.wikipedia.org/wiki/Parametric_down_conversion" is used to generate stream of entangled photons.waylon318 said:I'll admit I have a very small understanding of this phenomena in general. I read once that entangled particles are emitted as pi mesons decay. What I am unclear about is how do scientists know when to be ready to capture them and how do they contain them? Any help would be much appreciated.
waylon318 said:I'll admit I have a very small understanding of this phenomena in general. I read once that entangled particles are emitted as pi mesons decay. What I am unclear about is how do scientists know when to be ready to capture them and how do they contain them? Any help would be much appreciated.
waylon318 said:I'll admit I have a very small understanding of this phenomena in general. I read once that entangled particles are emitted as pi mesons decay. What I am unclear about is how do scientists know when to be ready to capture them and how do they contain them? Any help would be much appreciated.
StevieTNZ said:Wouldn't when you make some measurement on the 'particle' then it will appear and collapse to one of its possible states for each of its properties?
Because what I don't understand is say entangled photons are produced they fly off in opposite directions, for example? But do they really exist then? or is it the case when a measurement is performed one can say they definitely exist?
Entangled particles are captured and contained using a variety of methods, depending on the specific type of particles. One common method is using magnetic fields to trap particles in a specific location. Another method is using lasers to slow down and trap particles. In addition, special containers and chambers are used to keep the particles contained and prevent them from interacting with the environment.
Any type of particle can potentially be entangled, including photons, electrons, atoms, and molecules. However, in order for particles to be entangled, they must be able to interact with each other and share quantum properties such as spin or polarization.
Entangled particles are created through a process called quantum entanglement. This involves causing two or more particles to interact in a way that their quantum states become correlated. This can be achieved through various methods such as splitting a single particle or using photon emitters and detectors.
The ability to capture and contain entangled particles is crucial for studying and utilizing quantum entanglement. By keeping the particles isolated and controlled, scientists can perform experiments and tests to better understand the properties and behavior of entangled particles. This is essential for developing technologies such as quantum computing and secure communication.
To measure and verify entanglement of particles, scientists use a variety of techniques such as quantum state tomography, Bell tests, and quantum correlation measurements. These methods involve measuring the properties of the particles and comparing them to expected outcomes based on quantum entanglement theory. These measurements help confirm and quantify the level of entanglement between the particles.