- #1
Sciencelad2798
- 46
- 2
Very confused about this article and the experiment it's based on. I'm not very knowledgeable on this, but I'm very confused on what's happening here. It seems extremely weird to me
I was just confused about what was happening in layman's termsStevieTNZ said:So what's your question? And if this is going to head down the same track as your previously threads, well...
It’s OK to be confused here.Sciencelad2798 said:I was just confused about what was happening in layman's terms
.Sciencelad2798 said:Summary:: https://www.google.com/url?sa=t&source=web&rct=j&url=https://www.forbes.com/sites/fernandezelizabeth/2020/10/08/two-different-macroscopic-objects-have-been-put-in-quantum-entanglement/?sh=7447ccdf74ab&ved=2ahUKEwi9jqy8yaj0AhWIrHIEHQzZDg8QFnoECDoQAQ&usg=AOvVaw1NwKQmXGh_CaEqxRPb7DwF
Very confused about this article and the experiment it's based on. I'm not very knowledgeable on this, but I'm very confused on what's happening here. It seems extremely weird to me
See that makes more sense from a technical standpoint, but the overall idea of it still seems weird and abnormal to mephysika said:.
I recommend to you this one, much more rigorous and academic.
Testing the foundation of quantum physics in space via Interferometric and non-interferometric experiments with mesoscopic nanoparticles
https://www.nature.com/articles/s42005-021-00656-7.pdf?origin=ppub
"we survey the field of mesoscopic superpositions of nanoparticles and the potential of interferometric and non-interferometric experiments in space for the investigation of the superposition principle of quantum mechanics and the quantum-to-classical transition."
"While models beyond quantum mechanics, challenging some of its interpretational issues, have been formulated in their early days, testing the predictions of the theory when applied to the macroscopic world has proven to be a tall order. The main reason for this is the intrinsic difficulty in isolating large systems from their environment. Space offers a potentially attractive arena for such an endeavor, promising the possibility to create and verify the quantum properties of macroscopic superpositions far beyond current Earth-based capabilities"
.
Sciencelad2798 said:See that makes more sense from a technical standpoint, but the overall idea of it still seems weird and abnormal to me
Ah ok thank you. I have another question that's not directly related to this subject, but it's something that's been bothering me ever since I read it:Answer to Why is the speed of light so slow? by Dimitris Ilias https://www.quora.com/Why-is-the-sp...share=6d5aeecf&srid=uOqD3A&target_type=answerphysika said:clears weirdness instead.
Ok that does help, but I can't help but notice the weird similarities between the twof95toli said:There are a bunch of problems with this.
Firstly, most of modern science and technology is "weird"., The human brain hasn't changed much in the past 300 000 years or so and evolved to successfully survive on a savanna in Africa, not to think about quantum mechanics or what happens when we travel close to the speed of light. It is no wonder our brains struggle to grasp some of these concepts.
Secondly, you can only talk about things being "slow" if you compare it to something (even if only implicitly). Since nothing can travel faster than c it does not make sense to say that it is "slow" in absolute terms; it might be "inconveniently" slow when used for e.g. interplanetary communication but that does not mean that it is weird.
Thirdly, yes modern computers are very fast. It might help if you realize that modern computers are based on sending/receiving electromagnetic signals (i.e. light) between transistor. Modern CPUs are much smaller than 6cm so it is not THAT surprising that you can perform calculations faster than the time it takes light to travel length (which is about 0,2 ns or 5 GHz). In fact, there are circuits that operate MUCH faster than that; there are simple electronic circuits that can operate at hundreds of GHz
Lastly, this question should have gone into a new thread and not in the "Quantum Physics" forum
Macroscopic quantum entanglement is a phenomenon in which a large number of particles, typically at the macroscopic scale, become entangled and exhibit quantum properties such as superposition and non-locality.
Regular entanglement involves a small number of particles, typically at the microscopic scale, while macroscopic quantum entanglement involves a large number of particles at the macroscopic scale. Additionally, macroscopic quantum entanglement is more difficult to observe and control due to the many variables involved.
Some potential applications of macroscopic quantum entanglement include quantum computing, quantum sensing, and quantum communication. It could also potentially be used for precise measurements and in the development of new technologies.
Macroscopic quantum entanglement is studied in a variety of ways, including through experiments with large numbers of entangled particles, theoretical models and simulations, and observations of natural phenomena such as superconductivity and Bose-Einstein condensates.
One of the main challenges in understanding macroscopic quantum entanglement is the complexity of the systems involved, which makes it difficult to control and observe. There are also many unanswered questions about the nature of entanglement at the macroscopic scale and how it relates to our current understanding of quantum mechanics.