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Kkangliu
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We all know that Einstein's theory apply to the big universe, and quantum mechanism apply to the nanoscopic scale, and both theory work perfectly in it's realm, but how could two theory contradict each other?
Kkangliu said:We all know that Einstein's theory apply to the big universe, and quantum mechanism apply to the nanoscopic scale, and both theory work perfectly in it's realm, but how could two theory contradict each other?
Kkangliu said:We all know that Einstein's theory apply to the big universe, and quantum mechanism apply to the nanoscopic scale, and both theory work perfectly in it's realm, but how could two theory contradict each other?
buxcador said:Matterwave: ¿Didn't quantum mechanics fully explained inertial mass? With Higgs, and other fields?
As I understand, relativity says that it shouldn't be possible to tell the difference between gravity and acceleration, and since mass is just the flow of gravity field out of a closed surface, why gravitational mass cannot be equaled to inertial mass?
Matterwave said:I'm not sure what you are directing your question towards. I don't see how the Higgs mechanism affects any of the statements I made in my post.
Einstein's theory of relativity and the quantum mechanism are two of the most groundbreaking theories in modern physics. While both have been extensively tested and confirmed, there are some fundamental differences between the two that have caused debate and confusion in the scientific community.
One major difference is that Einstein's theory of relativity describes the behavior of objects on a large scale, such as planets and galaxies, while the quantum mechanism describes the behavior of particles on a small scale, such as atoms and subatomic particles. This difference in scale can lead to seemingly contradictory predictions.
The main conflict between Einstein's theory and the quantum mechanism is that they have different explanations for how the universe works. Einstein's theory of relativity is based on the concept of space-time, where space and time are intertwined and influenced by the presence of matter and energy. On the other hand, the quantum mechanism is based on the idea that particles can exist in multiple states at once and can be influenced by observation.
While there are apparent conflicts between the two theories, scientists are constantly working to find ways to reconcile them. One approach is through the development of a theory of quantum gravity, which would combine the principles of general relativity and quantum mechanics. However, this is still a topic of ongoing research and has yet to be fully realized.
The conflict between Einstein's theory and the quantum mechanism has led to significant advancements in our understanding of the universe. It has sparked debates and discussions among scientists, which have led to the development of new theories and models. It has also highlighted the limitations of both theories and the need for further research to fully understand the workings of the universe.
It is essential to understand that both Einstein's theory and the quantum mechanism have been extensively tested and have been proven to be accurate in their respective domains. Therefore, it would be inaccurate to label one theory as "correct" and the other as "wrong." It is more productive to view them as complementary explanations of different aspects of the universe. As our understanding of the universe evolves, we may discover connections between the two theories that can help us develop a more comprehensive understanding of the universe.