The simplest way is to have a circular extra dimension: If you move say 10-20 meters in a direction that's perpendicular to the three "standard" dimensions of space ("right", "forward" and "up") you have already moved all the way around the entire universe and returned to your starting point. (That number is just something I pulled out of my ***. The actual number could be bigger or smaller).mrlaughingman said:ahh yes sorry about that i was thinking about the string theory. but how can a dimension be microscopic exactly?
It seems very unlikely. In theory, space can be stretched even without the extra dimensions, but (I think) doing something like that always involves exotic matter of a type that has never been observed, and even if it exists, you'd have to squeeze a lot of it into a small space and keep it there.mrlaughingman said:but just out of curiosity could dimensional compression become reality?
It depends on what direction you're going in. If you go right, forward or up, and eventually get back to where you started (after traveling at least a few hundred billion light-years (probably much more)), that only means that space curves back on itself, or possibly that it has a non-trivial topology, like the space in the Asteroids game. Extra dimensions don't have anything to do with it.mrlaughingman said:so if i am understanding this then if you were to go completely around the universe and end were you started that's another dimension
Schrodinger's equation is a mathematical formula that describes the behavior of particles in quantum mechanics, specifically how their wave functions evolve over time. It is used to study the behavior of particles in multiple dimensions, including extra dimensions beyond the three that we experience in our everyday lives.
Schrodinger's equation includes additional terms that account for the existence of extra dimensions. These terms take into consideration the different possible states and interactions that particles can have in these extra dimensions, allowing scientists to better understand the behavior of particles in multi-dimensional systems.
Schrodinger's equation is a powerful tool for understanding the behavior of particles in multi-dimensional systems, including those with extra dimensions. It allows scientists to make predictions and calculations about the behavior of particles in these systems, providing valuable insights into the nature of these dimensions and their potential effects on our universe.
Schrodinger's equation is a general formula that can be applied to any number of dimensions, including extra dimensions. However, the specific terms and coefficients in the equation may vary depending on the properties and characteristics of the extra dimensions being studied.
Schrodinger's equation is a fundamental part of quantum mechanics, which is one of the most successful and widely accepted theories in modern physics. By including extra dimensions in this equation, scientists can gain a deeper understanding of the structure and behavior of the universe, helping to unravel some of the greatest mysteries of our world and beyond.