As far as the ket itself goes, multiplying it by some complex number has no physical significance. c1 |A> and (c1 + c2) |A> would refer to the same state. (For mathematical convenience, we usually normalize the state.)Einstein's Cat said:In Dirac's "The Principles of Quantum Mechanics," ket vectors are multipled by complex numbers (c1 |A> + c2 |A> = c1 + c2 |A>) and I was curious what affect this has a) on the ket vector and b) on the entire system?
I think you missed a factor of 2 there.Einstein's Cat said:Also is (c1 |A> + c2 |A> = c1 + c2 |A>) equal to (|A> + |A> = |A>)?
The purpose of exploring effects of multiplying kets by complex numbers is to understand how complex numbers affect quantum systems. This is important in quantum mechanics as it allows for a more accurate representation of physical systems and can lead to better predictions and analysis.
Complex numbers can change the state of a quantum system by altering the state vector, which represents the probability amplitudes of a system. Multiplying kets by complex numbers can result in a change in the magnitude and phase of these probability amplitudes, ultimately affecting the state of the system.
No, complex numbers can also be applied to classical systems. However, they are especially useful in quantum mechanics due to their ability to represent both magnitude and phase, which is essential in understanding quantum phenomena such as superposition and entanglement.
While complex numbers are an important tool in quantum mechanics, they do have limitations. For example, they cannot be used to represent physical quantities such as energy or position directly. They also do not have a physical interpretation, and their use is primarily mathematical.
Exploring effects of multiplying kets by complex numbers can benefit scientific research by providing a more accurate and precise understanding of quantum systems. This can lead to advancements in fields such as quantum computing, cryptography, and communication. It also allows for a deeper understanding of the fundamental principles of the universe.