Classical physics refers to the branch of Physics whereby energy and matter are two very different concepts. It is usually based on the theory of electromagnetic radiation and the laws of motion.
Classical physics is often considered the opposite of quantum mechanics. Classical physics describes the behavior of macroscopic objects using classical laws such as Newton's laws of motion, while quantum mechanics describes the behavior of particles on a microscopic scale with wave-particle duality and uncertainty principles.
Classical mechanics fails to accurately describe the behavior of particles at the quantum level, unlike Schrödinger's equation which can predict the behavior of particles based on their wave functions. Classical mechanics does not account for wave-particle duality, uncertainty principle, and quantum superposition which are crucial in understanding quantum systems. Schrödinger's equation provides a more comprehensive and accurate description of particle behavior at the atomic and subatomic levels.
Numerous places: 1) photo-electric effect. 2) black-body radiation spectrum. 3) spectrum of hydrogen emissions. 4) interference patterns of electrons through a slit. 5) compton scattering. All of the above can be easily explained by the existence of 'quanta,' but are impossible to explain through purely classical means.
Wave particle duality is almost ignored in everyday life mainly because the reactions involved especially with light is so miniscule that it only occurs in special situations and is hardly noticeable
I can only give you my view and everyone has a different view. Maxwell's equations shows the wave nature of light not the particle nature. A lot of this has to do with energy states of matter and possible changes in their gravity curve of their space time. This level of understanding is the leading edge to understanding the universe. Now if you want to take a chance on proto-science go to my web site of subspacescience.weebly.com where I show matter and light as an interaction of subspaces. Two subspaces to make a particle of matter and two subspaces to make a ray of light.
Tunneling is a quantum phenomenon. The definition of classical is "not quantum." The remainder is left as an exercise for the reader.
The de Broglie equation can be derived by combining the principles of wave-particle duality and the equations of classical mechanics. It relates the wavelength of a particle to its momentum, and is given by h/p, where is the wavelength, h is Planck's constant, and p is the momentum of the particle.
In quantum mechanics, the classical turning point is a critical point where a particle's behavior transitions from classical to quantum. It marks the boundary between regions where classical physics and quantum mechanics are most applicable. This point is significant because it helps us understand how particles behave differently at the quantum level compared to the classical level.
No. To explain the photoelectric effect, you have to think of light as a particle, not a wave. The fact that light can be both a wave and a particle is part of quantum mechanics, not classical physics.
Quantum Mechanics "replaced" Classical Mechanics in particle physics in mid-1930s.
There is a relatively new scientific field called quantum teleportation. This technology involves the disembodiment of one subatomic particle and the recreation of the particle somewhere else. The basic unit of quantum information on the particle is transmitted without intervening space. Classical teleportation is currently impossible.
Classical physics is often considered the opposite of quantum mechanics. Classical physics describes the behavior of macroscopic objects using classical laws such as Newton's laws of motion, while quantum mechanics describes the behavior of particles on a microscopic scale with wave-particle duality and uncertainty principles.
Three fundamental principles which form the basis of classical, or newtonian, mechanics. They are stated as follows: First law: A particle not subjected to external forces remains at rest or moves with constant speed in a straight line. Second law: The acceleration of a particle is directly proportional to the resultant external force acting on the particle and is inversely proportional to the mass of the particle. Third law: If two particles interact, the force exerted by the first particle on the second particle (called the action force) is equal in magnitude and opposite in direction to the force exerted by the second particle on the first particle (called the reaction force).
Classical physics fails to accurately describe phenomena at the quantum scale, like particles behaving as waves and existing in superpositions. Quantum mechanics, with principles like wave-particle duality and quantization of energy levels, provides a more comprehensive framework to explain such phenomena. Thus, the transition from classical to quantum physics occurs due to the limitations of classical physics in describing the behavior of particles at the quantum level.
Substances that do not follow the particle model are usually those at extremely high temperatures and pressures, such as in plasma or certain quantum states, where the traditional concept of particles breaks down. Additionally, phenomena like quantum entanglement and certain aspects of dark matter and energy challenge the classical particle model.
Kinematics is the branch of classical mechanics that describes the motion of objects without consideration of the causes leading to the motion.KINEMATICS IS BRANCH OF PHYSICS DEALING WITH PHENOMENONS RELATED TO MOTION OF PARTICLE.
Classical mechanics fails to accurately describe the behavior of particles at the quantum level, unlike Schrödinger's equation which can predict the behavior of particles based on their wave functions. Classical mechanics does not account for wave-particle duality, uncertainty principle, and quantum superposition which are crucial in understanding quantum systems. Schrödinger's equation provides a more comprehensive and accurate description of particle behavior at the atomic and subatomic levels.