Quantum mechanics explained principles like superposition of wave-particle duality of mater. It shaped a world where the classical laws of physics were merely a waste. It exposed to us a world of particles, that matter was made of many groups of particles each accomplishing a particular task just like our organs.
With the help of quantum mechanics we were able to get a 3 dimensional idea of the atom. It was able to explain the screening effect and the stark effect. It was also able to construct exact shape of orbitals and explain the formation of various types of compounds( A theory called hybridization and VSEPR and MOT came in handy thanks to quantum mechanics). It also explained the idea that atoms were composed of a lot more particles and helped predict their states nature and characteristics.
In quantum mechanics, electrons exist in a cloud-shaped area outside the nucleus. I found the concepts mind-blowing and it took me a couple of weeks to get comfortable with it.
Atomic physics and nuclear physics.
Not just of atoms - but of everything. Some things we learned is that:* There are truly random processes in nature. * We can't measure certain things with arbitrary precision (certain magnitudes, or combinations of magnitudes, in nature, aren't even DEFINED). * Particles that are quite distant from one another can be somehow connected, in a weird way.
Quantum Mechanics is valid for nearly everything (So far) it's just that the effects of it are only seen in microscopic scales like individual particles.
Einstein's work on the Photoelectric effect, which won him the Nobel prize in 1921 was a bulwark of Quantum Mechanics. Einstein went off in another direction because of his inate suspicion that Quantum Mechanics has severe internal difficulties. Quantum Mechanics and Relativity have not yet been reconciled--but they are moving together slowly. Quantum Gravity seems to be key to the issue and may be resolved by String Theory.
In quantum mechanics, electrons exist in a cloud-shaped area outside the nucleus. I found the concepts mind-blowing and it took me a couple of weeks to get comfortable with it.
Quantum Mechanics
Yes! Particles and atoms and ever larger assemblages of atoms. All this is a consequence of quantum mechanics.
Atomic physics and nuclear physics.
In the microworld the study of motion is called mechanics or classical mechanics. The study of the motion of particles in the microworld of atoms and nuclei is called quantum mechanics.
Not just of atoms - but of everything. Some things we learned is that:* There are truly random processes in nature. * We can't measure certain things with arbitrary precision (certain magnitudes, or combinations of magnitudes, in nature, aren't even DEFINED). * Particles that are quite distant from one another can be somehow connected, in a weird way.
Quantum Mechanics is valid for nearly everything (So far) it's just that the effects of it are only seen in microscopic scales like individual particles.
Quantum mechanics explained principles like superposition of wave-particle duality of mater. It shaped a world where the classical laws of physics were merely a waste. It exposed to us a world of particles, that matter was made of many groups of particles each accomplishing a particular task just like our organs. With the help of quantum mechanics we were able to get a 3 dimensional idea of the atom. It was able to explain the screening effect and the stark effect. It was also able to construct exact shape of orbitals and explain the formation of various types of compounds( A theory called hybridization and VSEPR and MOT came in handy thanks to quantum mechanics). It also explained the idea that atoms were composed of a lot more particles and helped predict their states nature and characteristics.
Einstein's work on the Photoelectric effect, which won him the Nobel prize in 1921 was a bulwark of Quantum Mechanics. Einstein went off in another direction because of his inate suspicion that Quantum Mechanics has severe internal difficulties. Quantum Mechanics and Relativity have not yet been reconciled--but they are moving together slowly. Quantum Gravity seems to be key to the issue and may be resolved by String Theory.
R. L. Longini has written: 'Introductory quantum mechanics for the solid state [by] Richard L. Longini' -- subject(s): Quantum theory, Solids, Atoms
The Bohr Model, and its the basis of quantum theory
Claude Cohen-Tannoudji has written: 'Mecanique quantique' -- subject(s): Quantum theory 'Quantum mechanics' -- subject(s): Quantum theory 'Photons and atoms' -- subject(s): Quantum electrodynamics 'Atom-photon interactions' -- subject(s): Photonuclear reactions, Quantum theory, Statistical physics