A hydrogen atom is initially four energy levels above the ground state (i.e., in the fourth excited state) when it emits a photon of wavelength 1282 nm. What is the quantum number ?f of the energy state right after the emission? List all of the allowed values for the orbital magnetic quantum number corresponding to the highest orbital quantum number of the initial state: Compare the orbital radii before (?i ) and after (?f ) the emission:
Quantum mechanics and hydrogen atom
Consider an electron of mass m moves with the velocity v in a hydrogen atom. If an electron is at a distance r from the proton, then the potential energy function of the electron can be written as follows:
Isotopes of Hydrogen Atoms
To understand isotopes, it's easiest to learn the simplest system. Hydrogen, the most basic nucleus, has received a great deal of attention. Several of the results seen in more complex nuclei can be seen in hydrogen isotopes. An isotope is a nucleus of the same atomic number (Z) but a different atomic mass number (A). The number of neutrons present in the nucleus varies with respect to the isotope.
Mass of Hydrogen Atom
Hydrogen is one of the most fundamental elements on Earth which is colorless, odorless, and a flammable chemical substance. The representation of hydrogen in the periodic table is H. It is mostly found as a diatomic molecule as water H2O on earth. It is also known to be the lightest element and takes its place on Earth up to 0.14 %. There are three isotopes of hydrogen- protium, deuterium, and tritium. There is a huge abundance of Hydrogen molecules on the earth's surface. The hydrogen isotope tritium has its half-life equal to 12.32 years, through beta decay. In physics, the study of Hydrogen is fundamental.
A hydrogen atom is initially four energy levels above the ground state (i.e., in the fourth excited state) when it emits a photon of wavelength 1282 nm.
What is the quantum number ?f of the energy state right after the emission?
List all of the allowed values for the orbital magnetic quantum number corresponding to the highest orbital quantum number of the initial state:
Compare the orbital radii before (?i ) and after (?f ) the emission:
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