1s^2 2s^2 2p^4
2, 8 is the electron configuration
Bohr proposed that an electron is found only in specific circular paths, or orbits, around the nucleus.
The Bohr magneton (μB) is a physical constant representing the magnetic moment of an electron in Bohr's model of the atom. The Bohr magneton is equal to eħ/2mc, where e is the elementary charge, ħ is the reduced Planck constant, and m and c are the electron's mass and speed of light respectively. The term "Bohr magnetron" is a misspelling or mispronunciation of "Bohr magneton."
Bohr's model of the atom includes fixed orbits for electrons, while the present-day model (quantum mechanics) describes electrons as existing in probability clouds around the nucleus. Bohr's model does not account for electron spin or electron-electron repulsion, which are important in the modern model. Additionally, the modern model supports the idea of electron wave-particle duality, while Bohr's model is based on more classical mechanics.
If you think to the electron configuration of lutetium this is: [Xe]4f14.5d1.6s2.
Bohr proposed that an electron is found only in specific circular paths, or orbits, around the nucleus.
2, 8 is the electron configuration
Planets.
The bohr diagram does
Bohr-Rutherford
21
energy
No, the atomic model by Niels Bohr is only applicable to atoms or ions with only one electron.
Bohr proposed that an electron is found only in specific circular paths, or orbits, around the nucleus.
Niels Bohr proposed the electron orbit model in 1913 as an improvement to the previous model proposed by Ernest Rutherford. Bohr's model suggested that electrons orbit the nucleus in specific energy levels, which helped explain the stability of the atom.
The Bohr magneton (μB) is a physical constant representing the magnetic moment of an electron in Bohr's model of the atom. The Bohr magneton is equal to eħ/2mc, where e is the elementary charge, ħ is the reduced Planck constant, and m and c are the electron's mass and speed of light respectively. The term "Bohr magnetron" is a misspelling or mispronunciation of "Bohr magneton."
Bohr's model of the atom includes fixed orbits for electrons, while the present-day model (quantum mechanics) describes electrons as existing in probability clouds around the nucleus. Bohr's model does not account for electron spin or electron-electron repulsion, which are important in the modern model. Additionally, the modern model supports the idea of electron wave-particle duality, while Bohr's model is based on more classical mechanics.