Possible energy levels of an electron in an atom is quantized. That is, there are only discrete energy levels that an electron can have, and nothing in between. These energy levels are given by E(n) = -hcR(Z^2/n^2) = -13.6 eV (Z^2/n^2) where Z is the atomic number and n is the energy level.
This is called the "ground state", all electrons occupy the orbitals of lowest energy available to them.
Successive ionization energies are the amount of energy required to remove an electron from an atom. Core electrons are closer to the nucleus and have higher ionization energies compared to valence electrons. By analyzing the ionization energy pattern, we can determine the number of core and valence electrons in an atom.
No, energies or electrons in a carbon atom cannot have arbitrary values greater than zero. They are quantized and can only have specific discrete values determined by the quantum mechanics of the atom.
No, the energies of electrons in a carbon atom are quantized, which means they can only take on specific, predetermined values. These energy levels are determined by the configuration of the atom and are restricted to specific discrete values dictated by the laws of quantum mechanics.
An atom with its electrons in the lowest possible energy level is said to be in its ground state. The ground state is the most stable configuration for an atom, with electrons occupying the available energy levels starting from the lowest.
The correct answer would be ground state
The term for an atom whose electrons have the lowest possible energies is "ground state." In this state, electrons are in their lowest energy levels or orbitals, closest to the nucleus. Excited states refer to when electrons are in higher energy levels, further away from the nucleus.
This is called the "ground state", all electrons occupy the orbitals of lowest energy available to them.
Ground state
Successive ionization energies are the amount of energy required to remove an electron from an atom. Core electrons are closer to the nucleus and have higher ionization energies compared to valence electrons. By analyzing the ionization energy pattern, we can determine the number of core and valence electrons in an atom.
No, energies or electrons in a carbon atom cannot have arbitrary values greater than zero. They are quantized and can only have specific discrete values determined by the quantum mechanics of the atom.
When all electrons in an atom are in orbitals with the lowest possible energy, the atom is in its ground state. This is the most stable arrangement for the electrons in an atom.
No, the energies of electrons in a carbon atom are quantized, which means they can only take on specific, predetermined values. These energy levels are determined by the configuration of the atom and are restricted to specific discrete values dictated by the laws of quantum mechanics.
No. Electrons will orbit around an atom only at specific energies (which change depending on the atom's atomic number and atomic mass). If you try to use a photon to change the energy of an electron and move it to another orbit path (or "energy level"), and the photon has the wrong energy in it, the electron won't change its orbit.
Electrons are generally gathered around an atom beginning with the lowest possible quantum numbers.
The more energy levels the electron jumps the more energy the emitted light will have. The more energy you have the shorter wavelength there is.
An atom with 11 protons, 12 neutrons, and 11 electrons. B. An atom with 11 protons, 10 neutrons, and 11 electrons.An atom with 11 protons, 12 neutrons, and 11 electrons.