Yes, at 1000 degrees Celsius, mercury will be in a gaseous state. Mercury has a boiling point of 356.9 degrees Celsius, so it will have transitioned to a gas at 1000 degrees Celsius.
The electron configuration of sodium in its ground state is 1s2 2s2 2p6 3s1. This is not an excited state configuration, as the electrons are in their lowest energy levels available in the atom. Excited states occur when electrons are in higher energy levels than the ground state configuration.
Mercury's state at 25 degrees Celsius is liquid.
Mercury only has a two and one oxidation state. HgO would be the formula for mercury II oxide.
HgI2 (with the '2' small subscript - ie below the line)
The ground state shorthand notation for iron (Fe) is [Ar] 3d^6 4s^2.
(Xe)6s24f145d4
The ground-state electron configuration for copper (Cu) using noble-gas shorthand is Ar 3d10 4s1.
The ground-state electron configuration for copper (Cu) using noble-gas shorthand is [Ar] 3d¹⁰ 4s¹. This notation indicates that copper has a total of 29 electrons, with the argon (Ar) core accounting for the first 18 electrons, followed by a fully filled 3d subshell and one electron in the 4s subshell.
The ground state configuration of 1s²2s²2p²3s²3p¹ is [Ne]3s²3p¹. This notation represents the electron configuration in shorthand form, where [Ne] represents the electron configuration of the noble gas neon (1s²2s²2p⁶).
The ground state electron configuration of mercury (Hg), which has an atomic number of 80, is [Xe] 4f² 5d⁹ 6s². This configuration indicates that mercury has a filled xenon core, followed by two electrons in the 6s subshell, nine in the 5d subshell, and two in the 4f subshell.
Yes, that's correct. The notation might be wrong, though.
The spectroscopic notation for state f is f.
2HG O22HgO refers to a chemical compound, specifically a mercury(II) oxide complex. In this notation, "2HG" likely indicates the presence of a specific ligand or group attached to the mercury center. The formula suggests the presence of mercury (Hg) in its +2 oxidation state, combined with oxide (O) and possibly other functional groups. However, this specific notation is not standard and may need clarification for precise interpretation.
Mercury in thermometers is in a liquid state, since mercury is liquid at room temperature.
Mercury is the ONLY metal that is found in liquid state at room temperature. Interesting, isn't it.
You can use the Rydberg formula: ( \frac{1}{\lambda} = R_H \left( \frac{1}{n_1^2} - \frac{1}{n_2^2} \right) ), where ( \lambda ) is the wavelength of light, ( R_H ) is the Rydberg constant, ( n_1 ) is the ground state (1), and ( n_2 ) is the lowest excited state (2) for mercury. By plugging in the values for this atom, you can calculate the needed wavelength.