Erm.. one maybe? :S
To calculate the energy it takes to remove a single electron from an atom on the surface of solid rubidium (Rb), you need to divide the given energy by Avogadro's number since 1 mole contains Avogadro's number of particles (6.022 x 10^23). Therefore, the energy to remove a single electron from an atom on the surface of solid rubidium would be 208.4 kJ divided by Avogadro's number.
How much energy is required to move the electron of the hydrogen atom from the 1s to the 2s orbital
alottt!
440 - 460 nm
1310 kJ/mol
To calculate the energy it takes to remove a single electron from an atom on the surface of solid rubidium (Rb), you need to divide the given energy by Avogadro's number since 1 mole contains Avogadro's number of particles (6.022 x 10^23). Therefore, the energy to remove a single electron from an atom on the surface of solid rubidium would be 208.4 kJ divided by Avogadro's number.
The energy contained within an atom is determined by its nucleus and the arrangement of its electrons. This energy is known as the atom's binding energy, which is the amount of energy required to break the nucleus apart. The binding energy of an atom varies depending on its size and composition.
There are many reasons why power plants release so much energy from so little fuel. They really use the energy efficiently harvested from every single charged atom.
How much energy is required to move the electron of the hydrogen atom from the 1s to the 2s orbital
A living cell is much larger than an atom of hydrogen. A living cell can be as much 10,000 times larger in size compared to a single hydrogen atom.
The electron affinity of yttrium is 29.6 kilojoules per mole. This is how much energy this element releases when added to a single neutral, gaseous molecule or atom to create a negative ion.
The energy required to ionize a hydrogen atom with an electron in the n4 level is 0.85 electron volts.
Chlorine is very electronegative and pulls on the hydrogen's single electron, forming a positive end where the Hydrogen atom is, and a negative charge where the Chlorine is. This is because the Chlorine pulls much harder on the electron than Hydrogen does.
alottt!
ok, so electron affinity is the amount of energy given off when a particular atom excepts electrons. Essentially, it is the likelihood that an atom will accept an electron, while ionization energy is how much energy is needed to take an electron off of a particular atom
36.8 kj
450 nm