The condensed electron configuration for polonium is [Xe] 6s2 4f14 5d10 6p4
The condensed electron configuration for copper is Ar 3d10 4s1.
The condensed ground state electron configuration for Barium is [Xe] 6s^2. This indicates that Barium has a full inner electron shell (represented by the noble gas configuration of Xenon) and two electrons in the outermost 6s orbital.
The condensed version (which you want to use for cesium!) is [Xe]6s1 It means cesium has all the electrons in the same places that xenon has, plus one valence electron way out in the 6th level.
The electron configuration of lead (Pb) is [Xe] 4f^14 5d^10 6s^2 6p^2, where [Xe] represents the electron configuration of xenon, which is the noble gas before lead in the periodic table. Lead has 82 electrons in total.
The electron configuration for oxygen is [He]2s2.2p4.The electron configuration for sulfur is [Ne]3s2.3p4.
The condensed electron configuration for copper is Ar 3d10 4s1.
The electron configuration of mendelevium is [Rn]5f13.7s2.
cyka
[Kr],5s2,4d10,5p1
The "Noble gas electron configuration," or the condensed electron configuration, for F is [He] 2s2 3p5.
the condensed electron configuration for Lu is [Xe] 6s^2 4f^14 5d^1
The condensed ground state electron configuration for Barium is [Xe] 6s^2. This indicates that Barium has a full inner electron shell (represented by the noble gas configuration of Xenon) and two electrons in the outermost 6s orbital.
1s^2 2s^2 2p^2
the condensed electron configuration for Lu is [Xe] 6s^2 4f^14 5d^1
Fluorine's atomic number is 9. Thus, neutral fluorine has 9 protons and 9 electrons. It's total configuration then is 1s2 2s2 2p5, so its valence configuration is 2s2 2p5.
The condensed electron configuration for Rhodium (Rh) is [Kr] 4d^8 5s^1.
The condensed version (which you want to use for cesium!) is [Xe]6s1 It means cesium has all the electrons in the same places that xenon has, plus one valence electron way out in the 6th level.