The element with 3 valence electrons in the 4d sublevel is Yttrium (Y), which has the atomic number 39. Yttrium is located in group 3 of the periodic table and is characterized by its electron configuration of [Kr] 4d^1 5s^2. In this configuration, the 4d sublevel contributes one valence electron, while the 5s contributes two, totaling three valence electrons.
The elements Y (Yttrium) to Cd (Cadmium) are filling the 4d energy sublevel. This range includes the transition metals from Yttrium (atomic number 39) to Cadmium (atomic number 48), where the 4d orbitals are progressively filled with electrons.
The element with 10 4d electrons in period 5 is zirconium (Zr). Zirconium has the atomic number 40 and is located in Group 4 of the periodic table. It is a transition metal, and its electron configuration includes 4d electrons along with 5s electrons. In its neutral state, zirconium has a total of 40 electrons, with the electron configuration [Kr] 5s² 4d².
Antimony (Sb) has an atomic number of 51, and its electron configuration is [Kr] 5s² 4d¹⁰ 5p³. In the Sb³⁺ oxidation state, it loses three electrons, typically from the 5p and 5s orbitals, resulting in the configuration [Kr] 4d¹⁰. Consequently, Sb³⁺ has no unpaired electrons, as all its electrons are paired in the filled 4d subshell.
The element that contains five electrons in its d orbital is molybdenum (Mo), which has an atomic number of 42. In its electron configuration, molybdenum is represented as [Kr] 4d^5 5s^1, indicating that it has five electrons in the 4d subshell.
Molybdenum (Mo) has a configuration of [Kr] 5s^1 4d^5. Therefore, it has 5 4d electrons.
The element with three 4d electrons is ruthenium (Ru), which has an atomic number of 44. The 4d sublevel can hold a maximum of 10 electrons, so with only three electrons, ruthenium has a partially filled 4d orbital.
The element with 3 valence electrons in the 4d sublevel is Yttrium (Y), which has the atomic number 39. Yttrium is located in group 3 of the periodic table and is characterized by its electron configuration of [Kr] 4d^1 5s^2. In this configuration, the 4d sublevel contributes one valence electron, while the 5s contributes two, totaling three valence electrons.
The elements Y (Yttrium) to Cd (Cadmium) are filling the 4d energy sublevel. This range includes the transition metals from Yttrium (atomic number 39) to Cadmium (atomic number 48), where the 4d orbitals are progressively filled with electrons.
2s: 2 electrons 5p: 6 4f: 14 3d: 10 4d: 10
The element with 10 4d electrons in period 5 is zirconium (Zr). Zirconium has the atomic number 40 and is located in Group 4 of the periodic table. It is a transition metal, and its electron configuration includes 4d electrons along with 5s electrons. In its neutral state, zirconium has a total of 40 electrons, with the electron configuration [Kr] 5s² 4d².
In iodine (I), the electron configuration is [Kr]5s²4d¹⁰5p⁵. This means that there are 10 electrons in the 4d orbital.
There are 10 electrons in the 4d subshell of the ground state of Xenon.
Antimony (Sb) has an atomic number of 51, and its electron configuration is [Kr] 5s² 4d¹⁰ 5p³. In the Sb³⁺ oxidation state, it loses three electrons, typically from the 5p and 5s orbitals, resulting in the configuration [Kr] 4d¹⁰. Consequently, Sb³⁺ has no unpaired electrons, as all its electrons are paired in the filled 4d subshell.
The element that contains five electrons in its d orbital is molybdenum (Mo), which has an atomic number of 42. In its electron configuration, molybdenum is represented as [Kr] 4d^5 5s^1, indicating that it has five electrons in the 4d subshell.
The element with ten 4d electrons in Period 5 is Palladium (Pd), which has an electron configuration of [Kr] 4d^10.
The maximum number of electrons that can occupy a 4d orbital is 10. This is because each orbital can hold a maximum of 2 electrons, and there are 5 4d orbitals available. Therefore, 2 electrons can occupy each of the 5 orbitals, giving a total of 10 electrons in the 4d orbital.