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The first orbital of hydrogen, which is the 1s orbital, can hold a maximum of 2 electrons.
The valence electrons fill in 4d orbital The electron configuration of yttrium is [Kr]4d15s2.
The element belongs to Group 3 of the periodic table. This is because the outermost electron configuration is 3d^(1)4s^(2), where the d orbital has one electron and the ns orbital has two electrons.
Carbon is the sixth element with a total of 6 electrons. In writing the electron configuration for carbon the first two electrons will go in the 1s orbital. Since 1s can only hold two electrons the next 2 electrons for C goes in the 2s orbital. The remaining two electrons will go in the 2p orbital. Therefore the C electron configuration will be 1s2 2s2 2p2.
All noble gases have the electron configuration s2p6.
You can determine the number of unpaired electrons in an element by examining its electron configuration. Unpaired electrons are found in the outermost energy level, and you can count them by looking for half-filled or singly occupied orbitals in the notation of the element.
The first orbital of hydrogen, which is the 1s orbital, can hold a maximum of 2 electrons.
The valence electrons fill in 4d orbital The electron configuration of yttrium is [Kr]4d15s2.
The extra electron would go into a 4s orbital because 4s can hold up to 2 electrons before 3d can be filled.
The electron configuration of an element shows the number of electrons in their energy levels and orbitals. For example, the electron configuration of a neutral magnesium atom, Mg, with 12 electrons, is 1s22s22p63s2. This means that there are two electrons in the s orbital of the first energy level, two electrons in the s orbital and six electrons in the p orbital of the second energy level, and two electrons in the s orbital of the third energy level. The number in front of each letter represents the energy level, the letter represents the orbital, and the superscripts represent the number of electrons in the orbital.
The element belongs to Group 3 of the periodic table. This is because the outermost electron configuration is 3d^(1)4s^(2), where the d orbital has one electron and the ns orbital has two electrons.
It's impossible, there are only 6 electrons in the p-orbital. So do you mean1s2 2s2 2p6? That's Neon.or do you mean1s2 2s2 2p6 3s1?That's Na, or Sodium.
The electron configuration of boron is 1s2 2s2 2p1. This means there are 2 electrons in the 1s orbital, 2 electrons in the 2s orbital, and 1 electron in the 2p orbital.
The element with the electron configuration He2s2 2p5 is fluorine. The atomic number of fluorine is 9, which means it has 9 electrons. The electron configuration represents 2 electrons in the 2s orbital and 5 electrons in the 2p orbital, giving a total of 7 valence electrons.
The electron configuration of 1s2 2s2 2p5 is for the element fluorine. Fluorine is a corrosive and poisonous gas. It has an atomic number of 9 and its group number is 17.
Carbon is the sixth element with a total of 6 electrons. In writing the electron configuration for carbon the first two electrons will go in the 1s orbital. Since 1s can only hold two electrons the next 2 electrons for C goes in the 2s orbital. The remaining two electrons will go in the 2p orbital. Therefore the C electron configuration will be 1s2 2s2 2p2.
All noble gases have the electron configuration s2p6.