# Number Of Valence Electrons In Hydrogen

Now, we know how many electrons are there in valence shells of hydrogen and oxygen atoms. Valence electrons given by hydrogen atoms = 1. 2 = 2 valence electrons given by sulfur atom = 6.2 = 12 Total valence electrons = 2 + 12 = 14.

### Electron Configuration

The electrons in an atom fill up its atomic orbitals according to the Aufbau Principle; 'Aufbau,' in German, means 'building up.' The Aufbau Principle, which incorporates the Pauli Exclusion Principle and Hund's Rule prescribes a few simple rules to determine the order in which electrons fill atomic orbitals:

1. Valence Electrons Chart - Valence Electrons of all the elements in table chart. This Valence Electrons chart table gives the Valence Electrons of all the elements of periodic table. Click on 'Element Atomic Number', 'Element Symbol', 'Element Name' and 'Element Valence Electrons' headers to sort.
2. Chlorine being a halogen needs another one electron to complete its octet. Likewise, hydrogen also needs one more electron to attain an octet because hydrogen’s outermost shell can hold up to 2 electrons. Thus a single bond is formed between the two atoms leading to a covalent bond formation.
1. Electrons always fill orbitals of lower energy first. 1s is filled before 2s, and 2s before 2p.
2. The Pauli Exclusion Principle states no two electrons within a particular atom can have identical quantum numbers. In function, this principle means that if two electrons occupy the same orbital, they must have opposite spin.
3. Hund's Rule states that when an electron joins an atom and has to choose between two or more orbitals of the same energy, the electron will prefer to enter an empty orbital rather than one already occupied. As more electrons are added to the atom, these electrons tend to half-fill orbitals of the same energy before pairing with existing electrons to fill orbitals.

### Valency and Valence Electrons

The outermost orbital shell of an atom is called its valence shell, and the electrons in the valence shell are valence electrons. Valence electrons are the highest energy electrons in an atom and are therefore the most reactive. While inner electrons (those not in the valence shell) typically don't participate in chemical bonding and reactions, valence electrons can be gained, lost, or shared to form chemical bonds. For this reason, elements with the same number of valence electrons tend to have similar chemical properties, since they tend to gain, lose, or share valence electrons in the same way. The Periodic Table was designed with this feature in mind. Each element has a number of valence electrons equal to its group number on the Periodic Table. This table illustrates a number of interesting, and complicating, features of electron configuration.

First, as electrons become higher in energy, a shift takes place. Up until now, we have said that as the principle quantum number, increases, so does the energy level of the orbital. And, as we stated above in the Aufbau principle, electrons fill lower energy orbitals before filling higher energy orbitals. However, the diagram above clearly shows that the 4s orbital is filled before the 3d orbital. In other words, once we get to principle quantum number 3, the highest subshells of the lower quantum numbers eclipse in energy the lowest subshells of higher quantum numbers: 3d is of higher energy than 4s.

Second, the above indicates a method of describing an element according to its electron configuration. As you move from left to right across the periodic table, the above diagram shows the order in which orbitals are filled. If we were the actually break down the above diagram into groups rather than the blocks we have, it would show how exactly how many electrons each element has. For example, the element of hydrogen, located in the uppermost left-hand corner of the periodic table, is described as 1s1, with the s describing which orbital contains electrons and the 1 describing how many electrons reside in that orbital. Lithium, which resides on the periodic table just below hydrogen, would be described as 1s22s1. The electron configurations of the first ten elements are shown below (note that the valence electrons are the electron in highest energy shell, not just the electrons in the highest energy subshell).

### The Octet Rule

Our discussion of valence electron configurations leads us to one of the cardinal tenets of chemical bonding, the octet rule. The octet rule states that atoms becomeespecially stable when their valence shells gain a full complement of valence electrons. For example, in above, Helium (He) and Neon (Ne) have outer valence shells that are completely filled, so neither has a tendency to gain or lose electrons. Therefore, Helium and Neon, two of the so-called Noble gases, exist in free atomic form and do not usually form chemical bonds with other atoms.

Most elements, however, do not have a full outer shell and are too unstable to exist as free atoms. Instead they seek to fill their outer electron shells by forming chemical bonds with other atoms and thereby attain Noble Gas configuration. An element will tend to take the shortest path to achieving Noble Gas configuration, whether that means gaining or losing one electron. For example, sodium (Na), which has a single electron in its outer 3s orbital, can lose that electron to attain the electron configuration of neon. Chlorine, with seven valence electrons, can gain one electron to attain the configuration of argon. When two different elements have the same electron configuration, they are called isoelectronic. ### Diamagnetism and Paramagnetism

The electron configuration of an atom also has consequences on its behavior in relation to magnetic fields. Such behavior is dependent on the number of electrons an atom has that are spin paired. Remember that Hund's Rule and the Pauli Exclusion Principle combine to dictate that an atom's orbitals will all half-fill before beginning to completely fill, and that when they completely fill with two electrons, those two electrons will have opposite spins. An atom with all of its orbitals filled, and therefore all of its electrons paired with an electron of opposite spin, will be very little affected by magnetic fields. Such atoms are called diagmetic. Conversely, paramagnetic atoms do not have all of their electrons spin-paired and are affected by magnetic fields. There are degrees of paramagnetism, since an atom might have one unpaired electron, or it might have four.

here is an EASY way, and a FORMAL way to draw the Lewis structure of HCN, Hydrogen cyanide:

## Formal Way

In the formal way we find how many electrons we have (step 1), how many each atom needs (step 2), how many of those are bonding (step 3 & 4), and how many are lone pairs (step 5). This info can then be used to determine the Lewis Dot Structure.

Step 1: Find valence e- for all atoms. Add them together.

H: 1
C: 4
N: 5

Total=10

## Total Number Of Valence Electrons In Hydrogen

Step 2: Find octet e- for each atom and add them together.

H: 2
C: 8
N: 8

Total=18

## Amount Of Valence Electrons In Hydrogen

Step 3: Find the bonding e-. Subtract step 1 total from step 2

18-10=8e-

Step 4: Find number of bonds by dividing the number of bonding electrons by
2 (because each bond is made of 2 e-)

8e-/2 = 4 bonds

Step 5: The rest are nonbonding pairs. Subtract bonding electrons (step 3) from valence electrons (step 1).

10-8= 2e-= 1 lone pair

Use information from step 4 and 5 to draw the HCNLewis structure.

## Lewis structure of HCN

Alternatively a dot method can be used to draw the HCN Lewis structure.

Calculate the total valence electrons in the molecule. H: 1
C: 4
N: 5

Total=10

Remember, uncharged carbon likes to have four bonds and no lone pairs. Uncharged nitrogen has three bonds and one lone pair. Hydrogen has one bond and no lone pairs.

Put carbon in the center and arrange hydrogen and nitrogen atoms on the sides. Arrange electrons until both carbon and nitrogen get a triple bond (giving an octet) and hydrogen has 2. This will put a lone pair on nitrogen.

## Number Of Valence Electrons List

A brief closing summary: The Lewis structure is used to represent bonding in a molecule, whether that be covalent or ionic. Covalent bonds are formed by sharing electrons between the atoms and are stronger than ionic bonds, which are much more of an electrostatic interactions. Most Lewis structures you encounter will be covalent bonds. Most Lewis structures will follow the octet rule, which states that the outer (valence) shell is stable when it has eight electrons. There are MANY exceptions to this rule, but it should be used as a general guide for creating Lewis structures.