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What does Valence mean in chemistry?

1 Answer

Valence bond theory describes a covalent bond as the overlap of half-filled atomic orbitals (each containing a single electron) that yield a pair of electrons shared between the two bonded atoms. We say that orbitals on two different atoms overlap when a portion of one orbital and a portion of a second orbital occupy the same region of space. In chemistry, valency or valence is the number of chemical bonds that an atom of a certain element can form. For a long time, people thought that this number was a fixed property of the element in question. They thought that carbon always has four bonds, oxygen always has two, and hydrogen always has one. The problem was seen only later. Valency is the combining power of an element. Elements in the same group of the periodic table have the same valency. The valency of an element is related to how many electrons are in the outer. Valence electrons are the electrons present in the outermost shell of an atom. You can easily determine the number of valence electrons an atom can have by looking at its Group in the periodic table. For example, atoms in Groups 1 and 2 have 1 and 2 valence electrons, respectively. Atoms in Groups 13 and 18 have 3 and 8 valence electrons. In chemistry, the valence or valency of an element is the measure of its combining capacity with other atoms when it forms chemical compounds or molecules.

Valence is a term that deals with the electrons that are most typically involved in the bonding characteristics of an atom. These electrons are found in the s and p orbitals of the highest energy level of the electron configuration for the element. Micromed driver download for windows.

The valence shell can hold 2 electrons in the s orbital representing the first two columns of the periodic table and 6 electrons in the p orbital found in columns 13 - 18 of the periodic table.

Some examples would include:

Mg #1s^2 2s^2 2p^6 3s^2# Magnesium has 2 valence electrons in the 3s orbital.

Se #[Ar] 4s^2 3d^10 4p^4# Selenium has 6 valence electrons in the 4s and 4p orbitals.

Each element in the periodic table will have the same number of valence electrons as the elements in the same column. All Alkai Metals (Li, Na, K, Rb) have 1 valence electron. All Halogens (F.Cl, Br, I) have 7 valence electrons. All of the Noble Gases (Ne, Ar, Kr Xe) will have 8 valence electrons and fulfill the #Rull of Octet#.

Atoms try to gain or lose electrons to fulfill the #Rule of Octet# for the 8 electrons that can fill the s and p orbitals. An atom can take on electrons and become an negatively charged anion or can lose electrons and become a positively charged cation. Or atoms can share valence electrons during bonding.

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SMARTERTEACHER

Valence Chemistry Youtube

Related questions

Valence bond (VB) theory assumes that all bonds are localized bonds formed between two atoms by the donation of an electron from each atom. This is actually an invalid assumption because many atoms bond using delocalized electrons. In molecular oxygen VB theory predict that there are no unpaired electrons. VB theory does a good job of qualitatively describing the shapes of covalent compounds. While Molecular Orbital (MO) theory is good for understanding bonding in general. It is more difficult to learn, but predicts the actual properties of molecules better than VB theory. MO theory actually predicts electron transitions because of the differences in the energy levels of orbitals in the molecule. MO theory has been more correct in numerous instances and for this reason it is preferred.

Valence Bond theory describes covalent bond formation as well as the electronic structure of molecules. The theory assumes that electrons occupy atomic orbitals of individual atoms within a molecule, and that the electrons of one atom are attracted to the nucleus of another atom. This attraction increases as the atoms approach one another until the atoms reach a minimum distance where the electron density begins to cause repulsion between the two atoms. This electron density at the minimum distance between the two atoms is where the lowest potential energy is acquired, and it can be considered to be what holds the two atoms together in a chemical bond.

Valence Chemistry Game

• d-orbital Hybridization is a Useful Falsehood

  For main group molecules, chemists (like Pauling) thought a long time ago that hypervalence is due to expanded s²p⁶ octets. The consensus is now clear that d orbitals are NOT involved in bonding in molecules like SF₆ any more than they are in SF₄ and SF₂. In all three cases, there is a small and roughly identical participation of d-orbitals in the wavefunctions. This has been established in both MO and VB theory.

• Delocalization of Electrons

  To introduce the concept of electron delocalization from the perspective of molecular orbitals, to understand the relationship between electron delocalization and resonance, and to learn the principles of electron movement used in writing resonance structures in Lewis notation, known as the curved arrow formalism.

• Hybridization

  Hybridization is the idea that atomic orbitals fuse to form newly hybridized orbitals, which in turn, influences molecular geometry and bonding properties. Hybridization is also an expansion of the valence bond theory. In order to explore this idea further, we will utilize three types of hydrocarbon compounds to illustrate (sp^3), (sp^2), and (sp) hybridization.

• Hybridization II

• Hybrid Orbitals in Carbon Compounds

  Diamond crystals such as the one shown here are appreciated by almost everyone, because of their hardness, sparkle, and high value. They are also important in many technical applications. However, in terms of chemistry, diamonds consist of only carbon atoms, except for impurities. Like diamond, the chemistry of carbon is indeed very interesting and valuable.

• Overview of Valence Bond Theory

  Valence Bond (VB) Theory looks at the interaction between atoms to explain chemical bonds. It is one of the two common theories that helps describe the bonding between atoms. The other theories is the Molecular Orbital Theory. Take note that these are theories and should be treated as such; they are not always perfect.

• Resonance

  Resonance structures are used when a single Lewis structure cannot fully describe the bonding; the combination of possible resonance structures is defined as a resonance hybrid, which represents the overall delocalization of electrons within the molecule. In general, molecules with multiple resonance structures will be more stable than one with fewer and some resonance structures contribute more to the stability of the molecule than others - formal charges aid in determining this.