TYPES OF TRANSITIONS: In U.V spectroscopy molecule undergo electronic transition involving σ, π and n electrons. Four types of electronic transition.

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Presentation transcript:

TYPES OF TRANSITIONS: In U.V spectroscopy molecule undergo electronic transition involving σ, π and n electrons. Four types of electronic transition are possible. i. σ ⇾ σ* transition ii. n ⇾ σ* transition iii. n ⇾ π* transition iv. π ⇾ π* transition

i. σ ⇾ σ* Transition : An electron in a bonding σ orbital of a molecule is excited to the corresponding anti-bonding orbital by the absorption of radiation. To induce a σ ⇾ σ* transition it required LARGE ENERGY. Ex: Methane Methane contain only single C-H bonds it undergo only σ ⇾ σ* transition only, it gives absorption maximum at 125nm.

ii. n⇾ σ* transition : In this type saturated compounds containing atoms with unshared electron pairs are undergo n ⇾ σ* transition. It require less energy than the σ ⇾ σ* type. Most of the absorption peaks appearing below 200nm. In the presence of polar solvents the absorption maximum tend to shift shorter wavelength Ex: Water , ethanol. In this the peaks in U.V region relatively small. Ex: Methlychloried , Oxygen, Nitrogen.

iii n ⇾ π* & π ⇾ π* transitions Most organic compounds are undergo transitions for n ⇾ π* and π ⇾ π* transition. Because energies required for processes bring the absorption peaks into spectral region. Both transition require the presence of an unsaturated functional group to the ´∏´ orbitals. Ex: For π ⇾ π* ⧐ Alkenes, carbonyl compounds, alkynes For n ⇾ π* ⧐ carbonyl compounds.

s* (anti-bonding) * n* Four types of transitions p* (anti-bonding) * n* n (non-bonding) p (bonding) s (bonding)