Absorbs EM radiation from a source, like a D 2 and Tungsten lamp Electrons relax back to ground state
Choose solvent based on transparency and effects on the system Polar solvents tend to mask fine structure Non-Polar solvents tend to keep the general peak arrangements, and skew the spectra Analyzing without solvent (Neat) is always the best
All organics can absorb EM radiation Chromophores – molecules that contain such functional groups and are capable of absorbing at UV radiation Functional groups have pi orbitals that help it absorb
Absorbing results in exciting non-bonding orbitals into the pi* orbitals
Leads to a large molar absorptivity Electron donor bonds to electron acceptor Donor loses electron when excited, and acceptor takes it
Excited to singlet state Stabilizes to singlet ground state, then relaxes down to ground state Relaxation causes emission of radiation Lasts a short time
Electrons cross into a triplet state from singlet state In triplet state electron spins are unpaired, spinning in the same direction Once stabilized to the triplet ground state, electrons relax back to ground state This releases radiation, and lasts longer then fluorescence
Luminescence cause by chemical reaction Not a lot of analytes that do this Emits light when relaxing More common in a biological setting, ex. fireflies
Rigidity effects how well it absorbs, more rigidity means more fluorescence Compounds with aromatic functional groups that have low pi to pi* provide intense fluorescence
Sources Lamps Laser Monochromators Transducers Photomultiplier tubes Cells Quartz is best Silica Plastic