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NUCLEAR MAGNETIC RESONANCE (NMR). WIDIASTUTI AGUSTINA ES, S.Si., M.Si. Nuclear Magnetic Resonance Spectroscopy (NMR) : Spectroscopic technique that provide information about amount and type of atomic molecule Hydrogen atoms 1 H NMR Carbon atoms 13 C NMR
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NUCLEAR MAGNETIC RESONANCE (NMR) WIDIASTUTI AGUSTINA ES, S.Si., M.Si.
Nuclear Magnetic Resonance Spectroscopy (NMR) : Spectroscopic technique that provide information about amount and type of atomic molecule • Hydrogen atoms 1H NMR • Carbon atoms 13C NMR • Phosphor atoms 31P NMR
NUCLEAR SPIN ATOM • Electron have quantum number ½ with a value of +1/2 and -1/2 - Spin Charge generates magnetic field so that electron act as a tiny magnet called a magnetic moment • This effect also valid for another atom. An atomic nucleus has an odd number and atomic number of the odd or both will have to have spin and produced magnetic moment • Nuclear Spin Rate depends on the quantum spin number , l, of nuclei
NUCLEAR SPIN NUMBER Number of spin state = 2 l +1 l = nuclear spin quantum number
SPIN STATE Nuclear atomic spin with + charge, generating a magnetic moment vector m + + m Without magnetic field, both spin state have the same energy + 1/2 - 1/2
RESONANCE In NMR spectroscopy, resonance is the energy absorption by the core-precision results in a change of spin nuclei from lower energy level to a higher energy level The precision results in a magnetic field oscillations and produce a "signal"
quantized -1/2 -1/2 DE = hn DE In a strong magnetic field, a rotating nuclei absorbs radio frequency (resonance phenomena) +1/2 +1/2 Bo Magnetic Field
LARMOR EQUATION g n = 2p Bo • =frequency of the radiation that comes, which will cause • the transition • = giromagnetic ratio • different for each atom (H, C, N) • B0= magnetic field
Magnetic Field In organic compounds, hydrogen atoms are surrounded by electrons moving in the presence of a magnetic field. The movement of electrons around the nuclei of hydrogen atoms in the magnetic field result in Diamagnetic Current The area around the atomic nucleus that is formed by electrons are called DiamagneticShielding B Induced (opposed Bo) Bo Applied
MEASUREMENT • Liquid Sample • Sample volume 0,5 mL • Solvent • 1H NMR = deuterated solvent • CDCl3, CDOH3, Acetone-d6, Benzene-d6 • Piridin-d5, DMSO-d6, D2O • 13C NMR = CHCl3, CHOH3, Acetone, Benzene • Piridin, DMSO, H2O • Sampel Amount = ≤ 50 mg
INFORMATION FROM 1H NMR 1. Chemical Shift(, ppm), expressed as ppm(per million) functional group 2. Integration number of proton 3. Multiplicity(s, d, t, q, qi, sext., hept.) proton relationship 4. Coupling Constant(J, Hz) type of proton relationship stereochemistryorposition of proton 5. Proton Signal: 0-15 ppm
integration multiplicity Coupling constante standartTMS Chemical shift ppm H group= amount & type ofproton
HYDROGEN EQUIVALENT Hydrogen Equivalent : Hydrogen that have a same chemical environtment • Compounds that have one hydrogen equivalent, producing one peak of proton NMR
- Compounds that have two/three hydrogen equivalent, producing two/three peak of proton NMR
CHEMICAL SHIFT NMR signal is not measured by resonance position, but based on how far to shift from TMS, called CHEMICAL SHIFT Has a highly protected proton and carbon (appears on upfield region)
PROTON CHEMICAL SHIFT Proton chemical shift depends on the frequency of tool used (shear difference for protons appear the same but measured in different tools) TMS shift in Hz downfield n 0 shift in Hz chemical shift = d = = ppm spectrometer frequency in MHz Any specific protons in a molecule will always appear at the same chemical shift (constant value)
PROTON CHEMICAL SHIFT Factors affecting proton chemical shift : • Electronegatifity of the neighbour atoms • Hibridisation from the adjacent atoms • Diamagnetic Effect from the adjacent phi bond
ELECTRONEGATIFITY d- d+ • Chlorine pull electron density away from carbon , caused electron density around the proton. • Chlorine caused proton to be “deshields” Cl C H d- d+ electronegative NMR CHART Deshieldingprotons,appears atlow field Shielding protons, appears at high field moredeshielding
ELECTRONEGATIFITY Chemical Shift of X on CH3X CH3X CH3F CH3OH CH3Cl CH3Br CH3I CH4 (CH3)4Si X F O ClBr I H Si Electronegativity ofX 4.0 3.5 3.1 2.8 2.5 2.1 1.8 Geseran Kimia d 4.26 3.40 3.05 2.68 2.16 0.23 0 TMS Most deshielded
ELECTRONEGATIFITY "deshielding" effect increased with increasing number of electronegative atoms most deshielded CHCl3 CH2Cl2CH3Cl 7.27 5.30 3.05 ppm “deshielding” effect decrease with increasing proton distance of electronegative atoms most deshielded -CH2-Br -CH2-CH2Br -CH2-CH2CH2Br 3.30 1.69 1.25 ppm
DIAMAGNETIC • Magnetic Induction on phi bond causes the formation of pi bonds • The presence of phi bond (double bond) or phi system will affect the chemical shift of nearby proton • Accured on alkyne, alkene and benzene ring
SPLITTING SIGNAL • On NMR spectrum, proton signals often do not appear as a single peak (singlet), but appear as doublet, triplet, quartet, and so on • Spin-spin splitting on the H atom is due to the interaction (coupling) with the neighboring H atom • Spin-spin splitting followed the (n +1) RULES, if an Atom H has n non-equivalent H atoms which are neighbors, then the NMR spectrum of H atom signal will experience a breakdown as a (n +1) peaks
(n+1) RULES n = 1, the signal will be splitted as (1+1) peaks, doublet n = 3, the signal will be splitted as (3+1) peaks, quartet
EXCEPTIONAL FOR (n+1) RULES Equivalent protons due to symmetry effects are usually not mutually spliting each other 1) no splitting if x=y no splitting if x=y Protons in the same group (tied to the same C) are usually not mutually splitting each other 2) or
EXEPTIONAL FOR (n+1) RULES N +1 rule applied to the protons in the aliphatic chain (saturated) or cyclic saturated. 3) or YES YES But it is not applied to the protons of the double bond or benzene compounds NO NO
PASCAL TRIANGLE • Splitting pattern similar with PASCAL TRIANGLE rule
SPLITTING PATTERN ( x = y ) ( x = y )
