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Overview of Spectroscopy. Use of Physical Methods to determine structures in Organic Chemistry. Spectroscopy in Organic Chemistry…. The Chemists Eyes, Ears and Nose How do we know what we have? NMR (nuclear magnetic resonance spectroscopy) Mass Spectrometry (MS)
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Overview of Spectroscopy Use of Physical Methods to determine structures in Organic Chemistry
Spectroscopy in Organic Chemistry…. The Chemists Eyes, Ears and Nose How do we know what we have? NMR (nuclear magnetic resonance spectroscopy) Mass Spectrometry (MS) Infrared Spectroscopy (IR and other vibrational classes like Near IR, Raman)
Structural Features obtained Spectroscopically • Molecular weight • Chemical Formula • Functional groups • Skeletal Connectivity, structural isomers • Spatial-geometric arrangements, stereoisomerism, symmetry • Presence and location of chromophores • Chirality issues
NMR looks at atoms by means of nuclei connectivity pathways spatial arrangements of atoms and 1:1 correspondence between signals and atoms • Mass Spec measures molecular weight, most fundamentally useful for unknowns controllable fragmentation can distinguish among rival possibilities independent of absorption of light • IR and Raman vibrations characteristic of bonds functional group identification “fingerprint” • UV--reports on conjugation and multiple bonds.
The Electromagnetic Spectrum 1 wavelength, is a distance…. Peaks per time; frequency Light comes in different forms of EMR All have λ, ν, and Energy Amplitude Photon E= h is frequency, Hz, 1/sec = c/; c=3x1010 cm/sec h = Planck’s constant = 6.624 x10-34 J•sec /c = 1/ = wavenumber, cm-1
Spacings between atomic nuclei in crystals lower E, lower larger Microwaves X-Ray UV IR+Raman NMR higher E, higher smaller Electron orbital transitions vibrations of bonds nuclear spin flips rotational states Log , meters -15 -10 -5 0 5 100 kcal/mol 10-6 kcal/mol 10 kcal/mol Chemical Properties as related to the different colors of light
Energy Transitions Light, (Frequency Dispersion) Features in Common for all Spectroscopy Measuring Scheme Data Some Physical Property Analysis, Interpretation A key for us here is, we use instruments to Disperse energy across a scale appropriate to a chemical property Knowledge Wisdom (or Progress)
Therefore we have Precise Analytical Instruments that can Disperse Energy • Accurate, precise, reproducible • Combine the energy dispersion scheme with a detection scheme. • Generally the sample sits physically between the source and the detector. • Detector provides selectivity in response, usually generates a voltage. We record voltage responses as “DATA”
Lightsource Sample Recorder Detector The dispersion is easy to achieve with ordinary light Monochromator rotates Prism or diffraction grating Spacings on grating appropriate to wavelength Schemes use slits to admit a select region of spectrum Pretty ineffective for radio waves
Instrument Response Energy There is a peak here But not here Spectroscopy “Spreads out Vision” All the techniques we will discuss have some features in common Data will have a running variable (x-axis) that is in some sense, a “energy” scale. (not at least directly, a time axis. Therefore a snapshot in time of a molecule) The response variable (an absorption or other intensity) is related to the chemical preponderance of some feature that cause the response. The position informs us about some chemical property in the sample The peak height informs us about how much of that property is in the sample
Fourier Transform MethodsAn alternative to Energy Dispersive methods • All modern NMR and IR is done this way • Measures all frequencies at same time. More efficient at signal-gathering in a give time (better S/N) • The frequencies present are deconvoluted (or dispersed) after data is collected. • Fourier Analysis is the mathematical method for doing this. It is based on the theory that any complex periodic (repeats over time) wave can be decomposed into a linear combination of sinusoids
Instrument Response time To get the measurement, we collect a detector response as a function of time Lots of different frequencies present from the sample Their voltages “beat” against each other making interference pattern (interferogram) Interference is periodic, because the frequencies are constant w.r.t each other
An Oscillating voltage is interpreted as a Frequency The process is similar to the way a sound wave is digitized to make e.g. a music CD Key to this is sampling at exactly equal time intervals This is a Frequency Axis. Think Hz!
Interfering Sinusoids are Represented in a decaying trace Space is frequency 1 Space is beating of frequency 2 vs 1 (1 - 2) A human being could compute this FT, counting beats per time unit Key to the process is a very precisely defined time base (the x axis) that the FT algorithm uses to count
Added together 2.5 2 1.5 1 0.5 0 -0.5 -1 -1.5 1000 0 200 400 600 800 Time(ms) Interference patterns--Almost able to Transform by Hand… Time(ms) But its really the Fast Fourier Transforms and fast computers that make this practical!
Since the time-acquisition is fast and efficient it is easy to Signal-Average Adding accumulating scans from the detector into memory of computer Signals are coherent and adding the scans causes signal to grow linearly with number of scans. Noise being random and incoherent grows with √no.of scans From this, the Signal-to-Noise ratio (S/N) grows proportionally to the square root of number of scans E.g., a spectrum acquired with 100 scans will be 10x better than one with 1 scan only.
Using computerized Data systems adds an additional limitation on our resolution problem More data points are better but usually at a cost to expt efficiency See here 2 identical peaks, digitized differently Bears directly on our ability to determine the position of Imax Linewidth. Usually measured at 0.5 Imax Can be limited by the instrumentation, or be limited by nature. Nature, here exerts herself as uncertainty to to slight chemical variation, or inability to measure energy precisely. Units of linewidth are same as axis, e.g. Hz, cm-1 Resolution (ability to distinguish line from closely spaced neighboring line is related to linewidth Some Features common to all Spectra
Noise, the curse of Science • All measurements, especially those we carry out with instruments, generate Noise. • Detectors of all sorts generate electrical noise • Noise is bad. It is random and incoherent and does not possess information. We go to tremendous expense and effort to eliminate, suppress, and finesse our way past noise. • Signals are good. They give us information. • Noise limits our ability to even observe very weak signals or to quantify somewhat weak signals. The Signal-to-Noise Ratio is an important parameter is assessing our ability to interpret data. • Noise is superimposed on top of peaks
Signal-to-Noise (S/N) ratios Measure height Typical rule of thumb: Limit of detection, S/N=3 Limit of Quantitation, S/N=10 Noise(rms) is 0.707 x peak to peak S/N=6.3/2*0.707 =4.45 So this peak is reliably detectable, but not reliably quantitatable
May need more experiments or to look further in the data! Chemistry 421--Structure Determination • Interpretable Connection between Structural Features and Spectroscopic signals • We will interpret spectra to learn about structures. • The Interpretation “paradigm” consists of charting:
???????? Total Unknowns Isolated natural products Unrelated impurities, contaminants Single component, vs mixture? “Partial Unknowns” New compound? Side reaction product Wrong starting material, carry through known synthetic steps Can we track known compounds? Peaks from precursor compounds may have “descendents” A way of Thinking…… Known compounds (verify structure) All predicted signals present? Agreement with literature? Impurities present? Fingerprint?
A Strategy for Handling Unknown Structures • Complementary 1H NMR, 13C NMR, Mass Spec, UV--any features stand out? • Get the Molecuar Weight from MS • Heavy Atoms? (ratio of M to M+1, M+2) • If heavy atoms are identified, subtract from MW • Consult various molecular formula DBs (Merck, CRC etc). Write out Molecular Formula • Use the DBE (sites of unsaturation) rule • Infrared-- Functional groups present? Identify as possibly subtract from formula (retain the need to incorporate at end) • Inventory 13C NMR and classify the C,H groups present. Tabulate fragments of structure. Reconcile MS fragments. • Assemble possible structures
Molecular Weight and Molecular Formulas • Absolutely critical to Stucture determination • Centrality of Mass Spectrometry to modern Chemistry • Molecular weight must agree with the structure. Note well, that a given nominal MW generally is consistent with several possible formulas. • The “nitrogen rule”. A compound with an even-numbered molecular weight has 0, 2 or an even number of nitrogens. • Very Important: Learn the rule for sites of unsaturation (double-bond equivalents, DBE) as a predictive tool for multiple bonds and/or rings. These are based on the standard valencies for ordinary atoms.
DBE Rules • Aim to reduce a formula to CNH2N+2 • Take formula and cross off Oxygen atoms • Replace all halogen atoms with hydrogen • Cross off all Nitrogen atoms, and for each N remove one H atom. • Sulfur treat like Oxygen (? Use care if there are a lot of oxygens, possible O=S=O type groups, similar issues with Phosphorus) • Subtract your newly reduced formula (looks like CxHx, from CxH2x+2 number H (even number) • Divide this answer by 2. Result is DBE.
So some “Decision-Tree” thinking is possible The NMR branch. Integrate at higher level with other techniques Data Synthetic Product 1H NMR Could it be what I want? Quick Inventory of signals YES NO Do I need more information? Worth more spectroscopy? What do I need to find out Back to the Lab! “granularity” of questions Assess Purity Carbon Survey Proton coupling pattern Need Assignments? YES NO Correlations to protons Separations methods, Feedback to synthesis. Information Content higher Noe for stereochemistry
Tonight’s Subjects How do the spectrometers work? The NMR measurable quantities
What is NMR Spectroscopy? • Nuclear Magnetic Resonance • Radio Frequency Absorption Spectra of atomic nuclei in substances subjected to magnetic fields. • Spectral Dispersion is Sensitive to the chemical environment via “coupling” to the electrons surrounding the nuclei. • Interactions can be interpreted in terms of structure, bonding, reactivity
The Fundamental NMR equations • Spinning nuclei produce a magnetic field that is proportional to its magnetic moment . The proportionality constant is ; = hI • An active nucleus in a magnetic field B0 has an energy w.r.t. zero field of: E (= h= h) = - • B0 where is the component of the magnetic moment colinear with B0 This gives for IZ= ±1/2; E = ± 1/2 (h B0) E = h B0 and in angular units = B0
Origin of the NMR Effect • Nuclei with other than A(#protons+neutrons) and Z(#protons) both even numbers, possess net spin and associated angular momenta • Reveals itself only in magnetic field. As usual, such momenta are quantized • States have different energies, populated according to Boltzmann distribution • States are 1/2, 3/2, 5/2…for A= odd number and integer if A= even number and Z= odd number • Transitions of individual nuclei between spin states is possible (both directions) leading to an equilibrium of populations • Number of states is 2I + 1
Direction of the Applied Magnetic Field Averages out in x,y plane; small net resultant vector along the z axis Z Nucleus Moments precess about magnetic field. Quantized either with or oppossed to field The Boltzmann excess of low over high energy state is very small, 1 in 106 Z M X X Y Y Because we are forced into observing the group behavior, we have the mathematic equivalent of the simple picture on the right Pictoral View of Spin Precession of nuclear magnet--Units of Torque
Resonance--A general phenomenon for energy pumping Imagine a kid on a swing… The period (frequency of the swing is determined (g, r(length), ). Lets say the natural period is 3 seconds, or the frequency is 0.33 If the Daddy gives a push every 3 seconds, the kid will go higher and energy will be absorbed. Every 2 seconds and the motion will get stalled and “interfered” with. Every 1.5 seconds and the energy will get absorbed but not as efficiently. The Daddy will get tired. This general principal applies in NMR among other kinds of measurement, and holds whether we scan through the applied frequency or multiplex all at once
NMR-What is it Good For?(absolutely everything!) Solving structures of compounds like synthetics, impurities, natural products Identifying metabolites Stereochemical determination Follow reactions Validating electronic theory; trends within series of compds. Kinetics Extended structure, e.g. protein nmr Molecular interactions e.g. ligand binding Acid-base questions Purities Mechanisms, e.g. isotope distributions, other effects Questions about the solid state Imaging
And Besides that… • You get your sample back! • Not so for mass spec • Try recovering your compound from a KBr pellet or nujol mull
But on the other Hand… • NMR is one of the least sensitive analytical methods • Characterized by long relaxation time constants, limiting experimental efficiency in real time • Sometimes too much information. Can be demanding on interpretation skill • Relatively Expensive compared with other analytical methods • As with other methods NMR has “blind spots” and cannot serve as an analytical panacea
What Do I Hope you will Learn? • Enough theory to make you conversant in the area…. • NMR with respect to how the effects arise and can be predicted; connection with experiments and limitations of these; survey of how the instruments work. • Basis of the experiments • Data processing considerations, at level to appreciate what may have been done to give your result. • A basic toolbox of experiments, what they do and how to use them in your work • A working knowledge of organic chemical shifts and influence of symmetry on signal counting • Spin coupling, coupling networks and connectivity, use of J-coupling constants in chemistry
Why NMR? • Unmatched versatility as an Analytical technique • High on chemical information content • Significant interpretability • Interpretable at several levels of sophistication • Response related to molar preponderance • These attributes are true for solids, liquids, mixtures, and to a small extent, gas phase • More than half the periodic table has at least one NMR active isotope
What are the Measurables in NMR? • Intensity (analytical parameter, proportional to molarity) • Chemical Shift (the electronic surroundings) • Couplings (scalar J and dipolar D; bond paths, angles connectivity and distances) • Relaxation parameters (motions, distances)
How do we Generate, and Record NMR Spectra? • Pulser • Frequency generation • Power Amplifier • Oscillator Host Workstation transmitter Acquisition computer RF pulse Timing control signals signal Probe in Magnet NMR Acquisition commands Phase locked loop Network • User interface • Expt. Setup, control • Data processing, plotting receiver PreAmp signal • Superheterodyne (beat-down to AF) • Phase sensitive detection • A/D convertor Data file storage FID with 90deg phase shift Free Induction Decay Block Diagram for Spectrometer
Radio Frequency Transmit-Receive system Finely controlled RF pulses Microsecond control Precise control of timing, e.g pulses and delays Other precisely delivered RF for decoupling, selective excitation Gradient amp and generator, shielded in probe to avoid eddy currents
Modern Superconducting NMR Magnets Older Magnets (1970s) had opposed pole faces. High voltages and currents demanded heroic temperature control. Field ran side to side through sample Note: Special superconducting alloys Niobium-Tantalum. Search goes on for higher temperature superconductors. Supercon magnets have much larger fields, better homogeneity. Field runs up the axis of the sample. New technology! Built in auxilliary magnet with reversed current acts as “active” shield, partly eliminating the projection into the room. Lines of force project several feet into the room. They concentrate at the top and bottom. Magnets can grab iron objects and accelerate them.
What’s the role of the magnet? • Bigger the field strength, the better. This is both from a sensitivity and dispersion of signals point of view. • Expressed in Hz, permits easiser math and trig as needed. Gauss would generate energies in ergs. Remember the energy difference gives the population excess. Roughly H7/4 increase energy E= h H0Iz Field strength, H0
The NMR Probe Matching to Tx network Sample goes inside here Coil Tuned Circuit Usually there is a double tuned response for Deuterium lock A second coil provides a decoupling, gradient or other RF
3 2 2 N I ( I 1 ) h g + H H = = c 0 0 0 IkT N=#spins The Rider site, referenced below gives receptivity vs. 13C with clickable entries. These reflect natural abundance, , etc. How Sensitive is NMR? http://arrhenius.rider.edu/nmr/NMR_tutor/periodic_table/nmr_pt_frameset.html Another good site is http://nmr.magnet.fsu.edu/resources/nuclei/table.htm
k is Boltzmann constant 1.38x10-23J/molecule•K Because the E is so small, the excess (which is what we detect) is miniscule , are the short names for the upper, lower spin quantum states of a spin=1/2 nucleus The answer to that question is… Not all that Sensitive! At any given time Mass spec is at least a 104 times more sensitive Compare with UV, IR at least 102x sensitive This is tied to the fact that NMR detects only the tiny Boltzmann excess. Any old molecule can fragment in MS or absorb a IR photon. Lots of research in NMR aimed at the sensitivity problem
Most Important Nuclei in NMR • 1H, (also 2H, 3H) • 13C • 31P • 15N especially when labeled into proteins • 19F • 29Si • Some isotopes of Sn, Cd. Pb, Ag, Pt No coincidence that these are the I=1/2 nuclei. Spin numbers higher possess nuclear quadrupole moment as well. This couples to, broadens and complicates the nuclear spin angular momentum. For the most part these are niche nuclei. Exception is 11B
Quadrupolar Nuclei • Spin ≤ 1 • Electric field at nucleus non-symmetrical • Effective relaxation mechanism, promotes loss of NMR fine structure • “decouple” from attached spins. Can even wipe out attached spin 1/2 signals. • Lines are broad, very challenging NMR • 35Cl, 11B, 17O, 14N, 7Li, etc. • Some redeem themselves, deuterium, 6Li
