Analytical Chemistry - Molecular and Atomic Spectroscopy
limitations to Beer's law
- applies to only monochromatic light - applies to dilute solutions < 0.01 M
photomultiplier tube (PMT)
- glass tube with no air that takes light and multiplies the intensity - cannot choose wavelength, so a monochromator is needed for each wavelength
requirements for molecular chemical analysis
- molecule has to absorb light - distinguishable wavelength for the compounds
photodiode array / diode array detector (DAD)
- pulls electrons from valence band to conductive band, leaving valence (+) and conductive (-) - when electrode is recharged, electrons and holes are recombined, creating current flow - based on which diodes are illuminated, we know wavelength
similarities / differences between single-beam and double-beam spectrophotometers
-both have light source, monochromators, sample holder, and detector - the double-beam has a beam chopper and mirrors to reference both the sample and the blank
properties of light
1) wavelength - distance between wave maxima (m) 2) frequency - # of oscillations of the field per second (Hz)
ways to reduce stray light
1. base line subtraction 2. rotating chopper 3. D2 lamp (modulated with hollow-cathode lamp) 4. Zeeman effect
temperature that a furnace atomizes molecules
2400 K
efficiency
45%-80% of light is reflected back (compares irradiance of grating to irradiance of mirror)
temperature that an ICP atomizes molecules
6000 K
Is emission or absorbance more sensitive?
Emission - uses single molecule detection - detected in the dark - uses excitation monochromator AND emission monochromator
inductively couple plasma (ICP)
Emission spectrum Identifies and measures elements through light energy emitted by excited Atoms the sample is placed in hot plasma torch - uses radio frequency voltage in coil around a glass tube - the emitted electrons collide with glass, which help maintain the high temperature
Why is a graphite furnace more sensitive and cleaner than a flame?
Graphite furnaces have argon gas running through them, which removes volatiles from the heat source. Because it takes seconds for the molecules to atomize (so the residence time in the furnace is larger), the sensitivity is increased.
grating monochromator
Gratings are optical elements with closely spaced lines, causes light of different wavelengths to diffract at different angles (is a wavelength selector)
What does higher resolution mean in terms of detection?
Higher resolution means you can detect a smaller change in wavelength (bandwidth)
how does adding NH3 to sample reduce isobaric interference?
It causes either an e- or H+ transfer, making one of the indistinguishable isotopes now neutral (which is not shown in MS because MS shows ions only)
which has better sensitivity AND resolution: PMT or DAD?
PMT, but it is slower.
double-beam spectrophotometer
Splits monochromatic light into two components One beam = sample One beam = reference solution or blank (corrects for variation in light source intensity) - works quickly
4-level lasers
The relaxation of laser action is not the ground state, making it easier to maintain population inversion
monochromator
a device (usually a grating or prism) that disperses light into its component wavelengths and selects a narrow band of wavelengths to pass through the exit slit
population inversion
a necessary condition for laser operation, in which more members of a collection of atoms are in an excited state than are in lower energy states
resolution
ability to separate two peaks closely- spaced together
chemical interference
analyte is not totally decomposed in flame (causes lower absorbance than actual)
stray light
any light outside the wavelength and bandwidth expected from the monochromator that is detected (comes from unwanted diffraction orders, environment, etc.)
Zeeman effect
apply parallel magnetic field to light path, which separates the wavelength of the light source into a higher and lower wavelength emitted, so the difference is the wavelength of the emitted electrons
type of x-ray excitation
bond-breaking ionization
type of UV-VIS excitation?
electronic excitation
triplet excited state (T)
electronic excitation AND are electrons are same spin (so both up or both down)
Rayleigh scattering
excitation light induces electron oscillation - scatters light at same v of excited state (filtered out by monochromator)
Which type of interference does each type of flame source have?
flame - chemical interference graphite furnace - chemical interference ICP emission - spectral interference ICP-MS - isobaric interference
Tungsten light
gives continues wavelengths in VIS range (near IR and UV) - is basically a regular lightbulb
globar light source
gives continuous wavelength at IR region -is a heated silicon carbide that emits radiation
D2 lamp
gives continuous wavelengths in UV range - provides electric discharge
laser
gives single wavelength and has a bandwidth of 3E-14 um - 3E-8 um
single-beam spectrophotometer
has a light source and a wavelength selector that filters the light to a specific wavelength then goes through the sample and hits a light detector with the light scatter after it passes through the sample
D2 lamp modulated with hc lamp
hc lamp gives energy to be absorbed by the sample, while the D2 lamp give energy to be absorbed by the sample and the scattering
atomization process
heat source causes samples to nebulize (so atoms are now separate) - they are separated in an inert gas, leaving the free atoms as "bare"
lean flame
higher temperature but also more oxidant (which is bad because oxidant means atoms are now molecules)
AA process
hollow-cathode lamp -> flame -> monochromator -> detector
spectrophotometers
instruments used to measure reflection or transmission properties of a material as a function of wavelength
Fourier Transform Detector
is used for IR detection - decomposes sine / cosine functions of waves to reproduce the wavenumber curve
types of light sources
lamps or lasers
fluorescence process
laser -> flame -> monochromator -> detect
parts of spectrophotometer
light source, wavelength selector, detectors
rich flame
lots of fuel and high sensitivity
spectrophotometry
method for measuring how much a compound / element absorbs light as it is irradiated
properties of lasers
monochromatic, extremely bright, collimated (light rays are parallel), polarized (electric field is oscillating in a plane perpendicular to light), coherent (light is in phase)
AE process
no light -> flame -> monochromator -> detector
in phase: constructive interference
out of phase: destructive interference
spectral interference
overlap of absorption line due to emissions from another element or compound
isobaric interference
overlapping of mass / molecule lines due to different elemental isotopes having the same mass
types of detectors
photomultiplier tube, photodiode, charge-coupled device (UV), thermocouples, ferroelectric material, photoconductive for IR
advantage of using two monochromators in series
prevents stray light by refocusing the light
detector
produces electric signal when struck by a photon(s)
type of microwave excitation
rotational excitation
rotating chopper
signal is like choppy blocks, with the higher part as the sample + background, while the lower part is the background - so the difference in signals is the signal that the sample itself gives
Ramon scattering
small fraction of excitation photons lose energy molecules which increases vibrational energy of molecules - absorbance and emission are mirror images of each other
charged-couple device
stores photogenerated charge from many diodes into 2D array (is extremely sensitive) - is what computers / phones use to hold / make pixels
spectrometry
the practical application of spectroscopy; uses instruments called spectrometers
stimulated emission
the process in which an incoming photon causes an excited atom to drop to a lower energy level, thereby emitting a photon in the same direction as the incident photon
transmittance
the ratio of the intensity of the light through the sample to the intensity of the light through the blank
spectroscopy
the theoretical approach to the science of studying the interaction between matter and radiated energy
type of infrared excitation
vibrational excitation
