What is needed to construct a NIR instrument? NIR SPECTROSCOPY Instruments Umeå 2006-04-10 Bo Karlberg light source dispersive unit (monochromator) detector (Fibres) (bsorbance/reflectance-standard) The light source The light source The tungsten (W) lamp is the most common light source Relatively long life-time lamp change should not change instrument performance Light emitting diodes (LEDs) have been proposed as NIR light sources = an ideal concept! Not ready for real applications yet Some dispersive principles Filter: two types (minimum) a) Fabry-Perot interference filter b) OTF (acousto-optical tunable filters) Holografic grating The interferometer principle (FT-NIR) Discrete filter systems Reflectance s Transmission Interference Filters Single and double beam configurations Filter Wheel UV/visible, Near-Infrared, mid-infrared filters 1-44 Filters Non-contact for solids cells, single fibers, fiber bundles for liquids Fast, rugged, inexpensive 1
coustic Optical Tunable Filter (OTF) coustic wave TeO 2 crystal Wavelength selected by radio frequency Near-Infrared (1000 2000 nm) OTF Tellurium oxide, birefringent crystal coustic waves change the refractive index of the material Polychromatic light radiated onto one side of the crystal comes out as two monochromatic beams on the other side Tellurium oxide crystal Radio Frequency Oscillator Sampling with single fibers and micro-bundles dvantages: OTF no moving parts adjustable intensity narrow beams Disadvantages: difficulties when measuring highly absorbing samples limited wavelength range Monochromator NIR Digitally synchronous holographic grating system Wavelength Standards We distinguish between pre-dispersive and post-dispersive configurations PRE-DISPERSIVE Reflectance s Reference Transmission s Light source Monochromator Scan Reference Scan Wavelength Std.. Spectrum 2
We distinguish between pre-dispersive and post-dispersive configurations POST-DISPERSIVE FT-NIR Light source Monochromator FT = Fourier Transform How does it work? First, we have to distuingish between: Frequency domain spectroscopy Frequency domain spectroscopy and Time domain spectroscopy λ in nm or cm -1 λ Time domain spectroscopy Interferogram P(t) P(t) is the time domain power time 3
Interferogram No detector can register waves at the speed of light however: time domain spectra can be created through application of interferometric approaches The interferometer principle Fourier transform = the time domain spectrum is transformed to a frequency domain spectrum The Michelson interferometer Outline: CE MEKC FTIR-CE Results QCL Results Conclusion The Michelson interferometer Beam Splitter Fixed Mirror Non-dispersive system with white light illumination Mechanical or magnetic drive mechanism Single beam rapid scanning of reference and sample Moving Mirror Co-addition of spectra to improve signal-to-noise Sampling attachment SMPLE 4
The wishbone interferometer Outline: CE MEKC FTIR-CE Results QCL Results Conclusion The wishbone design Collimated Beam from a Wishbone b nchor c Flex pivot (2) d Cube corner mirrors e Beam Splitter Collimated Beam to e e d d b c a Double pendulum The crystal interferometer Linear Motor for Scanning LED Dispersion principles, summary Beam Splitter Lens Polarization Filter Quartz Lens Crystals Polarization Filter Beam Splitter Lens Lens S a m p l e NIR: filter, grating and FT instruments are equally common on the market (roughly) mid-ir: total domination of FT instruments Reference s, NIR The diode-array design Silicon detector, up to 1100 nm, stable, rapid, reliable, inexpensive Lead sulphide, 900-2600 nm, a common NIR detector, established, a little slow response InGas (indium gallium arsenide), 800-1700 nm, 1300-2200 nm, 1500-2500 nm, expensive r r a y UV/visible, Near-Infrared Silicon rray (Si) 400-1100 nm Lead Sulfide (PbS) 1100-2500 nm Indium Gallium rsenide (InGas) 800-1600 nm cells, fiber optic bundles Resolution is determined by the number of elements in the array Fixed Grating 5
Scanning NIR systems System dvantages Disadvantages Holographic Gratings Rapid Scanning High Dynamic Range Rugged (Digital) Extend Scan Ranges Moving Parts Interferometers OTF Diode rrays Rapid Scanning Large perture Fast Scanning Fast Stepping No Moving Parts Rapid Scanning Rugged Moving Parts Environmentally Sensitive (Varies) Bandpass Variation Moving Parts Spectral rtifacts Bandpass Variation RF & Temperature Sensitive Unique Components (Crystal) Limited Wavelength (Cost) Limited Dynamic Range Temperature Sensitive Pixel Variations Qualitative analysis Identification of various substances (often very pure) Classification Qualitative analysis Quantitative analysis In this case the spectral resolution is of large importance In this case the signal-to-noise ratio is of large importance λ S/N λ presentation, NIR Transmission Pair Probe types Interactance Immersion Mirror Reflectance Probe 6
Contact Probes: Transmission Contact probes: Immersion Illumination Fibers Sapphire Lens Spacer Spacers for fixed path lengths (1 to 40 mm) 316 Stainless steel or other metals Ratings: 300C at 5000 psi (350 atm) Metal to sapphire seals Collection Fibers Sapphire windows Path length = 2 x Gap Fiber bundles Gap = 1.0 to 20 mm 0 to 15% Total solids 316 Stainless steel or other metals Ratings: 300C at 5000 psi (350 atm) Metal to sapphire seals Contact probes: Reflectance Fiber optics vs. length 4 3.5 14m 16m 25m 38m 46m 78m 3 Diffuse reflectance Fiber bundles Sapphire window 316 Stainless steel or other metals Ratings: 300C at 5000 psi (350 atm) Metal to sapphire seals bsorbance 2.5 2 1.5 1 0.5 0 1100 1300 1500 1700 1900 2100 2300 Wavelength Multiplexer systems Side-stream sampling points Process analyzer Multiplexer module Fiber optics nalog/digital outputs to PLC or DCS Process PC Multiple sample points per instrument Sequential analysis Reduced cost per measurement point Transmission, Interactance & Reflectance Probes 316 Stainless Steel Construction 1 in. Swagelok Fittings for Probes 0.5 & 1.0 in. NPT for Stream 7