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ARL QUANTRIS Top performance CCD based metals analyzer

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ARL QUANTRIS Top performance CCD based metals analyzer ILAP Meeting P. Dalager / E. Muller Outline Introduction Market requirements What is the ARL QUANTRIS? – PowerPoint PPT presentation

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Title: ARL QUANTRIS Top performance CCD based metals analyzer


1
ARL QUANTRISTop performance CCD based metals
analyzer
  • ILAP Meeting
  • P. Dalager / E. Muller

2
Outline
  • Introduction
  • Market requirements
  • What is the ARL QUANTRIS?
  • Instrument description
  • Software
  • Analytical performance
  • Customer benefits
  • Conclusions

3
Introduction
  • CCD based instruments appeared nearly a decade
    ago
  • New technology permitted lower cost, smaller
    bench-top instruments and flexibility
  • Potential to analyse all elements without any
    optical compromise
  • As long as wavelengths required covered and
    resolution good enough
  • Compromises were needed to integrate technology,
    resulted in
  • Smaller spectrometers with limited resolution
  • Key elements not measurable (N)
  • High detection limits, making analysis of minor
    elements not possible at levels required by
    specifications and norms (C, P)
  • RSD of minor elements (5-10 ) too limited to
    comply with norms
  • RSD of major elements (lt 2 ) too limited to
    optimize usage of alloying elements and save
    production costs
  • Stability frequently too limited to provide
    accurate results day by day

4
Introduction
  • Thermo (formerly ARL, then Thermo ARL)
  • Decades of experience in providing OE
    spectrometers
  • Instruments with superior analytical performance,
    stability, reliability and lifetime
  • ARL METALS ANALYZER, ARL 3460, ARL 4460
  • Thermo has experience with first generation of OE
    solid state detectors based instruments
  • ONESPARK (CID)
  • ARL EASYTEST and ARL ASSURE (CCD)
  • Thermo took challenge to
  • break most compromises
  • overcome limits experienced
  • really achieve performance of traditional PMT
    based instruments

5
Market requirements
  • Solid state detector based OES with analytical
    figures of merit comparable to PMT instruments
  • Analyze CNOPS elements in steel and P in Al
  • High reliability, stability and availability
  • Flexible instruments with no hardware
    modifications required for calibration extensions
    at customer sites
  • Unlimited lines selection for multi-base
    applications
  • Black-box operation with easy-to-use instrument
    and software

6
What is the ARL QUANTRIS ?
  • Second generation OE-CCD spectrometer
  • Based on up to three spectrographs and solid
    state detectors
  • Utilizes high end linear CCDs
  • Utilizes high end CCS source
  • First CCD based instrument
  • with analytical performance equivalent to
    traditional PMT based instruments
  • able to analyse elements C, N, P, S accurately
    even at lowest concentrations

7
Outline
  • Introduction
  • Market requirements
  • What is the ARL QUANTRIS?
  • Instrument description
  • Choice of technical solutions
  • Spectrometer optics
  • Solid state imagers
  • Excitation source
  • Instrument stability
  • Hardware description
  • Analytical development
  • Software
  • Analytical performance
  • Customer benefits
  • Conclusions

8
Choice of technical solutionSpectrometer optics
  • Three alternatives investigated
  • Paschen-Runge with chained linear solid state
    detectors along Rowland circle
  • Echelle with 2D solid-state detectors
  • Flat-field with linear solid-state detectors

9
Instrument descriptionOptics Flat field
Primary slit
Grating
Detector
10
Instrument descriptionOptics Flat field
  • Advantages
  • Simple configuration
  • Simple detection system
  • Simple mapping procedure (calibration, drift
    correction)
  • ? Simplicity of configuration facilitates
    manufacturing of stable and reliable instruments
  • Numerous manufacturers of linear detectors
  • Difficulties
  • Fields not flat over long distances
  • Linear CCDs not arbitrary long
  • ? Compromise spectral range/ resolution
  • ? Narrow slits for good resolution
  • ? Reduced light flux
  • ? Limited dynamic range
  • High light flux for good dynamic range
  • ? Broader slits needed
  • ? Lower resolution
  • Works only in 1. order of diffraction
  • ? Resolution limited for some critical wavelengths

11
Choice of technical solutionOptics ARL QUANTRIS
  • Up to three flat field spectrographs
  • Separation of spectral range to be analyzed
    within 3 modules
  • 129-200 nm (N, C, P, S)
  • 200-410 nm
  • 410-780 nm (Na, Li, K )
  • Optimized light collection in each module through
    specific lenses and gratings
  • Direct reading for all 3 modules to avoid fibre
    optics
  • No aging of fibres and no replacement necessary

12
Choice of technical solutionSolid state imagers
  • Multi-parameter evaluation of CMOS and CCD
    techniques
  • CMOS
  • Technology of choice for high-volume,
    space-constrained applications where image
    quality requirements low
  • Security cameras
  • PC videoconferencing
  • Automotive in-vehicle uses ...
  • CCD
  • Most suitable technology for high-end imaging
    applications
  • Digital photography
  • High-performance industrial imaging
  • Most scientific and medical applications

13
Choice of technical solution Detector ARL
QUANTRIS
  • CCD
  • Specifically designed for high end industrial,
    scientific or military applications
  • Color RGB CCDs used in monochromatic mode
  • Increases signal/noise ratio
  • Open new possibilities for increased dynamic
    range
  • Lumogen coating for CCDs used in VUV
    spectrograph to improve quantum efficiency
  • Reduced quantum efficiency at lower wavelengths
  • Coatings mandatory to increase quantum efficiency
    below 200 nm

14
Choice of technical solution Source ARL QUANTRIS
  • Two types of sources utilized on PMT instruments
  • HIREP on ARL METALS ANALYZER and ARL 3460
  • Current follows natural decay imposed by RLC
    circuit
  • 8 different excitation conditions available
  • Patented Current Controlled Source (CCS) on ARL
    4460
  • The only servo-controlled digital source on
    market
  • Solid state electronics
  • High degree of flexibility in selection of peak
    current, frequency and current waveforms
  • Enables optimization of all figures of merit for
    each metal
  • Achieves best accuracy, sensitivity and
    reproducibility
  • Compact design close to spark stand in a Faraday
    cage
  • Suppresses RF leakage and improves general
    stability

15
Choice of technical solution Source Our solution
  • ARL QUANTRIS optics with limited resolution in
    comparison to Paschen-Runge optics with 1 m focal
    length
  • CCS source best tool to compensate limitations
    and achieve best results
  • ? CCS source selected

16
Choice of technical solution Stability
  • Long-term stability of utmost importance in harsh
    environments to ensure quality analytical data
  • Key influence on precision, accuracy and speed of
    analysis
  • Time spent in drift correction is time lost
  • Drift corrections are expensive
  • Frequent drift correction can contribute to
    errors
  • Metals production depends on stable analytical
    instruments to ensure the process is under
    control
  • First generation of CCD based instruments dont
    have best stability reputation
  • Exception being ARL ASSURE thanks to flat field
    architecture
  • Thermo established reputation with stable
    instruments
  • Company knowledge exploited to provide stable
    instruments

17
Choice of technical solution Stability
  • Easier to achieve stability with simple flat
    field architecture
  • Well proven cast iron spectrometer
  • Provides unrivaled stability both on short and
    long term
  • Spectrometer running under vacuum
  • Provides rigidity
  • Independant from atmospheric pressure variations
  • Thermo-controlled CCDs to 0.5C at 0.5-2C
  • Achieves low noise in addition to stability
  • Water-cooled stand
  • Automatic optical alignment and spectrum
    profiling on each CCD

18
Hardware descriptionStand
  • Stand main features
  • With 3 optical channels
  • Argon flow optimized by computer simulation
  • Casted analysis table for light passes, argon
    admission and exhaust optimization
  • Quick analysis table exchange
  • Indirect water cooling table
  • Very low stand-by flow
  • Fast flush and dust blow out system
  • Use of short pulsed argon jets
  • Allow to reduce argon flush time even with
    Nitrogen analysis
  • Keep the spark chamber free of extra dust over
    extended time
  • Consequently reduces maintenance frequency and
    down time

19
Hardware descriptionOptical system main features
  • Spectrometer in cast iron, under dry vacuum
  • 3 spectrographs with flat field diffraction
    system
  • Focal length 200 mm
  • Primary slit width 15 µm
  • Holographic aberration corrected concave gratings
  • VUV spectrograph 3240 gr/mm (at grating center)
  • Basic spectrograph 1105 gr/mm (at grating
    center)
  • Optional alkaline spectrograph 590 gr/mm (at
    grating center)
  • Average dispersion
  • VUV spectrograph 1.2 nm/mm
  • Basic spectrograph 3.5 nm/mm
  • Optional alkaline spectrograph 6.7 nm/mm
  • Average bandpass per pixel
  • VUV spectrograph 8 pm/pixel
  • Basic spectrograph 24 pm/pixel
  • Optional alkaline spectrograph 43 pm/pixel

20
Hardware descriptionOptical system
  • Spectrometer views

21
Analytical developmentAnalytical conditions (2)
  • Fe base
  • Standard timings and source parameters
  • CCD and acquisition parameters
  • Adjusted to obtain max. intensity on IS lines
    (needs number of integrations to be adapted)
  • Analysis time
  • Fe base 31s (computation time added)
  • Al base 29 s (computation time added)

22
Analytical developmentPreliminary Manipulation
of Spectral Data
  • After summation of intensities of elementary
    integration times
  • 3 spectra obtained for each CCD line (RGB)
  • Added to obtain 1 spectrum for each CCD with up
    to ? 3 x better S/N
  • Pixel intensities of all CCDs used for
    computations (next slides)
  • Pixel intensities of all CCDs also stored in a
    file allowing graphical display of the spectra
  • With header with various information
  • With polynomial coefficients and pixel
    intensities for each CCD
  • Coefficients make spectra in nm from different
    instruments comparable

23
Analytical developmentNumerical Processing -
Generalities
  • Weaker performance of CCDs vs. PMTs
  • Sensitivity typically 2-3 orders of magnitude
    lower
  • Lower precision
  • Numerical processing offers unique
    differentiators to the ARL QUANTRIS
  • Because spectrum available and almost no
    limitation on line selection
  • Drawbacks partly compensated by "massaging"
    spectra with
  • Drift correction at each acquisition
  • Processing windows with full flexibility
  • Various filtering modes
  • Various  intensity modes 
  • Various background subtraction modes
  • Use of best internal standard for each analyte
    line
  • Deconvolution
  • Enormous potential, at every level !

24
Analytical developmentNumerical Processing For
drift correction
  • Drift correction
  • Drifts unavoidable !
  • For each CCD, at each acquisition
  • Well defined and resolved lines compared to a
    "mask"
  • Set of reference lines
  • Drift correction algorithm "moves and deforms"
    spectrum in order to find the smallest difference
    with reference lines
  • Special algorithms to find accurate maxima
    positions of measured lines
  • Parameters similar to a and b for
    restandardization

25
Analytical developmentNumerical Processing
Processing window
  • Chosen to eliminate interferences as much as
    possible
  • Chosen to solve desperate situations
  • Can be shrunk to a line ? amplitude measurement

26
Analytical developmentNumerical Processing
Filtering
  • Smoothing filters matched to line characteristics
  • Improve pixel reproducibility
  • Reduce noise
  • Improve reproducibility of integration

Raw run 1
Low-pass Filter
Raw run 2
27
Analytical developmentNumerical Processing
Filtering
  • Typical improvements due to smoothing filters
  • SD calculated on 10 runs performed on SUS RE12

28
Analytical developmentNumerical Processing
Background Subtraction
  • Various modes
  • Off-Peak ( Bg )
  • On-peak
  • If off-line background signal
    not available
  • Rectangular or trapezoidal
  • None
  • Quality of background on- peak not always
    sufficient
  • If good background improves sensitivity, bad
    background can degrade reproducibility

Bg
29
Outline
  • Introduction
  • Market requirements
  • What is the ARL QUANTRIS?
  • Instrument description
  • Software
  • Analytical performance
  • Customer benefits
  • Conclusions

30
SoftwareWinOE the powerful assistant
  • First Windows based version launched 1991
  • Regular releases (13) to add functions, improve
    ease-of-use, support new OS
  • Current version 3.1
  • Runs on all Thermos PMT based instruments
  • Runs on Windows 2000
  • Most powerful package on market
  • Most robust package on market
  • Simplest to use package on market

31
SoftwareNew WinOE 3.2
  • Main novelty supports ARL QUANTRIS now!
  • Line library manager
  • Libraries managed per matrix
  • Graphical tool to display the spectra acquired
    from the 3 CCD's and identity unknown peaks

32
SoftwareNew WinOE 3.2 Lines library manager
  • Lines libraries organized per base Fe, Al, Cu
  • A base lines library includes selected spectral
    lines, spectrum processing algorithms and
    information
  • Lines libraries available separately
  • Multi-base capability
  • New elements added without hardware change
  • Easy addition in analytical programs of any line
    included within the installed lines libraries
  • Lines of other bases need corresponding library

33
SoftwareNew WinOE 3.2 Qualitative analysis
  • Spectra display function, dedicated to the
    display of analysis spectra
  • On-line and off-line view
  • Spectra manipulation tools
  • Peak search function
  • Also called finger print mode
  • Permits qualitative analysis of any element in
    wavelength library gt 146000 lines
  • Perfect tool for metallurgical research
  • User friendly thanks to a modern look 'n feel
  • Evolving functionality
  • Nice tool for metallurgical research

34
Outline
  • Introduction
  • Market requirements
  • What is the ARL QUANTRIS?
  • Instrument description
  • Software
  • Analytical performance
  • Customer benefits
  • Conclusions

35
Analytical PerformanceNew detection limit
definition
  • Traditional DL calculation method
  • DL 3 s relative BEC
  • s relative relative standard deviation stored for
    the pure matrix sample with 10 runs
  • With background subtraction, too easy to
    artificially show very low DLs
  • Alternative method had to be defined
  • DL tsSensitivity
  • t Extracted from Student table for p 99.5 (3
    s) and df9? t 3.2498
  • s standard deviation in intensity measured on
    pure sample
  • Sensitivity slope of calibration curve at zero
    concentration
  • (C1- Co/(I1-Io)
  • Definition already used by some customers
  • Most accurate method
  • Gives very similar results on PMT based
    instruments with definition above

36
Analytical Performance Fe base detection limits
(3 s)
  • Key elements
  • Steel C, N, P, S, Pb, Si, Mn
  • Cast iron Pb, Mg, La, CeN
  • Garanteed values at Thermo
  • Calculation according to norms
  • Not every competitor calculated according to
    norms
  • ARL QUANTRIS in steel
  • 4 x inferior to ARL 3460
  • C better
  • 5 x better than ARL ASSURE
  • ARL QUANTRIS in cast iron
  • Equivalent to 3460

37
Analytical Performance Fe base reproducibility
example (1 s)
  • Low alloy steel
  • 10 runs per sample
  • Key elements
  • Minor C, N, P, S, Pb, Si, Mn
  • Major Co, Cr, Ni, Mn, Mo, W
  • ARL QUANTRIS
  • 15 lt ARL 3460
  • 4 x better than ARL ASSURE

38
Analytical Performance Fe base reproducibility
example (1 s)
  • Cast iron
  • Sample CKD 248
  • 10 runs per sample
  • Key elements
  • Minor Pb, Mg, La, Ce
  • Major C, Cr, Ni, Mo
  • ARL QUANTRIS
  • 50 better than ARL 3460
  • 7 x better than ARL ASSURE
  • RSD major elements
  • C, Ni gt ARL 3460
  • Cr, Mo lt ARL 3460
  • RSD trace elements
  • Pb ARL 3460

39
Analytical Performance Fe base reproducibility
  • Excellent element
  • More limited element

40
Analytical Performance Fe base accuracy
  • Calibration curves examples
  • Excellent linearity
  • Reduced absorption effects
  • Excellent Standard Errors of Estimate (SEE)

C in cast iron
Cr in cast iron
41
Analytical Performance Fe base accuracy (SEE)
  • Cr-Ni calibration
  • Same ranges and samples on both instruments
  • Key elements
  • Minor C, N, P, Pb, S
  • Major Co, Cr, Ni, Mn, Mo, W
  • Residual errors, QUANTRIS
  • Better on key elements
  • Cr, Mn

42
Analytical Performance Fe base stability
  • Stability of utmost importance when performing
    routine analyses
  • With vacuum spectrometer, automatic optical
    alignment and spectrum profiling, demonstrates
    exceptional stability
  • Reduces need for drift correction and allows more
    time for production sample analyses
  • Examples show long-term stability of elements N
    in a low alloy steel and Mg in a cast iron over 7
    days without any intermediate drift correction
  • Standard deviation achieved remains in range of
    2x precision

43
Analytical Performance Al base detection limits
(3 s)
  • Typical values yet
  • Application still in development
  • Guaranteed values to be slightly higher
  • Key elements
  • As, Ca, Cd, Li, Na, P, Pb, Sb, Sn
  • ARL QUANTRIS in Al
  • 10 x inferior to ARL 3460

44
Analytical Performance Al base reproducibility
example (1 s)
  • Al-Si-Cu sample
  • 10 runs per sample
  • ARL QUANTRIS
  • Clearly better on major elements
  • Sometimes inferior on minor elements

45
Analytical Performance Al base reproducibility
example (1 s)
  • Majors (gt 500 ppm) in SUS vs. datasheet ARL 3460

46
Outline
  • Introduction
  • Market requirements
  • What is the ARL QUANTRIS?
  • Instrument description
  • Software
  • Analytical performance
  • Customer benefits
  • Conclusions

47
Customer benefitsStability
  • Feature
  • Instrument virtually drift free
  • Simple flat field architecture
  • Well proven cast iron spectrometer running under
    vacuum
  • Thermo-controlled CCDs to 0.5 C at 5C
  • Water-cooled stand
  • Automatic optical alignment and spectrum
    profiling on each spectrograph
  • Benefit
  • Instrument delivers dependable performance 24 x 7
    x 365
  • Minimizes drift correction procedures and keeps
    instrument available for its primary task
  • Analysis of unknown samples
  • Minimizes consumption of expensive drift
    correction samples

48
Features and benefitsReproducibility
  • Feature
  • Instrument divided in 3 spectrographs
  • Thermally controlled CCDs for low noise
  • Optimal analytical line for each matrix and even
    each quality
  • Optimal Internal Standard, optimized for each
    analytical line
  • Optimal data treatment for each line (smoothing,
    filtering, background substraction)
  • Digital source with optimum waveform for each
    matrix
  • Benefit
  • Confidence in reproducibility of results
    delivered
  • Precision of minor elements (RSD 1-5 ) enough to
    comply with specifications and norms
  • Precision of major elements (RSD 0.2-1 ) permits
    minimal usage of alloying elements and save
    production costs

49
Features and benefits Flexibility
  • Feature
  • Full spectrum available with no spectral line
    compromize
  • Wavelength coverage from 129 nm to 780 nm
  • Extension of analytical needs with no hardware
    modifications
  • In some cases spectrograph 410-780 nm could be
    requested
  • Fast change tables and electrodes for
    multi-matrix applications
  • Benefit
  • All elements requested by the metals industry can
    be analyzed
  • Easy identification of unknown elements
  • Low investment costs
  • Up-grades performed with minimal downtime
  • Easier operation in multi-matrix applications
  • Lowest operating costs

50
Outline
  • Introduction
  • Market requirements
  • What is the ARL QUANTRIS?
  • Instrument description
  • Software
  • Analytical performance
  • Customer benefits
  • Conclusions

51
Conclusions
  • Thermo not first with CCD-based OE spectrometers
  • But when we do it, we do it right !!
  • For first time CCD based spectrometer with true
    performance of PMT based instruments
  • All spectral lines for all metals types
  • Full and continuous wavelength coverage from
    129-870 nm
  • For the first time low C, N analysable with
    CCD-based instrument
  • Detection limits, reproducibility, accuracy,
    stability, reliability
  • Rugged construction to be used in hostile
    environments
  • Stability to minimize drift corrections
  • Automatic optical alignment and spectrum
    profiling

52
Conclusions
  • Perfect instrument for metals producers and
    transformers
  • Lower operating costs, flexibility for
    identification of unknown elements
  • Perfect instrument for industrial central
    laboratories, analytical services contract
    laboratories
  • Multi-matrix applications without any compromizes
  • Permits also lowest costs of ownership
  • Price difference rapidly offset by savings on
    costs of ownership
  • Easily up-gradable at lower costs
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