Title: ARL QUANTRIS Top performance CCD based metals analyzer
1ARL QUANTRISTop performance CCD based metals
analyzer
- ILAP Meeting
- P. Dalager / E. Muller
2Outline
- Introduction
- Market requirements
- What is the ARL QUANTRIS?
- Instrument description
- Software
- Analytical performance
- Customer benefits
- Conclusions
3Introduction
- 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
4Introduction
- 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
5Market 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
6What 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
7Outline
- 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
8Choice 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
9Instrument descriptionOptics Flat field
Primary slit
Grating
Detector
10Instrument 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
11Choice 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
12Choice 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
13Choice 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
14Choice 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
15Choice 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
16Choice 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
17Choice 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
18Hardware 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
19Hardware 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
20Hardware descriptionOptical system
21Analytical 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)
22Analytical 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
23Analytical 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 !
24Analytical 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
25Analytical 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
26Analytical 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
27Analytical developmentNumerical Processing
Filtering
- Typical improvements due to smoothing filters
- SD calculated on 10 runs performed on SUS RE12
28Analytical 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
29Outline
- Introduction
- Market requirements
- What is the ARL QUANTRIS?
- Instrument description
- Software
- Analytical performance
- Customer benefits
- Conclusions
30SoftwareWinOE 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
31SoftwareNew 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
32SoftwareNew 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
33SoftwareNew 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
34Outline
- Introduction
- Market requirements
- What is the ARL QUANTRIS?
- Instrument description
- Software
- Analytical performance
- Customer benefits
- Conclusions
35Analytical 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
36Analytical 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
37Analytical 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
38Analytical 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
39Analytical Performance Fe base reproducibility
40Analytical 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
41Analytical 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
42Analytical 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
43Analytical 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
44Analytical 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
45Analytical Performance Al base reproducibility
example (1 s)
- Majors (gt 500 ppm) in SUS vs. datasheet ARL 3460
46Outline
- Introduction
- Market requirements
- What is the ARL QUANTRIS?
- Instrument description
- Software
- Analytical performance
- Customer benefits
- Conclusions
47Customer 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
48Features 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
49Features 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
50Outline
- Introduction
- Market requirements
- What is the ARL QUANTRIS?
- Instrument description
- Software
- Analytical performance
- Customer benefits
- Conclusions
51Conclusions
- 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
52Conclusions
- 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