| Instrument
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What it is
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What it does
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Main use in solar-silicon refining
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Typical commercial cost
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Rough open-source cost
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Open-source feasibility
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Notes
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| ICP-OES
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Inductively Coupled Plasma Optical Emission Spectroscopy. A liquid sample is nebulized into a very hot argon plasma, and the light emitted by excited atoms is measured at characteristic wavelengths.
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Multi-element elemental analysis, typically after dissolving the silicon sample in acid.
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Measures many metallic impurities such as Fe, Al, Ca, Ti, Mn, Cu, Ni, etc. Good for routine batch tracking and process control.
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New: about $50k–$250k typical market range; used: often about $20k–$150k.
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$20k–$80k for a serious open build; $80k–$150k if aiming for robust automation and better optics.
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Medium
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Most realistic advanced spectroscopy tool to open source. Hard parts are RF plasma source stability, optics, detector calibration, acid-resistant sample handling, and software. Commercial ICP-OES systems are positioned as routine elemental analyzers for busy labs.
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| ICP-MS
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Inductively Coupled Plasma Mass Spectrometry. Similar plasma front-end to ICP-OES, but instead of measuring light, it feeds ions into a mass spectrometer.
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Ultra-trace elemental analysis in solution, often down to ppb, ppt, or lower depending on element and matrix.
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Measures very low impurity concentrations. Important when impurities are too low for comfortable ICP-OES quantification, and for difficult trace-element work.
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New: about $50k–$500k typical market range; used: about $15k–$150k. Used Agilent 7850 listings are around $90k.
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$250k–$1M+ and likely multi-year development.
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Very low
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Open-sourcing a useful ICP-MS is far beyond a normal shop build. The plasma interface, ion optics, ultra-high-vacuum mass analyzer, RF electronics, contamination control, detector chain, and software are all difficult.
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| GDMS
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Glow Discharge Mass Spectrometry. A solid conductive or semiconductive sample is sputtered directly in a glow discharge source, and the sputtered ions are analyzed by a high-resolution mass spectrometer.
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Direct solid analysis of high-purity conductive and semiconductive materials, often to ppb levels, with minimal wet chemistry.
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Extremely useful for bulk purity analysis of silicon and other high-purity solids without dissolving the sample first.
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Commonly quote-only commercial systems; practical expectation is high six figures to low seven figures new.
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$500k–$2M+ and likely a specialized team effort.
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Extremely low
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This is one of the best-fit methods for high-purity bulk solids, but one of the least realistic to open source. Thermo positions GD-MS specifically for direct analysis of high-purity conductive and semiconductive materials at ppb levels.
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| SIMS
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Secondary Ion Mass Spectrometry. A focused primary ion beam sputters the surface, and the emitted secondary ions are mass analyzed.
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Ultra-sensitive surface and depth-profile analysis of dopants and impurities; can map concentration versus depth.
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Used for very low-level dopants such as B and P, and for depth profiling near surfaces, diffusion layers, and contamination gradients.
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Commonly quote-only commercial systems; practical expectation is high six figures to several million dollars new. Used older CAMECA IMS 7F systems do appear on the used market.
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$1M–$5M+ and a major long-duration development program.
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Essentially not realistic
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Fantastic tool, but not a practical open-source first target. Primary-ion optics, vacuum system, mass analyzer, detectors, stage control, and calibration are all very hard.
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| FTIR
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Fourier Transform Infrared Spectroscopy. Measures how a sample absorbs infrared wavelengths to infer bonding and composition.
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Identifies molecular bonds and some light-element-related features; in silicon work it is commonly used for oxygen, carbon, and some bonding-state information depending on sample prep and mode.
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Screening for oxygen/carbon-related information, contamination, and some material-ID tasks. More of a support instrument than the primary impurity workhorse.
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New: about $15k–$150k typical market range; used: about $7k–$60k.
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$5k–$25k for a credible open build; $25k–$60k for better mechanics, interferometer stability, and software.
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High
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This is the most open-sourceable instrument on this list. Many subsystems are comparatively accessible: IR source, Michelson interferometer, detector, sample holder, and transform software.
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