UV-DOAS / Differential Optical Absorption

UV-DOAS Gas Analyzers — Ultra-Violet Differential Optical Absorption Technology

Ultra-violet differential optical absorption spectroscopy (UV-DOAS) for SO₂, NO / NO₂, Cl₂, NH₃, O₃, and selected aromatic compounds — multi-wavelength fitting in the 190–400 nm range delivers simultaneous multi-gas measurement with water-vapor immunity for FGD, SCR, incineration, chlor-alkali, and ambient stack and process monitoring.

190–400nm UV Band
3Deployment Variants
8+Target Species
Multi-GasSimultaneous Fit
Technology Overview

What Is UV-DOAS Gas Analysis?

UV-DOAS exploits the fact that SO₂, NO₂, Cl₂, NH₃, O₃, and some aromatic hydrocarbons have distinctive, narrow-band vibronic absorption features in the 190–400 nm ultraviolet region that survive intact on the way through industrial stack and ambient air. By measuring the differential absorption — the high-frequency structure riding on top of a smooth broadband attenuation — and fitting it with a least-squares combination of reference cross-sections, UV-DOAS can quantify several UV-absorbing species simultaneously from a single optical path. The two defining strengths in industrial service are (a) water-vapor immunity, which removes the dryer / GFC optics burden that NDIR carries on wet stacks, and (b) genuine multi-gas simultaneous output on a single detector. Where UV-DOAS does not belong is on targets with no UV fingerprint (CO, CO₂, CH₄ — NDIR / TDLAS territory), on ppb-level NO₂ compliance duty where chemiluminescence remains the reference method, or in buyers’ shopping lists as a synonym for UV fluorescence (different physics, same spectral neighborhood).

UV-DOAS Measurement Principle

Step 1Broadband UV Light SourceA xenon short-arc lamp, deuterium lamp, or UV LED array radiates across the 190–400 nm band. Deep-UV sources (D₂ lamps, 190–250 nm) are needed for SO₂, NH₃, and NO fine-structure features; xenon arcs and UV LEDs cover the 250–400 nm band that holds NO₂, Cl₂, O₃, and aromatic absorption. Source stability and lamp aging are first-order engineering concerns for compliance-grade deployments.
Step 2Extractive or Open-Path Optical CellProcess deployments use a heated extractive cell (typically 0.5–5 m folded path) held above the sample dew point; ambient / fenceline deployments use an open-path geometry with transmitter and retroreflector separated by 10–1000 m. Because UV is not absorbed by water vapor at the wavelengths used here, the sample gas does not require drying for most targets — a major operational advantage over NDIR on wet stacks.
Step 3Spectrometer + Array DetectorTransmitted light is dispersed by a UV-grade diffraction grating and imaged onto a CCD or photodiode array covering the target 190–400 nm window at sub-nanometer resolution. The full spectrum is recorded in a single acquisition cycle (typically 100 ms to a few seconds per scan) and digitally high-pass filtered to extract the differential absorption structure while suppressing slow broadband attenuation from scattering, window contamination, and lamp drift.
Step 4Multi-Wavelength Least-Squares FitFirmware solves a linear least-squares problem that decomposes the observed differential absorption into a sum of reference cross-sections (SO₂, NO₂, NH₃, Cl₂, O₃, and matrix terms). Fit residuals are reported alongside concentrations as a data-quality indicator. The multi-wavelength fit is what separates UV-DOAS from single-line UV photometry and is why it handles overlapping absorbers (SO₂ + NO₂, NH₃ + SO₂) without the filter-wheel workarounds NDIR has to invoke.

Engineering & Deployment Notes

  • UV-DOAS is water-vapor immune at the target wavelengths, which removes the dryer / GFC optics burden that NDIR carries on wet stacks — a decisive advantage for FGD outlets and wet incineration scrubbers.
  • Source lamp aging is the dominant long-term drift: D₂ lamps age in hundreds to a few thousand hours; planned lamp-replacement schedules must be part of the project, not an afterthought.
  • UV window contamination (particulate deposition, condensate film) shows up as a slow broadband attenuation that the differential fit rejects, but only until the throughput drops below detector SNR — periodic purge and window-cleaning discipline still matter.
  • Temperature and pressure compensation on extractive UV-DOAS must be built-in for regulatory CEMS duty; open-path installations additionally need path-averaged temperature / pressure handling.
  • UV-DOAS is not a chemistry instrument — ppb NO₂ compliance duty in ambient air monitoring stations often still uses chemiluminescence (CLD) as the reference method for NO + NO₂ reporting.
Optical Variants

Deep-UV, Broadband, and Open-Path DOAS

All three share the same differential-fit method, but the source, window material, and geometry drive which target gases and deployment scenarios they fit. Most industrial CEMS platforms combine deep-UV and broadband; open-path DOAS is a separate long-baseline deployment choice.

Deep-UV DOAS (190–250 nm)

Deuterium-lamp or deep-UV LED source + solar-blind detector, tuned to the fine-structure absorption bands of SO₂ (200–230 nm), NH₃ (195–220 nm), and NO (at 226 nm).

Strengths
  • Strongest differential cross-sections for SO₂ / NH₃ / NO
  • Near-zero solar background (solar-blind region) for open-path deployments
  • Established reference method for SCR ammonia slip and wet FGD SO₂ outlet
Trade-offs
  • Deuterium lamp life 1000–2000 hours (planned replacement schedule required)
  • Sapphire / MgF₂ window materials mandatory; standard quartz is opaque at 190 nm
  • Higher lamp / optics capex than 250–400 nm variants
Typical Use

Wet-FGD SO₂ outlet, SCR NH₃ slip, nitric-acid plant stack, deep-UV ambient monitoring

Broadband UV DOAS (250–400 nm)

Xenon arc or UV LED array + array spectrometer covering 250–400 nm, tuned to NO₂ (350–450 nm), Cl₂ (260–360 nm), O₃ (250–290 nm), and aromatics (255–290 nm).

Strengths
  • Longer lamp life and lower operating cost than deep-UV
  • Broader simultaneous multi-gas window (NO₂ + Cl₂ + O₃ + aromatics on one spectrometer)
  • Standard UV-grade quartz and fused-silica components acceptable
Trade-offs
  • Solar background is significant in open-path mode and must be actively corrected
  • SO₂ and NH₃ fits degrade above 260 nm; deep-UV is preferred for those targets
  • Aromatic quantification is sensitive to mixture composition
Typical Use

Chlor-alkali Cl₂ process, post-SCR NO₂ monitoring, ozone generation QA, urban ambient

Open-Path / Long-Path DOAS

Transmitter and retroreflector (or active receiver) separated by 10–1000 m across a fenceline, plume corridor, or chemical-park perimeter; spectrum is integrated over the beam path.

Strengths
  • Long optical path drives detection down to sub-ppm, low-ppb on select targets in ambient air
  • Beam-integrated measurement gives a representative corridor average, not a point sample
  • Single beam tracks several target species simultaneously
Trade-offs
  • Weather dependence — fog, heavy rain, and snow drop throughput below detection
  • Alignment maintenance on long paths is a real operational cost
  • Not a stack-CEMS replacement — regulatory stack reporting still uses extractive or in-situ point analyzers
Typical Use

Fenceline ambient, urban air quality, emergency-response plume tracking, research-grade atmospheric studies

Gas Coverage

Where UV-DOAS Works Best

UV-DOAS is the default for SO₂ / NO₂ / Cl₂ on wet CEMS stacks and chlor-alkali process duty, a Good fit for NO / NH₃ / O₃, and a Conditional path for aromatics and elemental mercury. Each row links to the GESHINE gas category that currently covers that duty.

Gas Formula UV Absorption Band Typical Range UV-DOAS Fit Notes & Recommended Path
Sulfur Dioxide SO₂ 200–230 nm (fine-structure, deep-UV) 0–1000 ppm (CEMS) / 0–100 ppm (wet-FGD outlet) / sub-ppm (ambient long-path) Excellent

UV-DOAS is the default instrumental reference method for FGD outlet SO₂ and wet-stack CEMS; the deep-UV fine structure survives wet matrix without drying.

SO₂ / NOx Category
Nitrogen Dioxide NO₂ 350–450 nm (broadband structured) 0–500 ppm (CEMS / SCR outlet) / sub-ppm (ambient long-path) Excellent

UV-DOAS resolves NO₂ directly without the NO→NO₂ converter / ozone reactor CLD architecture demands; CLD still wins on ppb ambient NO₂ compliance work.

SO₂ / NOx Category
Nitric Oxide NO ≈ 226 nm (gamma band, deep-UV) 0–500 ppm (CEMS) / 0–50 ppm (SCR outlet) Good

NO fits are weaker than NO₂ and require deep-UV source + solar-blind detector; CEMS rigs often combine UV-DOAS NO₂ + CLD NO for a complete NOₓ report.

SO₂ / NOx Category
Chlorine Cl₂ 260–360 nm (broadband, peak ≈ 330 nm) 0–50 ppm (process / safety) / 0–1000 ppm (chlor-alkali cell gas / %vol-scale variants) Excellent

Replaces consumable electrochemical cells in continuous chlor-alkali, PVC / VCM, and water-treatment Cl₂ duty — minimal long-term drift, no humidity interference, and simultaneous interference compensation.

Chlorine Category
Ammonia NH₃ 195–220 nm (deep-UV, structured) 0–200 ppm (SCR slip / CEMS) / 0–2000 ppm (process extension) Good

Deep-UV DOAS is the extractive-CEMS default for NH₃ slip at SCR / SNCR outlets, especially when SO₂ and NO₂ are measured on the same optical platform. Sub-ppm in-situ NH₃ usually still routes to TDLAS near-IR.

Ammonia Category
Ozone O₃ 250–290 nm (Hartley band, strong) 0–200 ppm (process / generator QA) / sub-ppm (ambient) Good

UV-DOAS O₃ is deployed in ozone-generator QA, AOP water-treatment off-gas, and ambient monitoring. Many regulatory ambient O₃ stations still use dedicated UV absorption photometers rather than full DOAS.

Aromatic Hydrocarbons BTEX (Benzene / Toluene / Xylene) 255–290 nm (π→π* transitions) 0–50 ppm (fenceline) / low-ppb (long-path ambient) Conditional

Aromatic DOAS is real but mixture-composition sensitive; deployments are typically research / fenceline ambient rather than regulated stack CEMS. Speciated VOC compliance remains under voc-analyzers (PID / FID / GC-MS).

Mercury Hg⁰ 253.65 nm (atomic resonance) sub-ppb (CEMS / ambient) Conditional

Elemental Hg uses a narrow atomic line at 253.65 nm and is typically handled by Cold Vapor Atomic Fluorescence (CVAF) or dedicated UV absorption Hg CEMS — not generic multi-wavelength DOAS. Listed here for buyer disambiguation only; no in-house GESHINE self-owned Hg SKU in this release.

Technology Comparison

UV-DOAS vs TDLAS / NDIR / CLD / FTIR

Pick the technology that matches the physics, the matrix, and the regulatory framework — not the marketing buzzword. UV-DOAS wins on water-vapor immunity and multi-gas simultaneous UV absorbers; CLD remains the reference method for ppb ambient NOₓ; TDLAS / NDIR cover the IR targets.

Parameter UV-DOAS TDLAS NDIR CLD FTIR
Physics / Spectral RegionUltraviolet differential absorption 190–400 nmNear-IR 0.76–2.5 μm, single laser lineMid-IR 2–15 μm, broadband filterChemiluminescent NO + O₃ → NO₂* reaction (not spectroscopy)Full mid-IR spectrum with Fourier deconvolution
Typical Accuracy±1–2 % FS with fit-residual QA±0.5–1 % FS or ±0.1 ppm±1–2 % FS±1 % FS at ppm; ±2–5 % FS at ppb-ambient±2–5 % FS per component (mixture-dependent)
Detection LimitLow-ppm extractive; sub-ppm to low-ppb on long-path / open-path ambientSub-ppm to ppb on favorable linesppm (low-range 0.5–5 ppm clean matrix)Sub-ppb for NO / NO₂ (reference method for ambient NOₓ)ppm to sub-ppm per component
Response Time (T90)10–30 s typical<2–10 s15–60 s typical<20 s (with ozone generator warm-up)30–60 s per spectrum scan
Cross-Interference HandlingDifferential fit rejects broadband attenuation and overlapping absorbersLaser-line selection resolves neighboring speciesH₂O and overlapping IR bands are primary risksAmmonia / water / CO₂ quenching must be compensatedMixture-complex matrices require reference libraries
Multi-Gas SimultaneousYes — SO₂ / NO₂ / NH₃ / Cl₂ / O₃ in one optical headOne gas per laser; multi-gas = multi-laser opticsYes via swappable filters (3–5 channels)Effectively single-channel (NO + NO₂ with converter)Yes — up to 10–20 species per spectrum
Sample ConditioningWater-vapor immune; dryer usually not requiredHot, wet sample tolerated when laser line avoids H₂ODry sample preferred; or GFC / dual-beam correctionFull sample conditioning (dryer + converter + ozone)Heated cell + extensive sample conditioning
Relative CapexMedium to highMedium to highLow to mediumMedium (plus ozone generator consumable)High
Best ForWet-FGD SO₂, SCR NH₃ slip, chlor-alkali Cl₂, urban ambient plumeCorrosive / complex matrix low-ppm, single-gas process dutyCO / CO₂ CEMS, IAQ, combustion controlRegulatory ambient NOₓ reference method (ppb)Lab NMHC speciation, research multi-gas, troubleshooting

Choose UV-DOAS When…

  • Target is SO₂, NO₂, Cl₂, NH₃, or O₃ on a wet or mixed-acid stack
  • Multi-gas simultaneous output is needed on a single optical head
  • Sample is wet and you want to avoid the dryer / GFC optics burden NDIR demands
  • Fenceline or urban long-path / open-path geometry is part of the deployment
  • Chlor-alkali / PVC / VCM process Cl₂ where electrochemical consumables are unacceptable

Route to TDLAS / NDIR / CLD / FTIR When…

  • Target has no UV fingerprint (CO, CO₂, CH₄, refrigerants — NDIR territory)
  • ppb-trace NOₓ ambient compliance reporting (CLD reference method)
  • Single-line low-ppm HF / HCl / H₂S corrosive duty (TDLAS)
  • Lab speciation across 10+ unknown species (FTIR full-spectrum)
  • Regulated THC / NMHC continuous stack monitoring under EPA Method 25A (heated FID)
Applications

UV-DOAS in Industrial Duty

From wet-FGD SO₂ outlets and SCR ammonia slip to chlor-alkali Cl₂, multi-gas incineration stacks, and urban fenceline long-path — where UV-DOAS earns its place.

Wet-FGD SO₂ Outlet CEMS

Challenge
Coal-fired and industrial boilers with wet limestone / sulfite scrubbers discharge a saturated, wet stack gas that defeats most dry-sample architectures. Regulators still expect continuous SO₂ reporting under 40 CFR Part 60 / Part 75 and EU IED BAT; dryer-based NDIR or extractive NDIR with GFC is workable but adds conditioning complexity.
Solution
Extractive or in-situ UV-DOAS in the 200–230 nm deep-UV window measures SO₂ directly in wet gas without drying, using the differential fit to reject broadband attenuation and overlapping absorbers simultaneously. ZS-CEMS-200 pairs UV-DOAS SO₂ / NO₂ with chemiluminescence NO for a full CEMS stack.
FGD removal efficiency %

SCR / SNCR NH₃ Slip Monitoring

Challenge
Ammonia slip downstream of selective catalytic / non-catalytic reduction is a closed-loop control signal for NH₃ injection and a regulatory compliance point at many stacks. Sample-line adsorption and matrix interference (SO₂, H₂O) defeat most chemistry-based approaches.
Solution
Deep-UV DOAS at 195–220 nm resolves NH₃ on the same optical head as SO₂ / NO₂, which turns the slip measurement into a multi-gas simultaneous output. The ZS8100-NH₃ UV-DOAS ammonia analyzer is the platform for this duty.
NH₃ slip ppm at SCR outlet

Chlor-Alkali and PVC / VCM Cl₂ Process

Challenge
Cell-room header, drying section, and downstream compression rely on continuous Cl₂ measurement for yield, corrosion, and safety. Traditional electrochemical Cl₂ cells have 6–12 month consumable lifetime, humidity drift, and zero-recovery cycles that interrupt process data.
Solution
UV-DOAS in the 260–360 nm broadband window eliminates the consumable cell, delivers continuous drift-resistant readings, and handles humidity and cross-gas interference in one fit. The ZS-UVDOAS-Cl₂ analyzer covers in-line process Cl₂ duty across the chlorine analyzer family.
Cl₂ %vol (cell gas) / ppm (compression / safety)

Waste-Incineration Multi-Gas Stack

Challenge
Municipal and hazardous-waste incineration stacks carry SO₂, NO₂, NH₃ (from SNCR), HCl, and Cl₂ simultaneously. Running a separate point analyzer per species multiplies the sample-conditioning rack and the calibration burden.
Solution
UV-DOAS delivers SO₂ / NO₂ / NH₃ / Cl₂ simultaneously on one optical head; HCl stays on a dedicated TDLAS or FTIR channel because its strong UV absorption is below the DOAS operating window. The combined stack reduces rack footprint and calibration-gas manifold complexity.
Multi-gas CEMS compliance (EU IED BAT)

Urban Ambient / Fenceline Long-Path

Challenge
Industrial park fencelines, urban air-quality networks, and emergency-response plume tracking need path-integrated measurement of SO₂, NO₂, O₃, and sometimes aromatics at sub-ppm to low-ppb concentrations over corridors of 100 m to 1 km.
Solution
Open-path / long-path UV-DOAS with transmitter and retroreflector covers the full target list on one beam without per-station gas cylinders; the differential fit handles atmospheric attenuation and solar background. Regulatory stack CEMS still runs on extractive or in-situ point analyzers — long-path DOAS is a complement, not a replacement.
Path-averaged sub-ppm ambient concentration
FAQ

UV-DOAS Gas Analyzer FAQ

Common questions on when to pick UV-DOAS, how deep-UV and broadband variants differ, and how UV-DOAS relates to NDIR, CLD, FTIR, and UV fluorescence.

When should I choose UV-DOAS over NDIR?

Short answer: choose UV-DOAS when the target gas absorbs in the ultraviolet (SO₂, NO₂, Cl₂, NH₃, O₃, aromatics) and the sample is wet or multi-component. NDIR stays the default for targets with strong mid-IR fingerprints but no UV fingerprint (CO, CO₂, CH₄, refrigerants). On wet stacks, UV-DOAS avoids the dryer / GFC optics burden NDIR has to carry. For CEMS stacks with mixed acid gases and NH₃ slip, UV-DOAS typically wins on multi-gas simultaneous output from a single optical head.

Does UV-DOAS need sample drying like NDIR?

Usually no. Water vapor has negligible absorption in the 190–400 nm region at the narrow-band structure UV-DOAS uses for fitting, which is precisely why it is the default technology on wet-FGD outlets and wet incineration scrubbers. What it does need is temperature and pressure compensation (built-in), protection of the UV window from particulate / condensate deposition (purge and periodic cleaning), and planned source-lamp replacement. The water-vapor advantage is real; the engineering discipline is still real.

What is the difference between deep-UV DOAS and broadband UV-DOAS?

They are two wavelength regimes of the same method. Deep-UV DOAS (190–250 nm) uses deuterium or deep-UV LED sources, solar-blind detectors, and sapphire / MgF₂ windows, and targets SO₂, NH₃, and NO whose strongest fine-structure absorption sits in that region. Broadband UV-DOAS (250–400 nm) uses xenon arc or UV LED sources, standard UV-grade quartz, and targets NO₂, Cl₂, O₃, and aromatics that absorb above 250 nm. Most industrial CEMS platforms combine both regimes for a full multi-gas stack; ambient long-path DOAS often picks one regime to match the target mix.

How is DOAS different from FTIR?

Different spectral region and different deconvolution philosophy. UV-DOAS operates in 190–400 nm and fits a small number of well-characterized UV absorbers against narrow-band differential structure. FTIR operates across the full mid-IR and uses Fourier transform of a scanning interferogram to deconvolve broad overlapping bands for up to 10–20 species. FTIR wins on chemistry coverage and lab / research flexibility; UV-DOAS wins on targeted multi-gas CEMS simplicity, lower capex, and water-vapor immunity. They are complementary, not competitors.

Why is elemental mercury handled differently?

Elemental Hg absorbs on a single narrow atomic resonance at 253.65 nm — a line, not a molecular vibronic band. Regulatory Hg CEMS instruments use Cold Vapor Atomic Fluorescence (CVAF) or dedicated UV absorption Hg photometers optimized for that one line, not a general multi-wavelength DOAS spectrometer. Listing Hg on a UV-DOAS page is useful for buyer disambiguation, but a project that needs compliance Hg CEMS should route to a purpose-built Hg analyzer partner workflow, not to a general UV-DOAS SKU.

Is UV-DOAS the same as UV fluorescence?

No. UV absorption (DOAS) measures how much of an incident UV beam is absorbed at the target wavelengths. UV fluorescence measures the secondary re-emission from excited molecules (SO₂ fluoresces after being pumped with 214 nm photons) on a different detector geometry. Both live in the ultraviolet, but the physics, the detector arrangement, and the sample-cell engineering are all different. GESHINE’s UV-fluorescence product (the ZS6200-SO2 UVF analyzer) is on the SO₂ / NOₓ category but is explicitly not a UV-DOAS SKU and should not be cross-linked as one.

What certifications should I pin for a UV-DOAS CEMS?

In the EU, MCERTS (UK Environment Agency) and EN 15267 / EN 14181 QAL1 / QAL2 / AST are the standard type-approval framework, with EN 14791 (SO₂), EN 14792 (NOₓ), and EN 17255 (NH₃) as the reference methods. In the US, 40 CFR Part 60 Appendix B Performance Specifications (PS-2, PS-3, PS-6) and 40 CFR Part 75 cover instrumental stack monitoring. Specification should pin the target certifications explicitly rather than relying on vendor badges.

Is a generic “UV gas analyzer” the same as UV-DOAS, UV fluorescence (UVF), or a UV photometric SO₂ analyzer?

Not necessarily — “UV gas analyzer” is an ambiguous label, so route by what the instrument actually does. Generic wording like ultraviolet, UV absorption, online UV, or UV photometric multi-gas almost always points to UV-DOAS (differential optical absorption spectroscopy), which fits narrow-band UV structure for SO₂, NO₂, Cl₂, NH₃, and O₃ on one optical path. A search for “UV fluorescence” or “UV SO₂” instead means an emission-based chemistry — that is covered on the UV fluorescence (UVF) analyzer page. A “UV NOx” query usually lands best on the SO₂/NOx analyzer page, where UV-DOAS NO₂ pairs with chemiluminescence NO. When the UV label does not obviously match your target species and matrix, talk to an engineer who can map the duty to the right method.

Ready to Specify a UV-DOAS Analyzer?

Share your target species (SO₂ / NOₓ / NH₃ / Cl₂ / O₃ / aromatics), matrix composition, deployment geometry (extractive, in-situ, open-path), and regulatory framework — GESHINE application engineers will scope the right deep-UV, broadband-UV, or open-path DOAS configuration (including whether UV-DOAS is genuinely the correct choice or whether the project should route to TDLAS, NDIR, or CLD) within 48 hours.

  • Target species (SO₂ / NO / NO₂ / Cl₂ / NH₃ / O₃ / aromatics)
  • Matrix composition (moisture, particulate, acid gases)
  • Deployment geometry (extractive, in-situ, open-path)
  • Variant preference (deep-UV 190–250 nm vs broadband 250–400 nm)
  • Required range and detection limit (ppm stack vs sub-ppm ambient)
  • Regulatory framework (40 CFR Part 60 / 75, EU IED BAT, MCERTS, EN 14181)
  • Output protocols (4-20 mA / RS-485 Modbus / HART)
  • Path length / optical window / purge constraints

Get UV-DOAS Expert Consultation

Our application engineers will tell you honestly whether UV-DOAS is the right answer for your stack or fenceline — and when the project should route to TDLAS, NDIR, CLD, or heated FID instead — and then scope the right configuration.