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High Sensitivity Diode Array Detector Robust Dad Detector Easy Operation For HPLC
| Brand Name: | Echo |
| Model Number: | Echo |
| MOQ: | 1 Set |
| Price: | Contact Us for Pricing |
| Payment Terms: | T/T |
| Supply Ability: | 50+ Sets per Month |
High Sensitivity Diode Array Detector
,Robust Dad Detector
,Robust Diode Array Detector
High-Sensitivity Diode Array Detector for HPLC Peak Purity and Identity Confirmation
Product Overview
Our diode array detector (DAD) delivers full-spectrum UV-Vis acquisition from 190 to 800 nm at 250 Hz with a 512-element photodiode array and a deuterium/tungsten dual-lamp source. This DAD enables automated peak purity analysis, library spectrum matching, and multi-wavelength quantitation in a single run, achieving baseline noise below ±3 µAU. With its fiber-optic flow cell technology, temperature-insensitive optics, and built-in holmium oxide wavelength verification, the detector is the authoritative answer for identity confirmation in pharmaceutical QC and forensic toxicology.
Cause
Absorbance detection at a single wavelength misses co-eluting impurities that differ in UV profile. When a method monitors 254 nm only, a degradation peak absorbing at 310 nm can hide under the main API peak, leading to falsely passed purity tests. Pharmacopoeias now mandate peak purity checks via DAD for all stability-indicating methods. Using a VWD when DAD is required risks a regulatory observation. Additionally, older DADs suffer from baseline drift with temperature fluctuations and lose sensitivity in the deep UV (<210 nm), where many APIs and mobile-phase additives absorb.
Solution
Our DAD uses a fiber-optic flow cell coupling: the UV light travels through a 10 mm, 1.7 µL illuminated volume cell via fiber optic guiding, with the PDA chip thermally isolated from the lamp housing. This configuration slashes baseline drift to <0.5 mAU/hour. The dual-lamp design provides high energy across the entire range—deuterium for UV, tungsten for visible. The instrument auto-calibrates wavelength accuracy against the holmium oxide filter daily. Acquired spectra (1.2 nm resolution) are compared in real-time with a user-built or commercial spectral library. The peak purity algorithm reconstructs absorbance ratio chromatograms, flagging any impurity with a sip below threshold.
Specifications
| Parameter | Specification |
|---|---|
| Wavelength Range | 190–800 nm |
| Number of Diodes | 512 |
| Spectral Resolution | 1.2 nm |
| Acquisition Rate | Up to 250 Hz |
| Baseline Noise | < ±3 µAU (254 nm, 1 s time constant) |
| Drift | < 0.5 mAU/h after warm-up |
| Flow Cell | 10 mm pathlength, 1.7 µL volume, 50 bar max |
| Light Source | Deuterium + tungsten, pre-aligned cartridge |
| Wavelength Accuracy | ±0.5 nm, auto-calibrated |
| Communication | Ethernet, analog output |
| Software Features | Peak purity, 3D maps, spectral library match |
Application
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API peak purity testing in dru g substance release
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Forced degradation study spectral profiling
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Forensic dru g identification using UV library search
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Polyphenol and flavonoid fingerprinting in botanicals
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Cleaning validation with multi-wavelength quantification
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Extractables and leachables screening
How It Works
The polychromatic light beam passes through the flow cell, where it is absorbed by eluting analytes. The transmitted light is diffracted by a holographic grating onto the 512-element array. Each diode integrates current proportional to the light intensity in its narrow wavelength band, generating a full spectrum every 4 ms. The software constructs a 3D data cube (absorbance vs. time vs. wavelength) and slices it to produce both chromatograms at user-specified wavelengths and UV spectra for any time point. The peak purity algorithm compares absorbance spectra across the peak; a perfect match gives a purity factor of 1.0.
How To Choose
Select the flow cell based on your LC system: standard 10 mm path for conventional and UHPLC, 60 mm extended path for low-concentration trace analysis. The data acquisition rate must exceed your peak width: 250 Hz can accurately model a 0.5-second UHPLC peak. Ensure the lamp envelope includes your wavelength of interest—if quantifying at 195 nm, a high-purity nitrogen purge prevents ozone build-up. We can benchmark the DAD with your current method’s challenging impurity pair to demonstrate resolution of co-eluting peaks by spectral contrast.
FAQ
Q1: How often should the lamps be replaced?
A: Deuterium lamp lifetime is typically 2,000 hours, tungsten 4,000 hours. The software tracks lamp hours and warns when intensity drops below 70% of the reference.
Q2: Can I build a custom spectral library?
A: Yes, our CDS allows you to create and store spectra with retention times and molecular weights. Libraries can be exported/imported as XML for multisite use.
Q3: How do I verify that peak purity results are valid?
A: Always check the purity angle vs. threshold plot. We recommend injecting a known co-eluting mix quarterly to confirm the algorithm sensitivity.
Q4: Is the flow cell easy to clean?
A: The fiber-optic cell can be flushed in forward or reverse direction. We supply a cleaning kit with 0.1M nitric acid and organic flush protocols.
