#AIHCE 2011 Wrap-Up-the word from Booth 718

We heard it from an industrial hygienist

                                                                     in Portland, OR

Chlorinated hydrocarbons are a hot topic right now for first responders from fire departments and government agencies such as Homeland Security and Transportation Security Administration.We have been specializing in the measurement of chlorinated hydrocarbons since our development of the 11.7 eV long lifetime photoionization detector lamp in 1979. This lamp is available for the hand-held PIDs and for our portable gas chromatographs. Click here for more information about use of a photoionization based analyzer for the measurement of chlorinated hydrocarbons.

Web site

We brought along the first ever sold HNU PI-101 to Portland because we were showcasing it at The Chemistry of Industrial Hygiene Instrumentation Reception during the conference and we brought it to the booth thinking folks would get a kick out of it. We elicited a huge response from attendees most of whom were unaware that they could still get service from us on their old (and beloved) 101 series photoionizers.   Check out our "A New Era in Photoionization" brochure here.


Real-Time Detection Systems: our fast gas chromatograph Model 322 was extremely popular in Portland, OR. Although we introduced the Far-Ultraviolet detector in 1984, it remains underutilized. The most attractive feature of the FUV is that it is nearly universal and is more sensitive than the Thermal Conductivity Detector (TCD). Jack Driscoll and Phil Smith presented research at AIHCE for an industrial hygiene application using the fast GC Model 322 which uses resistively heated columns in the oven and a dual detection method: photoionization detector and a far-UV detector. Click here for more info on this application.

As a member of the American Industrial Hygiene Association's Real-Time Detection System Committee (AIHA RTDSC), Jack Driscoll is co-authoring a book with Phil Smith, Past Chair of the AIHA RTDSC called "Important Instrumentation and Methods for the Detection of Chemicals in the Field". Jack has contracted to contribute the last section of the book on the subject of Infrared Analyzers. He recently completed the Photoionization and Specialized Detectors sections.

Updated May 27, 2014

  AIHA Important Instrumentation Cover Page + Table of Contents by Dr. John Jack Driscoll

Far UV Absorbance Detector-The FUVAD

The Far UV Absorbance Detector

"Theory-Most organic and inorganic species absorb strongly in the far UV (FUV). Notable exceptions are the inert gases, helium and nitrogen which absorb very weakly in this region. Certain
diatomic species such as O which have low absorption in the region of the lamp energy 2 (124 nm) will have a poor response but low ppm levels can still be detected.

The far UV detector is relatively new to gas chromatography (compared to other  GC detectors) since it was introduced by HNU Systems in 1984. It is frequently compared with the thermal conductivity detector since it will respond to any compound that absorbs in the far or vacuum UV. The latter name is a misnomer since with a carrier gas flowing through the cell, a vacuum is not needed. Thus, the detector has a response that is nearly universal, a low dead volume (40 µl), and a fast electrometer time constant.
The primary emission from this lamp is the 124 mn line. Although there are visible lines from this lamp, the photodiode is unresponsive to any long wavelength UV or visible emissions and only the absorption at 124 nm needs to be considered for the absorption
process.

The minimum detection limits for organic compounds, oxygen, water, and
inorganic compounds are in the range from 0.1 to 10 ppm. A summary of the detection limits for organic and inorganic compounds is given in Table I.

Table I
Detection Limits for the FUV Detector


Compound Detection Limit (ng)
Sulfur dioxide 0.7
Methane 0.3
Oxygen 14
Water 3
Propane 1
Chloroform 5
Ethylene 1
Hydrogen sulfide 3

The HNU Far UV Detector (FUV) utilizes a simple, compact detector consisting
of a stable UV source, absorption cavity (1 cm path), and novel UV photodiode. The  detector has a universal response to all species which absorb in the 120 nm region. See Figure _ below. No response is observed for for noble gases or nitrogen. Thus, helium or nitrogen make ideal carrier gases. The
detector responds in accordance with the Lambert Beer Law:

I = Io e-kx

where I = Measured intensity

Io = Incident intensity

k = absorption coefficient

x= path length

Photons emitted from the far UV lamp (Io)are absorbed by molecules passing
through the cell causing a net decrease in photon flux to the photodiode (I). The changes in photon flux exhibits the Lambert Beers law relationship with concentration. The photodiode responds to the decrease in lamp flux and the change is amplified and
recorded.

The linearity of this detector is better than 104. The sensitivity of this detector is similar to the FID for methane and 25-100 times better than a TCD for selected compounds. In addition, the FUV detector is nondestructive and can be run in series with other detectors. Applications include trace levels of 02, H20 and inorganic gases which have been difficult to detect at sub-microgram levels previously.

Features

• Universal Response-
Responds to organic and inorganic compounds that absorb at 120 nm with detection limits 100 times lower than TCD
• Sensitivity Subnanogram
for most compounds
• Suitability for Capillary Column Analysis
Low dead volume (<50µL) allows operation with minimum make-up
• Non Destructive-Allows series operation of detectors
• Simplicity of Response
Unidirectional peaks, Beers Law Relationship  

• Adaptability-
Is readily adaptable to ANY chromatograph  

• Ease of Operation-
no additional gases needed
• Linearity->104
The detection limits for a number of compounds are given below in Table:
Applications

• Trace water in helium, nitrogen, semi conductor gases, or process streams
• Detector with nearly universal response & detection limits in the low or sub ppm levels
• Responds to all hydrocarbons with equivalent or better sensitivity for Methane (CH4) than the FID •Ideal complement to the PID"

Source of quoted text: Copyright 1998-2011 PID Analyzers, LLC 

For more information on this subject check out a chapter that Jack Driscoll wrote titled: FarUV ionization (Photoionization) and Absorbance Detectors.

Real-Time Detection Systems at #AIHCE: Fast GC Analysis for IH monitoring

 

Excellent attendance was reported for our podium session at the American Industrial Hygiene Conference and Exposition:

PO 111 Field Detection, Sampling and Analysis: Real Time Detection Systems. According to people who attended this session the room was nearly at capacity meaning approximately 200 people comprised the audience!

Tuesday | 10:30 a.m.–12:30 p.m. May 17, 2011 Portland, OR

Arranger: W. Groves, Penn State, University Park, PA. Moderator: P. Smith, Uniform Services University, Bethesda, MD. Monitors: M. Roe, 3M Company, Blaine, MN; J. Engel, USN, Camp Pendleton, CA.

10:30 a.m.

Fast GC Analysis with PID and FUV Detectors for Industrial Hygiene Monitoring at Low ppb Levels. (PO 111-1) J. Driscoll, D. Walsh, PID Analyzers, LLC, Pembroke, MA; P. Smith, US/DOL/OSHA

After the talk, numerous folks came by our booth to discuss industrial hygiene applications with Jack Driscoll for both the fast GC and the portable GC-the featured products at the HNU-PID Analyzers booth #718 at the 2011 AIHCE in Portland, OR.