Investigation and optimization of particle dimensions for needle trap device as an exhaustive active sampler

Investigation and optimization of particle dimensions for needle trap device as an exhaustive active sampler

► Frontal chromatography process is experimentally validated to describe the sampling process of a needle trap device. ► The trapping efficiency and desorption efficiency of a needle trap device in regard to particle dimensions are investigated and optimized. ► Effects of particles on the extraction...

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Veröffentlicht in:Journal of Chromatography A 2012-10, Vol.1260, p.54-60
Hauptverfasser: Zhan, Weiqiang, Pawliszyn, Janusz
Format: Artikel
Sprache:eng
Schlagworte:
Adsorbents
Adsorption
Breakthrough
Chromatography
Chromatography, Gas - instrumentation
Chromatography, Gas - methods
Desorption
Devices
Extraction
Frontal chromatography
Mathematical models
Models, Theoretical
Needle trap
Needles
Organic Chemicals - chemistry
Particle dimensions
Particle Size
Permeability
Reproducibility of Results
Sampling
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Pawliszyn, Janusz
description ► Frontal chromatography process is experimentally validated to describe the sampling process of a needle trap device. ► The trapping efficiency and desorption efficiency of a needle trap device in regard to particle dimensions are investigated and optimized. ► Effects of particles on the extraction of toluene, ethylbenzene and o-xylene are presented. Various needle trap devices (NTDs) with different designs have been developed during the past decade. A theoretical model on the fundamentals of the NTD was recently proposed, which employed the theory of frontal (gas–solid) chromatography to describe the sampling process. In the current work, different types of sorbent particles with different dimensions were packed into the needle as the adsorbent. The effects of particle dimensions, which would affect the packing density and consequently affect the capacity, the extraction efficiency and desorption efficiency of the NTD were experimentally investigated and the proposed theory was validated. The results demonstrated that NTDs packed with small particles possess higher extraction capacity and efficiency but much higher resistances to flow as well. The higher resistance did not necessarily result in poor desorption efficiency. The observed relationships among those physical parameters provide valuable guidance on how to design a NTD with high performance for future applications.
doi_str_mv 10.1016/j.chroma.2012.08.089
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Various needle trap devices (NTDs) with different designs have been developed during the past decade. A theoretical model on the fundamentals of the NTD was recently proposed, which employed the theory of frontal (gas–solid) chromatography to describe the sampling process. In the current work, different types of sorbent particles with different dimensions were packed into the needle as the adsorbent. The effects of particle dimensions, which would affect the packing density and consequently affect the capacity, the extraction efficiency and desorption efficiency of the NTD were experimentally investigated and the proposed theory was validated. The results demonstrated that NTDs packed with small particles possess higher extraction capacity and efficiency but much higher resistances to flow as well. The higher resistance did not necessarily result in poor desorption efficiency. 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subjects Adsorbents
Adsorption
Breakthrough
Chromatography
Chromatography, Gas - instrumentation
Chromatography, Gas - methods
Desorption
Devices
Extraction
Frontal chromatography
Mathematical models
Models, Theoretical
Needle trap
Needles
Organic Chemicals - chemistry
Particle dimensions
Particle Size
Permeability
Reproducibility of Results
Sampling
title Investigation and optimization of particle dimensions for needle trap device as an exhaustive active sampler
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