Physical Trace Gas Identification with the Photo Electron Ionization Spectrometer (PEIS)

Theodor Doll; Victor Fuenzalida; Helmut Schütte; Stefan Gaßmann; Juan J. Velasco-Velez; Robert Köhler; Alex Kontschev; Thomas Haas; Bert Ungethüm; Andreas Walte; Jonas Oberröhrmann; Adrian Onken; Kasimir M. Philipp; Minh-Hai Nguyen; Thomas Lenarz; Achim Walter Hassel; Wolfgang Viöl

doi:10.3390/s24041256

Physical Trace Gas Identification with the Photo Electron Ionization Spectrometer (PEIS)

Theodor Doll
, Victor Fuenzalida
, Helmut Schütte
, Stefan Gaßmann
, Juan J. Velasco-Velez
, Robert Köhler
, Alex Kontschev
, Thomas Haas
, Bert Ungethüm
, Andreas Walte
, Jonas Oberröhrmann
, Adrian Onken
, Kasimir M. Philipp
, Minh-Hai Nguyen
, Thomas Lenarz
, Achim Walter Hassel
, Wolfgang Viöl

Institute of Chemical Technology of Inorganic Materials

Research output: Contribution to journal › Article › peer-review

Abstract

Chemosensor technology for trace gases in the air always aims to identify these compounds and then measure their concentrations. For identification, traceable methods are sparse and relate to large appliances such as mass spectrometers. We present a new method that uses the alternative traceable measurement of the ionization energies of trace gases in a way that can be miniaturized and energetically tuned. We investigate the achievable performance. Since tunable UV sources are not available for photoionization, we take a detour via impact ionization with electrons, which we generate using the photoelectric effect and bring to sharp, defined energies on a nanoscale in the air. Electron impact ionization is thus possible at air pressures of up to 900 hPa. The sensitivity of the process reaches 1 ppm and is equivalent to that of classic PID. With sharpened energy settings, substance identification is currently possible with an accuracy of 30 meV. We can largely explain the experimental observations with the known quantum mechanical models.

Original language	English
Article number	1256
Number of pages	11
Journal	Sensors
Volume	24
Issue number	4
DOIs	https://doi.org/10.3390/s24041256
Publication status	Published - 16 Feb 2024

Fields of science

204 Chemical Process Engineering
205016 Materials testing
210006 Nanotechnology
104014 Surface chemistry
105113 Crystallography
105116 Mineralogy
204001 Inorganic chemical technology
211104 Metallurgy
104005 Electrochemistry
104006 Solid state chemistry
104017 Physical chemistry
503013 Subject didactics of natural sciences

JKU Focus areas

Sustainable Development: Responsible Technologies and Management

Access to Document

10.3390/s24041256

Cite this

Doll, T., Fuenzalida, V., Schütte, H., Gaßmann, S., Velasco-Velez, J. J., Köhler, R., Kontschev, A., Haas, T., Ungethüm, B., Walte, A., Oberröhrmann, J., Onken, A., Philipp, K. M., Nguyen, M.-H., Lenarz, T., Hassel, A. W., & Viöl, W. (2024). Physical Trace Gas Identification with the Photo Electron Ionization Spectrometer (PEIS). Sensors, 24(4), Article 1256. https://doi.org/10.3390/s24041256

@article{1b807ff9bfae47df8e8ad3ae730e53c1,

title = "Physical Trace Gas Identification with the Photo Electron Ionization Spectrometer (PEIS)",

abstract = "Chemosensor technology for trace gases in the air always aims to identify these compounds and then measure their concentrations. For identification, traceable methods are sparse and relate to large appliances such as mass spectrometers. We present a new method that uses the alternative traceable measurement of the ionization energies of trace gases in a way that can be miniaturized and energetically tuned. We investigate the achievable performance. Since tunable UV sources are not available for photoionization, we take a detour via impact ionization with electrons, which we generate using the photoelectric effect and bring to sharp, defined energies on a nanoscale in the air. Electron impact ionization is thus possible at air pressures of up to 900 hPa. The sensitivity of the process reaches 1 ppm and is equivalent to that of classic PID. With sharpened energy settings, substance identification is currently possible with an accuracy of 30 meV. We can largely explain the experimental observations with the known quantum mechanical models.",

author = "Theodor Doll and Victor Fuenzalida and Helmut Sch{\"u}tte and Stefan Ga{\ss}mann and Velasco-Velez, \{Juan J.\} and Robert K{\"o}hler and Alex Kontschev and Thomas Haas and Bert Ungeth{\"u}m and Andreas Walte and Jonas Oberr{\"o}hrmann and Adrian Onken and Philipp, \{Kasimir M.\} and Minh-Hai Nguyen and Thomas Lenarz and Hassel, \{Achim Walter\} and Wolfgang Vi{\"o}l",

year = "2024",

month = feb,

day = "16",

doi = "10.3390/s24041256",

language = "English",

volume = "24",

journal = "Sensors",

issn = "1424-8220",

publisher = "MDPI",

number = "4",

}

Doll, T, Fuenzalida, V, Schütte, H, Gaßmann, S, Velasco-Velez, JJ, Köhler, R, Kontschev, A, Haas, T, Ungethüm, B, Walte, A, Oberröhrmann, J, Onken, A, Philipp, KM, Nguyen, M-H, Lenarz, T, Hassel, AW & Viöl, W 2024, 'Physical Trace Gas Identification with the Photo Electron Ionization Spectrometer (PEIS)', Sensors, vol. 24, no. 4, 1256. https://doi.org/10.3390/s24041256

TY - JOUR

T1 - Physical Trace Gas Identification with the Photo Electron Ionization Spectrometer (PEIS)

AU - Doll, Theodor

AU - Fuenzalida, Victor

AU - Schütte, Helmut

AU - Gaßmann, Stefan

AU - Velasco-Velez, Juan J.

AU - Köhler, Robert

AU - Kontschev, Alex

AU - Haas, Thomas

AU - Ungethüm, Bert

AU - Walte, Andreas

AU - Oberröhrmann, Jonas

AU - Onken, Adrian

AU - Philipp, Kasimir M.

AU - Nguyen, Minh-Hai

AU - Lenarz, Thomas

AU - Hassel, Achim Walter

AU - Viöl, Wolfgang

PY - 2024/2/16

Y1 - 2024/2/16

N2 - Chemosensor technology for trace gases in the air always aims to identify these compounds and then measure their concentrations. For identification, traceable methods are sparse and relate to large appliances such as mass spectrometers. We present a new method that uses the alternative traceable measurement of the ionization energies of trace gases in a way that can be miniaturized and energetically tuned. We investigate the achievable performance. Since tunable UV sources are not available for photoionization, we take a detour via impact ionization with electrons, which we generate using the photoelectric effect and bring to sharp, defined energies on a nanoscale in the air. Electron impact ionization is thus possible at air pressures of up to 900 hPa. The sensitivity of the process reaches 1 ppm and is equivalent to that of classic PID. With sharpened energy settings, substance identification is currently possible with an accuracy of 30 meV. We can largely explain the experimental observations with the known quantum mechanical models.

AB - Chemosensor technology for trace gases in the air always aims to identify these compounds and then measure their concentrations. For identification, traceable methods are sparse and relate to large appliances such as mass spectrometers. We present a new method that uses the alternative traceable measurement of the ionization energies of trace gases in a way that can be miniaturized and energetically tuned. We investigate the achievable performance. Since tunable UV sources are not available for photoionization, we take a detour via impact ionization with electrons, which we generate using the photoelectric effect and bring to sharp, defined energies on a nanoscale in the air. Electron impact ionization is thus possible at air pressures of up to 900 hPa. The sensitivity of the process reaches 1 ppm and is equivalent to that of classic PID. With sharpened energy settings, substance identification is currently possible with an accuracy of 30 meV. We can largely explain the experimental observations with the known quantum mechanical models.

UR - https://www.scopus.com/pages/publications/85185556108

U2 - 10.3390/s24041256

DO - 10.3390/s24041256

M3 - Article

C2 - 38400413

SN - 1424-8220

VL - 24

JO - Sensors

JF - Sensors

IS - 4

M1 - 1256

ER -

Physical Trace Gas Identification with the Photo Electron Ionization Spectrometer (PEIS)

Abstract

Fields of science

JKU Focus areas

Access to Document

Other files and links

Cite this