Intracavity optogalvanic spectroscopy: Is there any evidence of a radiocarbon signal?

Persson, Anders; Salehpour, Mehran

doi:10.1016/j.nimb.2014.12.065

Cited by 9 publications

(17 citation statements)

References 13 publications

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“…Through the years, we have employed several different designs, materials and fabrication methods when making our split-ring resonator plasma sources [8][9][10][12][13][14]. For example, both microstrip and stripline waveguides have been fabricated on, e.g., silicon and Pyrex, using standard MST processes such as sputtering, electroplating, and wet and reactive ion etching.…”

Section: Devices and Systemsmentioning

confidence: 99%

“…In this paper, we present results obtained using the 12 CO 2 laser, more precisely a Merit SL laser from Access Lasers Inc. Because of the CO 2 lasers, the experiments have focused at spectroscopic studies of pure CO 2 or mixtures of CO 2 and N 2 . Moreover, the experiments have been conducted at pressures in the 10 to 1000 Pa range with ( [12]) or without ( [5][6][7]) a flow through the SSRR. In this paper, results from both configurations are presented.…”

Section: Devices and Systemsmentioning

confidence: 99%

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Optogalvanic spectroscopy with microplasma sources—current status and development towards a lab on a chip

Persson¹,

Berglund²,

Khaji³

et al. 2016

J. Micromech. Microeng.

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Söderberg, J. et al. (2016) Optogalvanic spectroscopy with microplasma sources -Current status and development towards lab on a chip. Journal of Micromechanics and MicroengineeringAccess to the published version may require subscription. N.B. When citing this work, cite the original published paper.Filen arkiveras tills dess att information om publikationen kommer in. Det är post-print och inga problem att ha i DiVA. Abstract. Miniaturized optogalvanic spectroscopy shows excellent prospects of becoming a highly sensitive method for gas analysis in micro total analysis systems. Here, a status report on the current development of microwave induced microplasma sources for optogalvanic spectroscopy is presented, together with the first comparison of the sensitivity of the method to conventional single-pass absorption spectroscopy. The studied microplasma sources are stripline split-ring resonators, with typical ring radii between 3.5 and 6 mm and operation frequencies around 2.6 GHz. A linear response (R 2 =0.9999), and a stability of more than 100 s are demonstrated when using the microplasma source as an optogalvanic detector. Additionally, saturation effects at laser powers higher than 100 mW are observed, and the temporal response of the plasma to periodic laser perturbation with repletion rates between 20 Hz and 200 Hz are studied. Finally, the potential of integrating additional functionality with the detector is discussed, with the particular focus on a pressure sensor and a miniaturized combustor to allow for studies of solid samples.

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Section: Devices and Systemsmentioning

confidence: 99%

Section: Devices and Systemsmentioning

confidence: 99%

Optogalvanic spectroscopy with microplasma sources—current status and development towards a lab on a chip

Persson¹,

Berglund²,

Khaji³

et al. 2016

J. Micromech. Microeng.

Self Cite

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show abstract

“…Most importantly, it fills a void in the aggregated literature on ICOGS [1][2][3][4][5][6] , namely the study of highly enriched 14 CO 2 samples. Hence, it is an important contribution to the field, and well worthy of publication in Analytical Chemistry.…”

Section: Uppsala Swedenmentioning

confidence: 99%

Comment on “Intracavity OptoGalvanic Spectroscopy Not Suitable for Ambient Level Radiocarbon Detection”

Persson

Salehpour

2016

Anal. Chem.

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“…His first criticism is that we should have demonstrated unequivocally that his earlier results could not be reproduced under identical conditions. We felt that this had already been accomplished in two different laboratories, at Groningen University and at Uppsala University (Persson et al 2013; Paul and Meijer 2015; Persson and Salehpour 2015), but he arbitrarily disregards their findings. For what reason should we also disregard the invalidating results from other laboratories when no evidence is produced to discredit them?…”

Section: Responsementioning

confidence: 99%

Response to “Comment on ‘Invalidation of the Intracavity Optogalvanic Method for Radiocarbon Detection’” by Daniel E Murnick

Carson

2016

Radiocarbon

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ABSTRACT. Our results, when taken alongside those of two other research groups, appear to invalidate the early positive results for intracavity optogalvanic spectroscopy (ICOGS) and its detection of radiocarbon. Daniel Murnick, whose lab published those early results, has directed a comment setting out the perceived shortcomings of our article and the reasons that the results do not constitute invalidation, as our article claims. Absent support from his own findings or published literature, his various counterclaims regarding our experimental procedure appear to constitute only his considered professional opinion and the largest confounder highlighted by our research is not even mentioned. The preponderance of documented evidence regarding ICOGS clearly supports the null hypothesis and in our opinion, nothing in Murnick's comment indicates otherwise. RESPONSEDaniel Murnick has submitted a comment in defense of his earlier publications regarding the detection of radiocarbon with intracavity optogalvanic spectroscopy (ICOGS), in which he points out perceived shortcomings in our research (Carson et al. 2016). Whereas we would expect insightful criticism from such an eminent scholar in the field, we were instead dismayed to read weak and unsubstantiated counterclaims to our findings.His first criticism is that we should have demonstrated unequivocally that his earlier results could not be reproduced under identical conditions. We felt that this had already been accomplished in two different laboratories, at Groningen University and at Uppsala University (Persson et al. 2013;Paul and Meijer 2015;Persson and Salehpour 2015), but he arbitrarily disregards their findings. For what reason should we also disregard the invalidating results from other laboratories when no evidence is produced to discredit them? Second, he claims that the theoretical basis for our findings was invalid. Our theoretical basis is an extension of the model he espoused in his own peer-reviewed publications. Compare what we present against his own model ( Murnick et al. 2008). We expanded one of his products into an integral and placed rough bounds on his own otherwise unspecified term K, which "is a corresponding optogalvanic proportionality constant that depends on the details of the electric discharge" (Murnick et al. 2008). If our model is invalid because of the reasonable caveats of Bachor et al. (1982), should this not also challenge his own published model? Third, he claims that the crucial flaw in our experiment was that we used sawtooth modulation, "[making] the intrinsically narrow band CO 2 laser effectively broadband." Rather than provide evidence drawn from a comparable CO 2 laser operated in a similar fashion, the support is claimed from an entirely different system (Genoud et al. 2015). The "lower sensitivity" found by Genoud et al. compared to Galli et al. (2013) was attributed by Munick to the line scanning, not to any of the other potential sources of discrepancy. Genoud et al. was working at~275 K at 20 mbar with a 3-mW quantum ...

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Intracavity optogalvanic spectroscopy: Is there any evidence of a radiocarbon signal?

Cited by 9 publications

References 13 publications

Optogalvanic spectroscopy with microplasma sources—current status and development towards a lab on a chip

Optogalvanic spectroscopy with microplasma sources—current status and development towards a lab on a chip

Comment on “Intracavity OptoGalvanic Spectroscopy Not Suitable for Ambient Level Radiocarbon Detection”

Response to “Comment on ‘Invalidation of the Intracavity Optogalvanic Method for Radiocarbon Detection’” by Daniel E Murnick

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