FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2922887968> ?p ?o ?g. }

• W2922887968 endingPage "4169" @default.
• W2922887968 startingPage "4149" @default.
• W2922887968 abstract "Abstract. Over the last few decades, differential optical absorption spectroscopy (DOAS) has been used as a common technique to simultaneously measure abundances of a variety of atmospheric trace gases. Exploiting the unique differential absorption cross section of trace-gas molecules, mixing ratios can be derived by measuring the optical density along a defined light path and by applying the Beer–Lambert law. Active long-path (LP-DOAS) instruments can detect trace gases along a light path of a few hundred metres up to 20 km, with sensitivities for mixing ratios down to ppbv and pptv levels, depending on the trace-gas species. To achieve high measurement accuracy and low detection limits, it is crucial to reduce instrumental artefacts that lead to systematic structures in the residual spectra of the analysis. Spectral residual structures can be introduced by most components of a LP-DOAS measurement system, namely by the light source, in the transmission of the measurement signal between the system components or at the level of spectrometer and detector. This article focuses on recent improvements by the first application of a new type of light source and consequent changes to the optical setup to improve measurement accuracy. Most state-of-the-art LP-DOAS instruments are based on fibre optics and use xenon arc lamps or light-emitting diodes (LEDs) as light sources. Here we present the application of a laser-driven light source (LDLS), which significantly improves the measurement quality compared to conventional light sources. In addition, the lifetime of LDLS is about an order of magnitude higher than of typical Xe arc lamps. The small and very stable plasma discharge spot of the LDLS allows the application of a modified fibre configuration. This enables a better light coupling with higher light throughput, higher transmission homogeneity, and a better suppression of light from disturbing wavelength regions. Furthermore, the mode-mixing properties of the optical fibre are enhanced by an improved mechanical treatment. The combined effects lead to spectral residual structures in the range of 5-10×10-5 root mean square (rms; in units of optical density). This represents a reduction of detection limits of typical trace-gas species by a factor of 3–4 compared to previous setups. High temporal stability and reduced operational complexity of this new setup allow the operation of low-maintenance, automated LP-DOAS systems, as demonstrated here by more than 2 years of continuous observations in Antarctica." @default.
• W2922887968 created "2019-04-01" @default.
• W2922887968 creator A5033109996 @default.
• W2922887968 creator A5065614745 @default.
• W2922887968 creator A5072992688 @default.
• W2922887968 creator A5082105225 @default.
• W2922887968 creator A5082644455 @default.
• W2922887968 creator A5089241905 @default.
• W2922887968 date "2019-08-01" @default.
• W2922887968 modified "2023-10-11" @default.
• W2922887968 title "Recent improvements of long-path DOAS measurements: impact on accuracy and stability of short-term and automated long-term observations" @default.
• W2922887968 cites W1496061387 @default.
• W2922887968 cites W1788287576 @default.
• W2922887968 cites W1804720587 @default.
• W2922887968 cites W1964308154 @default.
• W2922887968 cites W1970694259 @default.
• W2922887968 cites W1974807982 @default.
• W2922887968 cites W1974958345 @default.
• W2922887968 cites W1978803485 @default.
• W2922887968 cites W1985397957 @default.
• W2922887968 cites W1992766209 @default.
• W2922887968 cites W1999344872 @default.
• W2922887968 cites W2005103219 @default.
• W2922887968 cites W2020487345 @default.
• W2922887968 cites W2030156644 @default.
• W2922887968 cites W2030250917 @default.
• W2922887968 cites W2034700342 @default.
• W2922887968 cites W2042090621 @default.
• W2922887968 cites W2044905201 @default.
• W2922887968 cites W2051768832 @default.
• W2922887968 cites W2058991258 @default.
• W2922887968 cites W2061537224 @default.
• W2922887968 cites W2062176348 @default.
• W2922887968 cites W2071085741 @default.
• W2922887968 cites W2084290143 @default.
• W2922887968 cites W2085687328 @default.
• W2922887968 cites W2088718795 @default.
• W2922887968 cites W2089663223 @default.
• W2922887968 cites W2103074073 @default.
• W2922887968 cites W2110363951 @default.
• W2922887968 cites W2113298652 @default.
• W2922887968 cites W2116122429 @default.
• W2922887968 cites W2118989888 @default.
• W2922887968 cites W2126800173 @default.
• W2922887968 cites W2140127807 @default.
• W2922887968 cites W2145857138 @default.
• W2922887968 cites W2165140155 @default.
• W2922887968 cites W2171227140 @default.
• W2922887968 cites W2319511195 @default.
• W2922887968 cites W4321518418 @default.
• W2922887968 cites W608505263 @default.
• W2922887968 doi "https://doi.org/10.5194/amt-12-4149-2019" @default.
• W2922887968 hasPublicationYear "2019" @default.
• W2922887968 type Work @default.
• W2922887968 sameAs 2922887968 @default.
• W2922887968 citedByCount "7" @default.
• W2922887968 countsByYear W29228879682020 @default.
• W2922887968 countsByYear W29228879682021 @default.
• W2922887968 countsByYear W29228879682022 @default.
• W2922887968 countsByYear W29228879682023 @default.
• W2922887968 crossrefType "journal-article" @default.
• W2922887968 hasAuthorship W2922887968A5033109996 @default.
• W2922887968 hasAuthorship W2922887968A5065614745 @default.
• W2922887968 hasAuthorship W2922887968A5072992688 @default.
• W2922887968 hasAuthorship W2922887968A5082105225 @default.
• W2922887968 hasAuthorship W2922887968A5082644455 @default.
• W2922887968 hasAuthorship W2922887968A5089241905 @default.
• W2922887968 hasBestOaLocation W29228879681 @default.
• W2922887968 hasConcept C11413529 @default.
• W2922887968 hasConcept C120665830 @default.
• W2922887968 hasConcept C121332964 @default.
• W2922887968 hasConcept C125287762 @default.
• W2922887968 hasConcept C130047971 @default.
• W2922887968 hasConcept C155512373 @default.
• W2922887968 hasConcept C176666156 @default.
• W2922887968 hasConcept C178790620 @default.
• W2922887968 hasConcept C185592680 @default.
• W2922887968 hasConcept C194072897 @default.
• W2922887968 hasConcept C202799725 @default.
• W2922887968 hasConcept C31872934 @default.
• W2922887968 hasConcept C32891209 @default.
• W2922887968 hasConcept C33390570 @default.
• W2922887968 hasConcept C41008148 @default.
• W2922887968 hasConcept C4606981 @default.
• W2922887968 hasConcept C62520636 @default.
• W2922887968 hasConcept C94915269 @default.
• W2922887968 hasConceptScore W2922887968C11413529 @default.
• W2922887968 hasConceptScore W2922887968C120665830 @default.
• W2922887968 hasConceptScore W2922887968C121332964 @default.
• W2922887968 hasConceptScore W2922887968C125287762 @default.
• W2922887968 hasConceptScore W2922887968C130047971 @default.
• W2922887968 hasConceptScore W2922887968C155512373 @default.
• W2922887968 hasConceptScore W2922887968C176666156 @default.
• W2922887968 hasConceptScore W2922887968C178790620 @default.
• W2922887968 hasConceptScore W2922887968C185592680 @default.
• W2922887968 hasConceptScore W2922887968C194072897 @default.
• W2922887968 hasConceptScore W2922887968C202799725 @default.
• W2922887968 hasConceptScore W2922887968C31872934 @default.

• next