FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2898049818> ?p ?o ?g. }

• W2898049818 endingPage "13288" @default.
• W2898049818 startingPage "13279" @default.
• W2898049818 abstract "Microplastics (MPs, <5 mm) have been reported as emerging environmental contaminants, but reliable data are still lacking. We compared the two most promising techniques for MP analysis, namely, Raman and Fourier transform infrared (FTIR) spectroscopy, by analyzing MPs extracted from North Sea surface waters. Microplastics >500 μm were visually sorted and manually analyzed by μ-Raman and attenuated total reflection (ATR)-FTIR spectroscopy. Microplastics ≤500 μm were concentrated on gold-coated filters and analyzed by automated single-particle exploration coupled to μ-Raman (ASPEx-μ-Raman) and FTIR imaging (reflection mode). The number of identified MPs >500 μm was slightly higher for μ-Raman (+23%) than ATR-FTIR analysis. Concerning MPs ≤500 μm, ASPEx-μ-Raman quantified two-times higher MP numbers but required a four-times higher analysis time compared to FTIR imaging. Because ASPEx-μ-Raman revealed far higher MP concentrations (38-2621 particles m-3) compared to the results of previous water studies (0-559 particles m-3), the environmental concentration of MPs ≤500 μm may have been underestimated until now. This may be attributed to the exceptional increase in concentration with decreasing MP size found in this work. Our results demonstrate the need for further research to enable time-efficient routine application of ASPEx-μ-Raman for reliable MP counting down to 1 μm." @default.
• W2898049818 created "2018-10-26" @default.
• W2898049818 creator A5002693963 @default.
• W2898049818 creator A5054142461 @default.
• W2898049818 creator A5059594046 @default.
• W2898049818 creator A5070768533 @default.
• W2898049818 creator A5078547121 @default.
• W2898049818 date "2018-10-23" @default.
• W2898049818 modified "2023-10-17" @default.
• W2898049818 title "Comparison of Raman and Fourier Transform Infrared Spectroscopy for the Quantification of Microplastics in the Aquatic Environment" @default.
• W2898049818 cites W1859098346 @default.
• W2898049818 cites W1918281332 @default.
• W2898049818 cites W1936293037 @default.
• W2898049818 cites W1956592121 @default.
• W2898049818 cites W1957200237 @default.
• W2898049818 cites W1976960673 @default.
• W2898049818 cites W1981644934 @default.
• W2898049818 cites W1991395683 @default.
• W2898049818 cites W2005404508 @default.
• W2898049818 cites W2012119635 @default.
• W2898049818 cites W2014173070 @default.
• W2898049818 cites W2027494760 @default.
• W2898049818 cites W2037211189 @default.
• W2898049818 cites W2037496050 @default.
• W2898049818 cites W2038662847 @default.
• W2898049818 cites W2054699727 @default.
• W2898049818 cites W2060296270 @default.
• W2898049818 cites W2078048974 @default.
• W2898049818 cites W2080068601 @default.
• W2898049818 cites W2083347120 @default.
• W2898049818 cites W2094482107 @default.
• W2898049818 cites W2095345231 @default.
• W2898049818 cites W2103747630 @default.
• W2898049818 cites W2116464510 @default.
• W2898049818 cites W2116887560 @default.
• W2898049818 cites W2122568885 @default.
• W2898049818 cites W2133892291 @default.
• W2898049818 cites W2139256870 @default.
• W2898049818 cites W2164526292 @default.
• W2898049818 cites W2229518787 @default.
• W2898049818 cites W2294074907 @default.
• W2898049818 cites W2307709285 @default.
• W2898049818 cites W2321066044 @default.
• W2898049818 cites W2397870965 @default.
• W2898049818 cites W2428475944 @default.
• W2898049818 cites W2473511412 @default.
• W2898049818 cites W2520216211 @default.
• W2898049818 cites W2528340666 @default.
• W2898049818 cites W2546432926 @default.
• W2898049818 cites W2552024085 @default.
• W2898049818 cites W2555499857 @default.
• W2898049818 cites W2559635780 @default.
• W2898049818 cites W2565917501 @default.
• W2898049818 cites W2572128147 @default.
• W2898049818 cites W2593083124 @default.
• W2898049818 cites W2607612974 @default.
• W2898049818 cites W2609067898 @default.
• W2898049818 cites W2737217596 @default.
• W2898049818 cites W2748498801 @default.
• W2898049818 cites W2760170935 @default.
• W2898049818 cites W2765126919 @default.
• W2898049818 cites W2767378937 @default.
• W2898049818 cites W2767480030 @default.
• W2898049818 cites W2772864847 @default.
• W2898049818 cites W2795670227 @default.
• W2898049818 cites W2801680854 @default.
• W2898049818 cites W2808257176 @default.
• W2898049818 cites W2856517393 @default.
• W2898049818 cites W560717185 @default.
• W2898049818 doi "https://doi.org/10.1021/acs.est.8b03438" @default.
• W2898049818 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/30350953" @default.
• W2898049818 hasPublicationYear "2018" @default.
• W2898049818 type Work @default.
• W2898049818 sameAs 2898049818 @default.
• W2898049818 citedByCount "219" @default.
• W2898049818 countsByYear W28980498182019 @default.
• W2898049818 countsByYear W28980498182020 @default.
• W2898049818 countsByYear W28980498182021 @default.
• W2898049818 countsByYear W28980498182022 @default.
• W2898049818 countsByYear W28980498182023 @default.
• W2898049818 crossrefType "journal-article" @default.
• W2898049818 hasAuthorship W2898049818A5002693963 @default.
• W2898049818 hasAuthorship W2898049818A5054142461 @default.
• W2898049818 hasAuthorship W2898049818A5059594046 @default.
• W2898049818 hasAuthorship W2898049818A5070768533 @default.
• W2898049818 hasAuthorship W2898049818A5078547121 @default.
• W2898049818 hasConcept C102519508 @default.
• W2898049818 hasConcept C107872376 @default.
• W2898049818 hasConcept C113196181 @default.
• W2898049818 hasConcept C120665830 @default.
• W2898049818 hasConcept C121332964 @default.
• W2898049818 hasConcept C158355884 @default.
• W2898049818 hasConcept C160892712 @default.
• W2898049818 hasConcept C185592680 @default.
• W2898049818 hasConcept C192562407 @default.
• W2898049818 hasConcept C2780401329 @default.
• W2898049818 hasConcept C40003534 @default.
• W2898049818 hasConcept C49102809 @default.

• next