SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2126634858> ?p ?o ?g. }

Showing items 1 to 100 of ±133 with 100 items per page.

W2126634858 endingPage "2150" @default.
W2126634858 startingPage "2145" @default.
W2126634858 abstract "Laser ablation is widely used in conjunction with ambient ionization techniques, and a fundamental understanding of the mechanism of material removal is important to its optimal use in mass spectrometry. Finite element analysis simulates the laser material interaction on larger time and distance scales than atomistic approaches. Here, a two-dimensional finite element model was developed to simulate infrared laser irradiation of glycerol using a wavelength-tunable infrared (IR) laser.The laser fluence used for the simulations was varied from 1000 to 6000 J/m(2), the wavelength was varied from 2.7 to 3.7 µm, and both flat-top and Gaussian shape laser profiles were studied.Phase explosion conditions were found for laser wavelengths near 3 µm (which corresponds to the OH stretch absorption of glycerol) and fluences above 2000 J/m(2). This suggests that laser ablation of glycerol is driven by phase explosion in the OH stretch region. The Gaussian profile generated regions of higher glycerol temperature, whereas the flat-top profile heated a larger volume of material above the phase explosion temperature.These results suggest that the best performance for pulsed IR laser sample irradiation is in the wavelength range from 2.9 to 3.1 µm for materials with a strong OH stretch absorption." @default.
W2126634858 created "2016-06-24" @default.
W2126634858 creator A5070427740 @default.
W2126634858 creator A5078614844 @default.
W2126634858 date "2012-08-07" @default.
W2126634858 modified "2023-09-24" @default.
W2126634858 title "Finite element simulation of infrared laser ablation for mass spectrometry" @default.
W2126634858 cites W1972050584 @default.
W2126634858 cites W1972808096 @default.
W2126634858 cites W1980042208 @default.
W2126634858 cites W1981781693 @default.
W2126634858 cites W1992218508 @default.
W2126634858 cites W1996076449 @default.
W2126634858 cites W2002407800 @default.
W2126634858 cites W2007661953 @default.
W2126634858 cites W2013915244 @default.
W2126634858 cites W2016642215 @default.
W2126634858 cites W2022351152 @default.
W2126634858 cites W2022381933 @default.
W2126634858 cites W2023698910 @default.
W2126634858 cites W2028811987 @default.
W2126634858 cites W2029644425 @default.
W2126634858 cites W2039298216 @default.
W2126634858 cites W2039392102 @default.
W2126634858 cites W2044811560 @default.
W2126634858 cites W2044835288 @default.
W2126634858 cites W2058340084 @default.
W2126634858 cites W2063142894 @default.
W2126634858 cites W2064250994 @default.
W2126634858 cites W2071044837 @default.
W2126634858 cites W2071255171 @default.
W2126634858 cites W2072068912 @default.
W2126634858 cites W2075254534 @default.
W2126634858 cites W2083060948 @default.
W2126634858 cites W2089643027 @default.
W2126634858 cites W2090278903 @default.
W2126634858 cites W2094311632 @default.
W2126634858 cites W2094603341 @default.
W2126634858 cites W2096932401 @default.
W2126634858 cites W2101004170 @default.
W2126634858 cites W2101938950 @default.
W2126634858 cites W2110908445 @default.
W2126634858 cites W2119353874 @default.
W2126634858 cites W2132790269 @default.
W2126634858 cites W2136289152 @default.
W2126634858 cites W2136757321 @default.
W2126634858 cites W2137302938 @default.
W2126634858 cites W2142058429 @default.
W2126634858 cites W2145053517 @default.
W2126634858 cites W2146685301 @default.
W2126634858 cites W2166371669 @default.
W2126634858 doi "https://doi.org/10.1002/rcm.6331" @default.
W2126634858 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/22886810" @default.
W2126634858 hasPublicationYear "2012" @default.
W2126634858 type Work @default.
W2126634858 sameAs 2126634858 @default.
W2126634858 citedByCount "4" @default.
W2126634858 countsByYear W21266348582013 @default.
W2126634858 countsByYear W21266348582014 @default.
W2126634858 countsByYear W21266348582022 @default.
W2126634858 crossrefType "journal-article" @default.
W2126634858 hasAuthorship W2126634858A5070427740 @default.
W2126634858 hasAuthorship W2126634858A5078614844 @default.
W2126634858 hasConcept C111337013 @default.
W2126634858 hasConcept C113196181 @default.
W2126634858 hasConcept C120665830 @default.
W2126634858 hasConcept C121332964 @default.
W2126634858 hasConcept C125287762 @default.
W2126634858 hasConcept C127413603 @default.
W2126634858 hasConcept C133033976 @default.
W2126634858 hasConcept C145148216 @default.
W2126634858 hasConcept C146978453 @default.
W2126634858 hasConcept C158355884 @default.
W2126634858 hasConcept C162356407 @default.
W2126634858 hasConcept C178790620 @default.
W2126634858 hasConcept C185544564 @default.
W2126634858 hasConcept C185592680 @default.
W2126634858 hasConcept C192562407 @default.
W2126634858 hasConcept C198291218 @default.
W2126634858 hasConcept C22078206 @default.
W2126634858 hasConcept C2778902805 @default.
W2126634858 hasConcept C2779188808 @default.
W2126634858 hasConcept C43617362 @default.
W2126634858 hasConcept C44280652 @default.
W2126634858 hasConcept C49040817 @default.
W2126634858 hasConcept C520434653 @default.
W2126634858 hasConcept C6260449 @default.
W2126634858 hasConceptScore W2126634858C111337013 @default.
W2126634858 hasConceptScore W2126634858C113196181 @default.
W2126634858 hasConceptScore W2126634858C120665830 @default.
W2126634858 hasConceptScore W2126634858C121332964 @default.
W2126634858 hasConceptScore W2126634858C125287762 @default.
W2126634858 hasConceptScore W2126634858C127413603 @default.
W2126634858 hasConceptScore W2126634858C133033976 @default.
W2126634858 hasConceptScore W2126634858C145148216 @default.
W2126634858 hasConceptScore W2126634858C146978453 @default.
W2126634858 hasConceptScore W2126634858C158355884 @default.
W2126634858 hasConceptScore W2126634858C162356407 @default.