SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3090496611> ?p ?o ?g. }

Showing items 1 to 70 of 70 with 100 items per page.

W3090496611 abstract "The evolution of micrometeorological measurements has been recently manifested by developments in methodological and analytical techniques using spatial surface brightness temperature captured by infrared cameras (Schumacher et al. 2019, Katurji and Zawar-Reza 2016). The Thermal Image Velocimetry (TIV) method can now produce accurate 2D advection-velocities using high speed (>20Hz) infrared imagery (Inagaki 2013, Schumacher 2019). However, to further develop TIV methods and achieve a novel micrometeorological measurement technique, all scales of motion within the boundary layer need to be captured. Spatial observations of multi-frequency and multi-scale temperature perturbations are a result from the turbulent interaction of the overlying atmosphere and the surface. However, these surface signatures are connected to the larger scales of the atmospheric boundary layer (McNaughton 2002, Tr&#228;umner 2015). When longer periods (a few hours to a few days) of spatial surface brightness temperatures are observed, the larger scale information needs to be accounted for to build a comprehensive understanding of surface-atmospheric spatial turbulent interactions. Additionally, the time-frequency decomposition of brightness temperature perturbations shows longer periods of 4-15 minutes superimposed over shorter periods of ~ 4&#8211;30 seconds. This suggests that that boundary layer dynamic scales (of longer periods) can influence brightness temperature perturbations on the local turbulent scale. An accurate TIV algorithm needs to account for all scales of motion when analysing the time-space variability of locally observed spatial brightness temperature patterns. To analyse these propositions temporally high resolved geostationary satellite infrared data from the Himawari 8 satellite was compared to near-surface and high speed (20 Hz) measured air and brightness temperature using thermocouple measurements and infrared cameras. The satellite provides a temporal resolution of 10-minutes and a horizontal resolution of 2 by 2 km per pixel and therefore captures the atmospheric meso &#947; and micro &#945; scale which signals are usually active for ~10 minutes to < 12 hours.&#160;Moreover, the Himawari 8 brightness temperature was used to create the near-surface mean velocity field using TIV. Afterwards, the velocity field was compared to the in-situ measured wind velocity over several days during January 2019. The results show that the atmospheric forcing from the micro &#945; scale to lower atmospheric scales has a major impact on the near-surface temperature over several minutes. A significant (p-value: 0.02) positive covariance between the Himawari 8 measurement and the local measured temperature 1.5 cm above the ground on a 10 minute average, specifically concerning cooling and heating patterns, has been found. Further analysis demonstrates that the retrieved near-surface 2-D velocity field calculated from the Himawari 8 brightness temperature perturbations is correctly representing the mean velocity. This finding allows the classification of meso-scale atmospheric forcing and its direct connection to local scale turbulent 2-D velocity measurements. This extends the TIV algorithm by a multi-scale component which allows to address inter-scale boundary layer analysis from a new point of view.&#160;In respect to the current findings a new experiment will focus on the repeated induced local velocity patterns from large scale forcing which will be measured through the surface brightness temperature." @default.
W3090496611 created "2020-10-08" @default.
W3090496611 creator A5024773574 @default.
W3090496611 creator A5083269048 @default.
W3090496611 creator A5091543149 @default.
W3090496611 date "2020-03-11" @default.
W3090496611 modified "2023-09-25" @default.
W3090496611 title "The infrared measurement cascade: Connecting large scale meteorologically induced surface temperature perturbations to local spatial velocity structures" @default.
W3090496611 doi "https://doi.org/10.5194/egusphere-egu2020-1106" @default.
W3090496611 hasPublicationYear "2020" @default.
W3090496611 type Work @default.
W3090496611 sameAs 3090496611 @default.
W3090496611 citedByCount "0" @default.
W3090496611 crossrefType "posted-content" @default.
W3090496611 hasAuthorship W3090496611A5024773574 @default.
W3090496611 hasAuthorship W3090496611A5083269048 @default.
W3090496611 hasAuthorship W3090496611A5091543149 @default.
W3090496611 hasConcept C111603439 @default.
W3090496611 hasConcept C120665830 @default.
W3090496611 hasConcept C121332964 @default.
W3090496611 hasConcept C125245961 @default.
W3090496611 hasConcept C153294291 @default.
W3090496611 hasConcept C158355884 @default.
W3090496611 hasConcept C158709400 @default.
W3090496611 hasConcept C18903297 @default.
W3090496611 hasConcept C196558001 @default.
W3090496611 hasConcept C2778755073 @default.
W3090496611 hasConcept C44870925 @default.
W3090496611 hasConcept C53802167 @default.
W3090496611 hasConcept C57879066 @default.
W3090496611 hasConcept C62520636 @default.
W3090496611 hasConcept C86803240 @default.
W3090496611 hasConcept C91228026 @default.
W3090496611 hasConcept C91586092 @default.
W3090496611 hasConcept C98444146 @default.
W3090496611 hasConceptScore W3090496611C111603439 @default.
W3090496611 hasConceptScore W3090496611C120665830 @default.
W3090496611 hasConceptScore W3090496611C121332964 @default.
W3090496611 hasConceptScore W3090496611C125245961 @default.
W3090496611 hasConceptScore W3090496611C153294291 @default.
W3090496611 hasConceptScore W3090496611C158355884 @default.
W3090496611 hasConceptScore W3090496611C158709400 @default.
W3090496611 hasConceptScore W3090496611C18903297 @default.
W3090496611 hasConceptScore W3090496611C196558001 @default.
W3090496611 hasConceptScore W3090496611C2778755073 @default.
W3090496611 hasConceptScore W3090496611C44870925 @default.
W3090496611 hasConceptScore W3090496611C53802167 @default.
W3090496611 hasConceptScore W3090496611C57879066 @default.
W3090496611 hasConceptScore W3090496611C62520636 @default.
W3090496611 hasConceptScore W3090496611C86803240 @default.
W3090496611 hasConceptScore W3090496611C91228026 @default.
W3090496611 hasConceptScore W3090496611C91586092 @default.
W3090496611 hasConceptScore W3090496611C98444146 @default.
W3090496611 hasLocation W30904966111 @default.
W3090496611 hasOpenAccess W3090496611 @default.
W3090496611 hasPrimaryLocation W30904966111 @default.
W3090496611 hasRelatedWork W13649122 @default.
W3090496611 hasRelatedWork W1452760 @default.
W3090496611 hasRelatedWork W15501494 @default.
W3090496611 hasRelatedWork W16372552 @default.
W3090496611 hasRelatedWork W20413638 @default.
W3090496611 hasRelatedWork W2297784 @default.
W3090496611 hasRelatedWork W3317684 @default.
W3090496611 hasRelatedWork W3474192 @default.
W3090496611 hasRelatedWork W6615381 @default.
W3090496611 hasRelatedWork W875273 @default.
W3090496611 isParatext "false" @default.
W3090496611 isRetracted "false" @default.
W3090496611 magId "3090496611" @default.
W3090496611 workType "article" @default.