FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2564903344> ?p ?o ?g. }

• W2564903344 endingPage "627" @default.
• W2564903344 startingPage "618" @default.
• W2564903344 abstract "Purpose To investigate ion recombination and polarity effects in scanning and microionization chambers when used with digital electrometers and high‐dose‐rate linac beams such as flattening‐filter‐free (FFF) fields, and to compare results against conventional pulsed and continuous photon beams. Methods Saturation curves were obtained for one Farmer‐type ionization chamber and eight small‐volume chamber models with volumes ranging from 0.01 to 0.13 cm 3 using a Varian TrueBeam™ STx with FFF capability. Three beam modes (6 MV, 6 MV FFF, and 10 MV FFF) were investigated, with nominal dose‐per‐pulse values of 0.0278, 0.0648, and 0.111 cGy/pulse, respectively, at d max . Saturation curves obtained using the Theratronics T1000 60 Co unit at the UWADCL and a conventional linear accelerator (Varian Clinac iX) were used to establish baseline behavior. Jaffé plots were fitted to obtain P ion , accounting for exponential effects such as charge multiplication. These values were compared with the two‐voltage technique recommended in TG‐51, and were plotted as a function of dose‐per‐pulse to assess the ability of small‐volume chambers to meet reference‐class criteria in FFF beams. Results Jaffé‐ and two‐voltage‐determined P ion values measured for high‐dose‐rate beams agreed within 0.1% for the Farmer‐type chamber and 1% for scanning and microionization chambers, with the exception of the CC01 which agreed within 2%. With respect to ion recombination and polarity effects, the Farmer‐type chamber, scanning chambers and the Exradin A26 microchamber exhibited reference‐class behavior in all beams investigated, with the exception of the IBA CC04 scanning chamber, which had an initial recombination correction that varied by 0.2% with polarity. All microchambers investigated, with the exception of the A26, exhibited anomalous polarity and ion recombination behaviors that make them unsuitable for reference dosimetry in conventional and high‐dose‐rate photon beams. Conclusions The results of this work demonstrate that recombination and polarity behaviors seen in conventional pulsed and continuous photon beams trend accordingly in high‐dose‐rate FFF linac beams. Several models of small‐volume ionization chambers used with a digital electrometer have been shown to meet reference‐class requirements with respect to ion recombination and polarity, even in the high‐dose‐rate environment. For such chambers, a two‐voltage technique agreed well with more rigorous methods of determining P ion . However, the results emphasize the need for careful reference detector selection, and indicate that ionization chambers ought to be extensively tested in each beam of interest prior to their use for reference dosimetry." @default.
• W2564903344 created "2017-01-06" @default.
• W2564903344 creator A5009329296 @default.
• W2564903344 creator A5071702024 @default.
• W2564903344 creator A5074319306 @default.
• W2564903344 creator A5077635558 @default.
• W2564903344 date "2017-02-01" @default.
• W2564903344 modified "2023-10-12" @default.
• W2564903344 title "Ion recombination and polarity corrections for small-volume ionization chambers in high-dose-rate, flattening-filter-free pulsed photon beams" @default.
• W2564903344 cites W1511672462 @default.
• W2564903344 cites W1880819771 @default.
• W2564903344 cites W1979533454 @default.
• W2564903344 cites W1982429108 @default.
• W2564903344 cites W1985486205 @default.
• W2564903344 cites W2006673706 @default.
• W2564903344 cites W2007668419 @default.
• W2564903344 cites W2011294672 @default.
• W2564903344 cites W2012877757 @default.
• W2564903344 cites W2023602419 @default.
• W2564903344 cites W2027902922 @default.
• W2564903344 cites W2037886788 @default.
• W2564903344 cites W2038365068 @default.
• W2564903344 cites W2059194263 @default.
• W2564903344 cites W2066483664 @default.
• W2564903344 cites W2070721330 @default.
• W2564903344 cites W2073955944 @default.
• W2564903344 cites W2077135900 @default.
• W2564903344 cites W2083464082 @default.
• W2564903344 cites W2084911627 @default.
• W2564903344 cites W2116605249 @default.
• W2564903344 cites W2126225659 @default.
• W2564903344 cites W2165767756 @default.
• W2564903344 cites W2167659512 @default.
• W2564903344 cites W2335646924 @default.
• W2564903344 doi "https://doi.org/10.1002/mp.12053" @default.
• W2564903344 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/28001291" @default.
• W2564903344 hasPublicationYear "2017" @default.
• W2564903344 type Work @default.
• W2564903344 sameAs 2564903344 @default.
• W2564903344 citedByCount "16" @default.
• W2564903344 countsByYear W25649033442018 @default.
• W2564903344 countsByYear W25649033442019 @default.
• W2564903344 countsByYear W25649033442020 @default.
• W2564903344 countsByYear W25649033442021 @default.
• W2564903344 countsByYear W25649033442022 @default.
• W2564903344 countsByYear W25649033442023 @default.
• W2564903344 crossrefType "journal-article" @default.
• W2564903344 hasAuthorship W2564903344A5009329296 @default.
• W2564903344 hasAuthorship W2564903344A5071702024 @default.
• W2564903344 hasAuthorship W2564903344A5074319306 @default.
• W2564903344 hasAuthorship W2564903344A5077635558 @default.
• W2564903344 hasConcept C113196181 @default.
• W2564903344 hasConcept C120665830 @default.
• W2564903344 hasConcept C121332964 @default.
• W2564903344 hasConcept C145148216 @default.
• W2564903344 hasConcept C151770136 @default.
• W2564903344 hasConcept C168834538 @default.
• W2564903344 hasConcept C180048950 @default.
• W2564903344 hasConcept C184779094 @default.
• W2564903344 hasConcept C185592680 @default.
• W2564903344 hasConcept C192562407 @default.
• W2564903344 hasConcept C198291218 @default.
• W2564903344 hasConcept C2780271382 @default.
• W2564903344 hasConcept C2989005 @default.
• W2564903344 hasConcept C43617362 @default.
• W2564903344 hasConcept C62520636 @default.
• W2564903344 hasConcept C71924100 @default.
• W2564903344 hasConcept C75088862 @default.
• W2564903344 hasConceptScore W2564903344C113196181 @default.
• W2564903344 hasConceptScore W2564903344C120665830 @default.
• W2564903344 hasConceptScore W2564903344C121332964 @default.
• W2564903344 hasConceptScore W2564903344C145148216 @default.
• W2564903344 hasConceptScore W2564903344C151770136 @default.
• W2564903344 hasConceptScore W2564903344C168834538 @default.
• W2564903344 hasConceptScore W2564903344C180048950 @default.
• W2564903344 hasConceptScore W2564903344C184779094 @default.
• W2564903344 hasConceptScore W2564903344C185592680 @default.
• W2564903344 hasConceptScore W2564903344C192562407 @default.
• W2564903344 hasConceptScore W2564903344C198291218 @default.
• W2564903344 hasConceptScore W2564903344C2780271382 @default.
• W2564903344 hasConceptScore W2564903344C2989005 @default.
• W2564903344 hasConceptScore W2564903344C43617362 @default.
• W2564903344 hasConceptScore W2564903344C62520636 @default.
• W2564903344 hasConceptScore W2564903344C71924100 @default.
• W2564903344 hasConceptScore W2564903344C75088862 @default.
• W2564903344 hasIssue "2" @default.
• W2564903344 hasLocation W25649033441 @default.
• W2564903344 hasLocation W25649033442 @default.
• W2564903344 hasOpenAccess W2564903344 @default.
• W2564903344 hasPrimaryLocation W25649033441 @default.
• W2564903344 hasRelatedWork W1974368552 @default.
• W2564903344 hasRelatedWork W2025881135 @default.
• W2564903344 hasRelatedWork W2048513016 @default.
• W2564903344 hasRelatedWork W2432853332 @default.
• W2564903344 hasRelatedWork W2594621417 @default.
• W2564903344 hasRelatedWork W2890169615 @default.
• W2564903344 hasRelatedWork W2982119686 @default.
• W2564903344 hasRelatedWork W3082738208 @default.

• next