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W3204649659 startingPage "14215" @default.
W3204649659 abstract "Abstract. In this work, an abundance of ice-nucleating particles (INPs) from livestock facilities was studied through laboratory measurements from cloud-simulation chamber experiments and field investigation in the Texas Panhandle. Surface materials from two livestock facilities, one in the Texas Panhandle and another from McGregor, Texas, were selected as dust proxies for laboratory analyses. These two samples possessed different chemical and biological properties. A combination of aerosol interaction and dynamics in the atmosphere (AIDA) measurements and offline ice spectrometry was used to assess the immersion freezing mode ice nucleation ability and efficiency of these proxy samples at temperatures above −29 ∘C. A dynamic filter processing chamber was also used to complement the freezing efficiencies of submicron and supermicron particles collected from the AIDA chamber. For the field survey, periodic ambient particle sampling took place at four commercial livestock facilities from July 2017 to July 2019. INP concentrations of collected particles were measured using an offline freezing test system, and the data were acquired for temperatures between −5 and −25 ∘C. Our AIDA laboratory results showed that the freezing spectra of two livestock dust proxies exhibited higher freezing efficiency than previously studied soil dust samples at temperatures below −25 ∘C. Despite their differences in composition, the freezing efficiencies of both proxy livestock dust samples were comparable to each other. Our dynamic filter processing chamber results showed on average approximately 50 % supermicron size dominance in the INPs of both dust proxies. Thus, our laboratory findings suggest the importance of particle size in immersion freezing for these samples and that the size might be a more important factor for immersion freezing of livestock dust than the composition. From a 3-year field survey, we measured a high concentration of ambient INPs of 1171.6 ± 691.6 L−1 (average ± standard error) at −25 ∘C for aerosol particles collected at the downwind edges of livestock facilities. An obvious seasonal variation in INP concentration, peaking in summer, was observed, with the maximum at the same temperature exceeding 10 000 L−1 on 23 July 2018. The observed high INP concentrations suggest that a livestock facility is a substantial source of INPs. The INP concentration values from our field survey showed a strong correlation with measured particulate matter mass concentration, which supports the importance of size in ice nucleation of particles from livestock facilities." @default.
W3204649659 created "2021-10-11" @default.
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W3204649659 date "2021-09-24" @default.
W3204649659 modified "2023-10-14" @default.
W3204649659 title "Laboratory and field studies of ice-nucleating particles from open-lot livestock facilities in Texas" @default.
W3204649659 cites W1633474379 @default.
W3204649659 cites W1973577532 @default.
W3204649659 cites W1979922580 @default.
W3204649659 cites W1986687589 @default.
W3204649659 cites W1997721614 @default.
W3204649659 cites W1997748083 @default.
W3204649659 cites W1998647656 @default.
W3204649659 cites W2003558508 @default.
W3204649659 cites W2011254969 @default.
W3204649659 cites W2014697432 @default.
W3204649659 cites W2019952129 @default.
W3204649659 cites W2026126728 @default.
W3204649659 cites W2053125454 @default.
W3204649659 cites W2061246363 @default.
W3204649659 cites W2084177570 @default.
W3204649659 cites W2087205377 @default.
W3204649659 cites W2090561822 @default.
W3204649659 cites W2100069759 @default.
W3204649659 cites W2100365896 @default.
W3204649659 cites W2102319010 @default.
W3204649659 cites W2102338459 @default.
W3204649659 cites W2105286019 @default.
W3204649659 cites W2107528792 @default.
W3204649659 cites W2114337380 @default.
W3204649659 cites W2125840831 @default.
W3204649659 cites W2137223522 @default.
W3204649659 cites W2140247361 @default.
W3204649659 cites W2145192043 @default.
W3204649659 cites W2153979644 @default.
W3204649659 cites W2155423388 @default.
W3204649659 cites W2157528493 @default.
W3204649659 cites W2158137897 @default.
W3204649659 cites W2161587320 @default.
W3204649659 cites W2162509780 @default.
W3204649659 cites W2166715881 @default.
W3204649659 cites W2184680220 @default.
W3204649659 cites W2195223536 @default.
W3204649659 cites W2258185802 @default.
W3204649659 cites W2264569645 @default.
W3204649659 cites W2296138349 @default.
W3204649659 cites W2405946698 @default.
W3204649659 cites W2416701218 @default.
W3204649659 cites W2417369947 @default.
W3204649659 cites W2517359970 @default.
W3204649659 cites W2543460200 @default.
W3204649659 cites W2566267159 @default.
W3204649659 cites W2593887101 @default.
W3204649659 cites W2612386074 @default.
W3204649659 cites W2616871981 @default.
W3204649659 cites W2619741711 @default.
W3204649659 cites W2767020497 @default.
W3204649659 cites W2790696117 @default.
W3204649659 cites W2802420031 @default.
W3204649659 cites W2808410171 @default.
W3204649659 cites W2809280069 @default.
W3204649659 cites W2898173402 @default.
W3204649659 cites W2924989158 @default.
W3204649659 cites W2936810019 @default.
W3204649659 cites W2944594732 @default.
W3204649659 cites W2948580053 @default.
W3204649659 cites W2985318829 @default.
W3204649659 cites W2995682630 @default.
W3204649659 cites W2998500935 @default.
W3204649659 cites W3000104560 @default.
W3204649659 cites W3028293912 @default.
W3204649659 cites W3039789320 @default.
W3204649659 cites W3085788146 @default.
W3204649659 cites W3086814589 @default.
W3204649659 cites W3106882685 @default.
W3204649659 cites W3107998125 @default.
W3204649659 cites W3131764431 @default.
W3204649659 cites W3135937323 @default.
W3204649659 cites W4254773053 @default.
W3204649659 doi "https://doi.org/10.5194/acp-21-14215-2021" @default.
W3204649659 hasPublicationYear "2021" @default.