Fig 5 - by Yong-Rae Kim (19797278)

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S1 Table - by Yong-Rae Kim (19797278)

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Experimental procedure performed in this study. by Yong-Rae Kim (19797278)

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S2 Table - by Yong-Rae Kim (19797278)

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Fig 4 - by Yong-Rae Kim (19797278)

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Participant characteristics (<i>n</i> = 34). by Yong-Rae Kim (19797278)

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Comparison of six theoretical mood factors and TMD scores estimated using K-POMS-B between three ECDs (<i>n</i> = 34; *<i>p</i> < 0.05 using Friedman test with Bonferroni’s correct... by Yong-Rae Kim (19797278)

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S4 Table - by Yong-Rae Kim (19797278)

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S6 Table - by Yong-Rae Kim (19797278)

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Microbial differential abundance at 24 hours post-treatment was assessed using ANCOM (<i>P</i> <  0.05). by Elena G. Olson (10649705)

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Multiple drug-resistant <i>Salmonella</i> serovars used in the current study with previously described antibiotic resistance to several antibiotics. by Elena G. Olson (10649705)

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Overview of the experimental design in the current study. by Elena G. Olson (10649705)

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Effect of 1.25% of SCFP on MDR <i>Salmonella</i> serovars reduction at 24h. by Elena G. Olson (10649705)

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Effect of 1.25% SCFP on poultry cecal microbial composition inoculated with six multidrug-resistant (<i>MDR</i>) <i>Salmonella</i> serovars compared to a no-treatment control at 24... by Elena G. Olson (10649705)

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Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…We further find that the Weber number (<i>We</i>) significantly influences the Leidenfrost point, with the droplet impact wall behavior going through the states of film bounce back, ejecting tiny droplets and bounce back, and ultimately droplet breakup as the <i>We</i> increases. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…We further find that the Weber number (<i>We</i>) significantly influences the Leidenfrost point, with the droplet impact wall behavior going through the states of film bounce back, ejecting tiny droplets and bounce back, and ultimately droplet breakup as the <i>We</i> increases. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…We further find that the Weber number (<i>We</i>) significantly influences the Leidenfrost point, with the droplet impact wall behavior going through the states of film bounce back, ejecting tiny droplets and bounce back, and ultimately droplet breakup as the <i>We</i> increases. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…We further find that the Weber number (<i>We</i>) significantly influences the Leidenfrost point, with the droplet impact wall behavior going through the states of film bounce back, ejecting tiny droplets and bounce back, and ultimately droplet breakup as the <i>We</i> increases. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…We further find that the Weber number (<i>We</i>) significantly influences the Leidenfrost point, with the droplet impact wall behavior going through the states of film bounce back, ejecting tiny droplets and bounce back, and ultimately droplet breakup as the <i>We</i> increases. …”

Effect of the Surface Peak–Valley Features on Droplet Impact Dynamics under Leidenfrost Temperature by Yunlong Jiao (6672764)

“…We further find that the Weber number (<i>We</i>) significantly influences the Leidenfrost point, with the droplet impact wall behavior going through the states of film bounce back, ejecting tiny droplets and bounce back, and ultimately droplet breakup as the <i>We</i> increases. …”