Predictions of Age-Standardized Rate of burden caused by fire, heat and hot substances for different sexes in 2030 based on the Bayesian Age-Period-Cohort model. by Shi Huang (125861)

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Frontier Analysis: Countries with high potential for improvement in the burden of injuries caused by fire, heat, and hot substances in 2021. by Shi Huang (125861)

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Drinking Behaviors of the participants categorized by the respective year. by Jae Yeon Jeong (11979030)

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Sleep and Mental health of the participants categorized by the respective year. by Jae Yeon Jeong (11979030)

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The burden forecast of injuries caused by fire, heat, and hot substances for 2021–2030. by Shi Huang (125861)

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General characteristics of the participants categorized by the respective year. by Jae Yeon Jeong (11979030)

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The burden of injuries caused by fire, heat and hot substances in female and male across 22 GBD regions. by Shi Huang (125861)

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Burden of injuries caused by fire, heat, and substances in Disability-Adjusted Life Years, Years of Life Lost and Years Lived with Disability between 1990 and 2021. by Shi Huang (125861)

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Age-Standardized Rate of injuries caused by fire, heat and hot substances in 22 GBD regions with varying Social-Demographic Index globally from 1990 to 2021. by Shi Huang (125861)

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Difference in drinking, smoking, and suicidal ideation by year. by Jae Yeon Jeong (11979030)

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Graph of successive trends in the burden of injury caused by fire, heat and hot substances between 1990 and 2021. by Shi Huang (125861)

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Drinking Behaviors of the female participants categorized by the respective year. by Jae Yeon Jeong (11979030)

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Burden of injuries caused by fire, heat, and substances in Incidence, Prevalence and Death between 1990 and 2021. by Shi Huang (125861)

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Decomposition analysis of gastric cancer burden in Taiwan, stratified by gender. (A) Incidence. (B) Prevalence. (C) Mortality. (D) DALYs. Positive values on the X-axis indicate an... by Xiaohuang Yang (10182727)

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Distribution of continuous variables of all 3 visits of group 1 (placebo) and group 2 (placebo) that have no significant difference among the groups. by Nattapon Riengvirodkij (11268720)

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Amplitude for A/L = 0.29. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Top view of the experimental setup. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Amplitude for A/L = 0.338. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Parameters of energy harvesting. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Graph for Max Amplitude/Length at G_y = 0. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”