Overhead view of the eye drop aid. by Yuka Kasai (21354922)

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Raw_data_N_adition_increased_SOC_PNAS.xlsx by Guoyong Yan (14273351)

“…We found that SOC significantly increased with N addition, driven by the combined responses of plants, soil, and microbes. …”

Effect of Molecular Structure on the B3LYP-Computed HOMO–LUMO Gap: A Structure −Property Relationship Using Atomic Signatures by Ahmed Mohamed (628889)

“…The atomic fragments containing π-bonds in various aromatic compounds were found to be the most significant atomic Signatures, explaining nearly 50% of the variance in the data, with regression coefficients that decreased <i>E</i>_gap. …”

Temperature-dependent parameter values under stable temperatures conditions. by Zadoki Tabo (12415261)

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Temperature-invariant parameters, symbols, ranges and baseline values, and sources. by Zadoki Tabo (12415261)

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Temperature-dependent parameters, symbols, derived curves, ranges, and their sources. by Zadoki Tabo (12415261)

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Temperature effects on populations of <i>S. haematobium</i> and <i>S. mansoni</i> infections. by Zadoki Tabo (12415261)

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Temperature-dependent model parameters in the life history of <i>Schistosoma</i> species between human and intermediate host genera. by Zadoki Tabo (12415261)

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Impacts of individual input parameters on the output variables (a) by Zadoki Tabo (12415261)

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Dynamics of Solid–Liquid Compound Droplets on Cylindrically Concave Superhydrophobic Surfaces by Niju K. Mohammed (22631779)

“…Results indicate that the maximum spreading diameter (β_max) and the residence time of the composite droplet decrease with the increasing concavity ratio (δ) due to differences in axial and azimuthal spreading and gravity. …”

Dynamics of Solid–Liquid Compound Droplets on Cylindrically Concave Superhydrophobic Surfaces by Niju K. Mohammed (22631779)

“…Results indicate that the maximum spreading diameter (β_max) and the residence time of the composite droplet decrease with the increasing concavity ratio (δ) due to differences in axial and azimuthal spreading and gravity. …”

Dynamics of Solid–Liquid Compound Droplets on Cylindrically Concave Superhydrophobic Surfaces by Niju K. Mohammed (22631779)

“…Results indicate that the maximum spreading diameter (β_max) and the residence time of the composite droplet decrease with the increasing concavity ratio (δ) due to differences in axial and azimuthal spreading and gravity. …”

Dynamics of Solid–Liquid Compound Droplets on Cylindrically Concave Superhydrophobic Surfaces by Niju K. Mohammed (22631779)

“…Results indicate that the maximum spreading diameter (β_max) and the residence time of the composite droplet decrease with the increasing concavity ratio (δ) due to differences in axial and azimuthal spreading and gravity. …”

Dynamics of Solid–Liquid Compound Droplets on Cylindrically Concave Superhydrophobic Surfaces by Niju K. Mohammed (22631779)

“…Results indicate that the maximum spreading diameter (β_max) and the residence time of the composite droplet decrease with the increasing concavity ratio (δ) due to differences in axial and azimuthal spreading and gravity. …”

The speed diagram. by Yifei Li (198040)

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Factors of orthogonal experiment. by Yifei Li (198040)

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Analysis of variance in orthogonal test. by Yifei Li (198040)

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Comparison between simulation tests and bench tests. by Yifei Li (198040)

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Schematic diagram of the millet characteristic dimensions. by Yifei Li (198040)

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Structure and collision diagram of the millet hole seeding system. by Yifei Li (198040)

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