Test road monitoring results. by Yunke Liu (4839084)

“…The results show that the cement-phosphogypsum-red clay unconfined compressive strength decreases with the increase of the number of wet and dry cycles, with a larger decay in the first three times and leveling off thereafter. …”

Schematic diagram of the wet/dry cycle process. by Yunke Liu (4839084)

“…The results show that the cement-phosphogypsum-red clay unconfined compressive strength decreases with the increase of the number of wet and dry cycles, with a larger decay in the first three times and leveling off thereafter. …”

Quantitative analysis table of mix composition. by Yunke Liu (4839084)

“…The results show that the cement-phosphogypsum-red clay unconfined compressive strength decreases with the increase of the number of wet and dry cycles, with a larger decay in the first three times and leveling off thereafter. …”

Basic physical indexes of red clay. by Yunke Liu (4839084)

“…The results show that the cement-phosphogypsum-red clay unconfined compressive strength decreases with the increase of the number of wet and dry cycles, with a larger decay in the first three times and leveling off thereafter. …”

Sample preparation process diagram. by Yunke Liu (4839084)

“…The results show that the cement-phosphogypsum-red clay unconfined compressive strength decreases with the increase of the number of wet and dry cycles, with a larger decay in the first three times and leveling off thereafter. …”

Layout plan of settlement monitoring points. by Yunke Liu (4839084)

“…The results show that the cement-phosphogypsum-red clay unconfined compressive strength decreases with the increase of the number of wet and dry cycles, with a larger decay in the first three times and leveling off thereafter. …”

SCA-2 curing agent basic parameters. by Yunke Liu (4839084)

“…The results show that the cement-phosphogypsum-red clay unconfined compressive strength decreases with the increase of the number of wet and dry cycles, with a larger decay in the first three times and leveling off thereafter. …”

Sustainable Sea of Internet of Things: Wind Energy Harvesting System for Unmanned Surface Vehicles by Hao Cao (2248066)

“…The simulation and experimental results show that it can obtain a maximum average power of 23.25 mW at a wind speed of 8 m/s. …”

Sustainable Sea of Internet of Things: Wind Energy Harvesting System for Unmanned Surface Vehicles by Hao Cao (2248066)

“…The simulation and experimental results show that it can obtain a maximum average power of 23.25 mW at a wind speed of 8 m/s. …”

Sustainable Sea of Internet of Things: Wind Energy Harvesting System for Unmanned Surface Vehicles by Hao Cao (2248066)

“…The simulation and experimental results show that it can obtain a maximum average power of 23.25 mW at a wind speed of 8 m/s. …”

Sustainable Sea of Internet of Things: Wind Energy Harvesting System for Unmanned Surface Vehicles by Hao Cao (2248066)

“…The simulation and experimental results show that it can obtain a maximum average power of 23.25 mW at a wind speed of 8 m/s. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”

Insulator-on-Conductor Fouling Amplifies Aqueous Electrolysis Rates by Harry Morris Rodriguez (18331235)

“…The effect is not limited to reactants of limited water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled than clean electrodes. In a system involving a surface-active reactant, rate augmentation is driven by the synergy between insulator-confined reactant enrichment and insulator-induced current crowding, whereas only the latter and possibly localized decrease in <i>iR</i> drop near the insulator are relevant in a system composed of non-surface-active species. …”