Demonstration of test steps. by Jin Zhu (164147)

Algorithm operation steps. by Junyan Wang (4738518)

Different steps of the fabrication process. by Md. Abu Daud (21485629)

Adjustment step size. by Qingnan Ji (22662198)

“…Integration efficiency increases by 18.7%, and computational complexity is significantly reduced, with average computation time decreased by 15.4%. …”

Improving Accuracy and Transferability of Machine Learning Chemical Activation Energies by Adding Electronic Structure Information by Esteban Marques (14713002)

“…Recent advances have shown that machine learning can be used to create tools to predict them. Such tools can significantly decrease the computational cost for these predictions compared to traditional methods, which require an optimal path search along a high-dimensional potential energy surface. …”

Influence of Postsynthetic Ligand Exchange in ZIF‑7 on Gate-Opening Pressure and CO₂/CH₄ Mixture Separation by Lukas W. Bingel (9371686)

“…The enhanced surface affinity toward carbon dioxide, along with a sharper isotherm step and narrower hysteresis, translated to increased selectivity, faster cycling, and reduced process costs due to decreased energy input as shown by optimization opportunities of the high-pressure feed step.…”

Influence of Postsynthetic Ligand Exchange in ZIF‑7 on Gate-Opening Pressure and CO₂/CH₄ Mixture Separation by Lukas W. Bingel (9371686)

“…The enhanced surface affinity toward carbon dioxide, along with a sharper isotherm step and narrower hysteresis, translated to increased selectivity, faster cycling, and reduced process costs due to decreased energy input as shown by optimization opportunities of the high-pressure feed step.…”

Table1_Purification of linearized template plasmid DNA decreases double-stranded RNA formation during IVT reaction.DOCX by Juan Martínez (4474276)

DataSheet1_Purification of linearized template plasmid DNA decreases double-stranded RNA formation during IVT reaction.PDF by Juan Martínez (4474276)

Voltage, current and power behavior. by Rafael Mendes Faria (18886798)

An Integrated Approach for Determination of Total Per- and Polyfluoroalkyl Substances (PFAS) by Marzieh Shojaei (11084912)

“…In soils, the total PFAS estimated with results from an extraction method utilizing sequential acidic and basic solvents led to a 35% increase in precursors during TOP assay relative to results from a basic solvent only extraction in one of three soils tested, but concentrations did not increase significantly in remaining soils. …”

CONSORT flow diagram. by Christopher Angelillo (17743121)

“…It also increased daily steps and decreased sedentary time in participants who did not meet the recommended physical activity guidelines.…”

The evolutionary dynamics of molecular number of NSR in the modeling. by Yuzhen Liang (4347781)

Evaluation results of eye detection approaches. by Verdzekov Emile Tatinyuy (19959261)

“…<div><p>This study presents a novel multi-stage hierarchical approach to optimize key selection on virtual keyboards using eye gaze. …”

Shows the block diagram of ResNet34. by Verdzekov Emile Tatinyuy (19959261)

“…<div><p>This study presents a novel multi-stage hierarchical approach to optimize key selection on virtual keyboards using eye gaze. …”

Dynamic Covalent Chemistry Enabled Closed-Loop Recycling of Thermally Modified Polymer Membrane by Ching Yoong Loh (17863097)

“…Thermal and mechanical characterizations confirmed the great stability of the membranes, with the Diels–Alder reaction enabling depolymerization and reformation of the network without causing significant degradation. Additionally, the RFMs were recycled the third time, maintaining the fluxes (752 to 823 LMH) from the previous generation with a slight decrease in separation efficiency in dichloromethane-water emulsion separation (98.3 to 97%). …”

Dynamic Covalent Chemistry Enabled Closed-Loop Recycling of Thermally Modified Polymer Membrane by Ching Yoong Loh (17863097)

“…Thermal and mechanical characterizations confirmed the great stability of the membranes, with the Diels–Alder reaction enabling depolymerization and reformation of the network without causing significant degradation. Additionally, the RFMs were recycled the third time, maintaining the fluxes (752 to 823 LMH) from the previous generation with a slight decrease in separation efficiency in dichloromethane-water emulsion separation (98.3 to 97%). …”

Dynamic Covalent Chemistry Enabled Closed-Loop Recycling of Thermally Modified Polymer Membrane by Ching Yoong Loh (17863097)

“…Thermal and mechanical characterizations confirmed the great stability of the membranes, with the Diels–Alder reaction enabling depolymerization and reformation of the network without causing significant degradation. Additionally, the RFMs were recycled the third time, maintaining the fluxes (752 to 823 LMH) from the previous generation with a slight decrease in separation efficiency in dichloromethane-water emulsion separation (98.3 to 97%). …”

Dynamic Covalent Chemistry Enabled Closed-Loop Recycling of Thermally Modified Polymer Membrane by Ching Yoong Loh (17863097)

“…Thermal and mechanical characterizations confirmed the great stability of the membranes, with the Diels–Alder reaction enabling depolymerization and reformation of the network without causing significant degradation. Additionally, the RFMs were recycled the third time, maintaining the fluxes (752 to 823 LMH) from the previous generation with a slight decrease in separation efficiency in dichloromethane-water emulsion separation (98.3 to 97%). …”

Dynamic Covalent Chemistry Enabled Closed-Loop Recycling of Thermally Modified Polymer Membrane by Ching Yoong Loh (17863097)

“…Thermal and mechanical characterizations confirmed the great stability of the membranes, with the Diels–Alder reaction enabling depolymerization and reformation of the network without causing significant degradation. Additionally, the RFMs were recycled the third time, maintaining the fluxes (752 to 823 LMH) from the previous generation with a slight decrease in separation efficiency in dichloromethane-water emulsion separation (98.3 to 97%). …”