Flow of premises through the study. by Eleni Mantzari (6991172)

“…</p><p>Methods and findings</p><p>The study was conducted between February and May 2023, in 13 licensed premises in England. It used an A-B-A reversal design, set over 3 consecutive 4-weekly periods with “A” representing the nonintervention periods during which standard serving sizes were served, and “B” representing the intervention period when the largest serving size of draught beer (1 imperial pint (568 ml)) was removed from existing ranges so that the largest size available was two-thirds of a pint. …”

Simulated number of cells via the Gillespie algorithm. by José Camacho Mateu (11473518)

Changes in AL (A) and SE (B) according to the treatment time estimation curve in patients given 0.125% atropine. by Zi-Rong Chen (9227618)

“…A larger In4_ALE correlated significantly with larger changes in AL at 6 months after In4_ALE in all myopic children. …”

Table 2 - Early identification of the efficacy of 0.125% atropine treatment for children with Myopia: A prospective pilot study by Zi-Rong Chen (9227618)

Gridding Triboelectric Nanogenerator for Raindrop Energy Harvesting by Bolang Cheng (11461820)

“…The peak output power density reaches 110 mW/m², which is 42 times the reported maximum value of 2.6 mW/m² of raindrop energy harvesting TENGs with the size larger than 10 cm². Moreover, the G-TENG can harvest the mechanical energy of raindrops at a wide range of raindrop flow rates from 0.055 to 0.219 mL/(cm²·s). …”

Gridding Triboelectric Nanogenerator for Raindrop Energy Harvesting by Bolang Cheng (11461820)

“…The peak output power density reaches 110 mW/m², which is 42 times the reported maximum value of 2.6 mW/m² of raindrop energy harvesting TENGs with the size larger than 10 cm². Moreover, the G-TENG can harvest the mechanical energy of raindrops at a wide range of raindrop flow rates from 0.055 to 0.219 mL/(cm²·s). …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

Real-Time Polymer Viscosity–Catalytic Activity Relationships on the Microscale by Or Eivgi (1677280)

“…Specifically, an increase in microenvironment viscosity led to a corresponding local decrease in the catalytic molecular ruthenium ring-opening metathesis polymerization rate, plausibly by restricting diffusional access to active catalytic centers. …”

CNOT-Efficient Circuits for Arbitrary Rank Many-Body Fermionic and Qubit Excitations by Ilias Magoulas (4807101)

“…Recently, Yordanov et al. [<i>Phys. Rev. A</i><b>102</b>, 062612 (2020); <i>Commun. Phys.…”

CNOT-Efficient Circuits for Arbitrary Rank Many-Body Fermionic and Qubit Excitations by Ilias Magoulas (4807101)

“…Recently, Yordanov et al. [<i>Phys. Rev. A</i><b>102</b>, 062612 (2020); <i>Commun. Phys.…”

Thermal Conductivity of a Fluid-Filled Nanoporous Material: Underlying Molecular Mechanisms and the <i>Rattle</i> Effect by Nikolas Ferreira de Souza (18102642)

“…In particular, a robust molecular framework to describe the crossover between the decrease in thermal conductivity through the rattle effect in very narrow pores and the increase in thermal conductivity when replacing vacuum with a fluid phase in larger pores is still missing. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”