Norm ISWSVR: A Data Integration and Normalization Approach for Large-Scale Metabolomics by Xian Ding (421647)

“…More importantly, Norm ISWSVR also allows a low frequency of QCs, which could significantly decrease the burden of a large-scale experiment. …”

Brief Report: Increased technology use associated with lower A1C in a large pediatric clinical population by G. Todd Alonso (9568724)

Two hypothesized models for C period decrease as growth rate increases. by Sara Sanders (4163479)

The proportion of lake area which exhibited decreases (blue bars) versus increases (green bars) in chl-a for the largest 18 lakes in the world. by Benjamin M. Kraemer (7526225)

Data from: Colony losses of stingless bees increase in agricultural areas, but decrease in forested areas by Malena Sibaja Leyton (18400983)

Realize large improvements in average NUE by removing low iNUE. by Newell R. Kitchen (12530448)

Fig 3 - by Calvin P. Philp (12095878)

Large play kit. by Calli Naish (17125111)

Unexpected Parabolic Temperature Dependency of CH₄ Emissions from Rice Paddies by Haoyu Qian (800177)

Subjects:

Innovation, nightlights and a continuous measure of city size. by Saul Estrin (8629173)

Subjects:

Studies with large effect sizes tend to have low samples sizes. by Jeff C. Clements (9161831)

The percentages of genes with largely changed expression after AdNKX2-1 infection. by Yuko Ito (1976692)

Subjects:

Tissue, days post-infection (dpi) and the top 10 most significant genes with increased and decreased expression with valid gene symbols for the response contrasts. by Gillian P. McHugo (8965919)

Large <i>Bgl-</i>FaNaC neurons labeled with HCR <i>in situ</i> hybridization. by Laura C. Vicente-Rodríguez (16437803)

High-Temperature Resistance, Lightweight, and Thermally Insulating Silica Aerogel via Doping Hollow Silica Nanoparticles by Mingyang Yang (1405321)

“…Traditional solutions to this issue, such as doping with opacifiers or fibers, often increase thermal conductivity and density. To increase the thermal stability of standard aerogels comprising small full-density SiO₂ nanoparticles (SFPs) (typically 2–15 nm in diameter), SiO₂ aerogels were doped with large hollow SiO₂ nanoparticles (LHPs) with diameters of 100–250 nm. …”

High-Temperature Resistance, Lightweight, and Thermally Insulating Silica Aerogel via Doping Hollow Silica Nanoparticles by Mingyang Yang (1405321)

“…Traditional solutions to this issue, such as doping with opacifiers or fibers, often increase thermal conductivity and density. To increase the thermal stability of standard aerogels comprising small full-density SiO₂ nanoparticles (SFPs) (typically 2–15 nm in diameter), SiO₂ aerogels were doped with large hollow SiO₂ nanoparticles (LHPs) with diameters of 100–250 nm. …”

High-Temperature Resistance, Lightweight, and Thermally Insulating Silica Aerogel via Doping Hollow Silica Nanoparticles by Mingyang Yang (1405321)

“…Traditional solutions to this issue, such as doping with opacifiers or fibers, often increase thermal conductivity and density. To increase the thermal stability of standard aerogels comprising small full-density SiO₂ nanoparticles (SFPs) (typically 2–15 nm in diameter), SiO₂ aerogels were doped with large hollow SiO₂ nanoparticles (LHPs) with diameters of 100–250 nm. …”

High-Temperature Resistance, Lightweight, and Thermally Insulating Silica Aerogel via Doping Hollow Silica Nanoparticles by Mingyang Yang (1405321)

“…Traditional solutions to this issue, such as doping with opacifiers or fibers, often increase thermal conductivity and density. To increase the thermal stability of standard aerogels comprising small full-density SiO₂ nanoparticles (SFPs) (typically 2–15 nm in diameter), SiO₂ aerogels were doped with large hollow SiO₂ nanoparticles (LHPs) with diameters of 100–250 nm. …”

High-Temperature Resistance, Lightweight, and Thermally Insulating Silica Aerogel via Doping Hollow Silica Nanoparticles by Mingyang Yang (1405321)

“…Traditional solutions to this issue, such as doping with opacifiers or fibers, often increase thermal conductivity and density. To increase the thermal stability of standard aerogels comprising small full-density SiO₂ nanoparticles (SFPs) (typically 2–15 nm in diameter), SiO₂ aerogels were doped with large hollow SiO₂ nanoparticles (LHPs) with diameters of 100–250 nm. …”

High-Temperature Resistance, Lightweight, and Thermally Insulating Silica Aerogel via Doping Hollow Silica Nanoparticles by Mingyang Yang (1405321)

“…Traditional solutions to this issue, such as doping with opacifiers or fibers, often increase thermal conductivity and density. To increase the thermal stability of standard aerogels comprising small full-density SiO₂ nanoparticles (SFPs) (typically 2–15 nm in diameter), SiO₂ aerogels were doped with large hollow SiO₂ nanoparticles (LHPs) with diameters of 100–250 nm. …”