Scattering efficiency by particle diameter. by Elliott Donghyun Kim (19469973)

“…Mie scattering, known for effectively decreasing short-wave infrared light, was employed by utilizing water aerosols having a diameter of 1 to 5 μm. …”

Relative transmission rate by wavelength. by Elliott Donghyun Kim (19469973)

“…Mie scattering, known for effectively decreasing short-wave infrared light, was employed by utilizing water aerosols having a diameter of 1 to 5 μm. …”

Failure mode of the sample. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Positions of AE probes and strain gauges. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Sampling site. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Received AE waves. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Test schemes for soft rocks. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Failure mode of the sample. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

S1 Table - by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

AE monitoring system. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

MTS-370.25 fatigue resting system. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Schematic diagram of the AE testing system. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Strain at different positions of the sample. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Transmission electron micrographs (TEM) of thin sections of cells of <i>L</i>. <i>rhamnosus</i> CRL 1505. by María A. Correa Deza (4097602)

DataSheet_5_SMRT and NCoR1 fine-tune inflammatory versus tolerogenic balance in dendritic cells by differentially regulating STAT3 signaling.pdf by Atimukta Jha (9671405)

Decreased expression of Gata4 target genes in <i>Gata4 G295S^ki/ki</i> embryonic hearts. by Chaitali Misra (165517)

Flow cytometric fluorescence density-plot analysis (Q₁ dead, Q₂ injured and Q₃ live cell population) of <i>L</i>. <i>rhamnosus</i> CRL 1505. by María A. Correa Deza (4097602)

Effects of adenosine receptor-specific antagonists on responses to hypoxia at E9.5 and E12.5. by Daniela L. Buscariollo (140729)

“…<p>A and B: Specimens were treated with DPCPX, an A1AR-specific antagonist at 10 nM (A: E9.5, n = 15; B: E12.5, n = 23), SCH-58261, an A2aAR-specific antagonist at 100 nM (A: E9.5, n = 15; B: E12.5, n = 19), or vehicle (A: E9.5, n = 27; B: E12.5, n = 42) at 15 min (arrows), and exposed to hypoxia (gray boxes). …”

Video 5_Acute amivantamab-induced myocardial injury in a patient with epidermal growth factor receptor-mutant lung cancer: a first case report.avi by Seiya Kaneko (22808465)

Overview of the study protocol. by Jan Maleček (17396660)