A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

Image_5_Safflower Yellow and Its Main Component HSYA Alleviate Diet-Induced Obesity in Mice: Possible Involvement of the Increased Antioxidant Enzymes in Liver and Adipose Tissue.j... by Kemin Yan (4924420)

HSV-1 DNA replication does not decrease H3.1 mobilization in U2OS cells. by Kristen L. Conn (469235)

High initiation rates decrease stability of stall-containing <i>S</i>. <i>cerevisiae</i> mRNAs. by Heungwon Park (3859507)

Image5_A distinct immune landscape in anti-synthetase syndrome profiled by a single-cell genomic study.jpeg by Jiayu Ding (12005975)

“…As ASS and MDA5⁺ DM have similar organ involvements, MDA5⁺ DM was used as a disease control. …”

Mitochondrial Na⁺ transients are coincident with transient decrease in cytosolic Mg²⁺ concentration. by Guillaume Azarias (194360)

Developmental status of non-eclosing <i>Cotesia ruficrus.</i> by Xian Li (201841)

Reduced resistance and exacerbated lung inflammation in <i>ccr2</i>^-/- mice with <i>C</i>. <i>muridarum</i> respiratory infection. by Shuaini Yang (20670608)

Trending decrease in Slfn family RNA expression from the splenic tissue of VC-Slfn3KO mice. by Emilie E. Vomhof-DeKrey (6900677)

Efficacy and Safety of OnabotulinumtoxinA in Patients with Neurogenic Detrusor Overactivity: A Systematic Review and Meta-Analysis of Randomized Controlled Trials by Tao Cheng (1235148)

“…The onabotulinumtoxinA-treated groups had a significantly decreased mean number of urinary incontinence episodes per week (at week 6) (onabotulinumtoxinA200U: MD: -10.72, 95% CI: -13.4 to -8.04, P<0.00001; 300 U: MD: -11.42, 95% CI: -13.91 to -8.93, P<0.00001), MDP (200 U: MD: -33.46, 95% CI: -39.74 to -27.18, P<0.00001; 300 U: MD: -31.72, 95% CI: -37.69 to -25.75, P<0.00001), and greater increased MCC (200 U: MD: 141.30, 95% CI: 121.28 to 161.32, P<0.00001; 300 U: MD: 151.39, 95% CI: 130.43 to 172.34, P<0.00001) compared to the placebo-treated groups. …”

In vivo DLS infusion of the mGluR5 inhibitor MPEP at late training stages preserves behavioral sensitivity to contingency change in overtrained mice. by Vincent Paget-Blanc (21807763)

Scatter dot plot of the absolute levels of change in LH and FSH between the baseline and week-15 visit. by Sigrid Nilsson (12647302)

Adiponectin expression is required for <i>Urtica dioica</i> L. to enhance ceramidase activity and decrease ceramide accumulation. by Diana N. Obanda (2551765)