Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Heterogeneous Condensation on Simplified Viral Envelope Protein Structures by Kawkab Ahasan (18784843)

“…The rapid initial condensation fills up the gap between the pillars, reducing the active surface area and leading to a gradual decrease and a plateau in the condensation rate. …”

Initial transport rate of [³H]-hypoxanthine of PhZ mutants (V%). by Mariana Barraco-Vega (19996318)

“…Given the low V% value obtained with strains Y54G, V58A, A128F, Y129D, A148V and T429P (<2%), an arbitrary V% value of 2 was assigned for presentation purposes. …”

DataSheet_1_IGF2BP3 promotes progression of gallbladder carcinoma by stabilizing KLK5 mRNA in N6-methyladenosine-dependent binding.zip by Junzhe Zhang (1541173)

“…As a result, inhibition of KLK5 decreased the expression of PAR2, and deregulated phospho-Akt. …”

DataSheet_3_IGF2BP3 promotes progression of gallbladder carcinoma by stabilizing KLK5 mRNA in N6-methyladenosine-dependent binding.xlsx by Junzhe Zhang (1541173)

“…As a result, inhibition of KLK5 decreased the expression of PAR2, and deregulated phospho-Akt. …”

DataSheet_2_IGF2BP3 promotes progression of gallbladder carcinoma by stabilizing KLK5 mRNA in N6-methyladenosine-dependent binding.xlsx by Junzhe Zhang (1541173)

“…As a result, inhibition of KLK5 decreased the expression of PAR2, and deregulated phospho-Akt. …”

Peck’s formula for simulating a bilinear settlement curve. by Xingli Jia (13994009)

One-pot Synthesis of Metal-coordinated Covalent Organic Frameworks for Enhanced CO₂ Photoreduction by Hongbo Xue (10953437)

“…HB-TAPT + Co with ordered and segregated D–A arrays is synthesized by combining 2,4,6-tris(4-aminophenyl)-1,3,5-triazine (TAPT, a strong electron-acceptor) with 2-hydroxy-1,3,5-benzenetricarbaldehyde (HB)-loaded Co²⁺ (a strong electron-donor). …”