Preparation process of concrete joint specimens. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

Cohesion correction coefficient. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

Fig 18 in each curve fitting results. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

Fig 29 in each curve fitting results. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

Fig 9(b) in the straight-line fitting results. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

Specimen packaging process. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

Relationship between τ_<i>i</i> and σ_<i>i</i>. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

The relationship between Δσ_n and τ₁, <i>JRC</i>. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

Relationship between τ_<i>i</i> and σ_<i>i</i>. by Zhezhe Zhang (19704587)

“…Under the same <i>JRC</i>, σ_<i>i</i> increases with the increase of τ₁, and Δσ_n decreases with the increasing τ₁. Under the same <i>JRC</i> and σ_<i>i</i>, τ_<i>i</i> is significantly smaller under the UNLCSL path than the CNL path. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”

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

“…The results indicate that initial condensation rates on surfaces with intermediate <i>p/d</i> ratios (e.g., 1.2–1.3) are significantly higher due to increased active surface area and droplet cluster formations. …”