Species richness (<i>SR</i>, upper panels) and Shannon’s entropy (<i>SE</i>, lower panels) vs. the rate in which new species are trying to invade the community, <i>νN</i>. by Immanuel Meyer (12306666)

Subjects:

Continuous Viscoelasticity Measurement of Cell Spheroids via Microfluidic Electrical Aspiration by Heyi Chen (19930197)

Subjects:

Inclusion and exclusion criteria delineated via the PCC (Population, Concept, Context) search framework. by Rabia Asghar (18840759)

Linearity of ACER3 activity assay. by Jae Kyo Yi (13570063)

The relationships between the mean time to extinction <i>T</i> and the size of the community, <i>N</i>, in different scenarios. by Immanuel Meyer (12306666)

Subjects:

Multiple linear regression analysis across generations in test populations. by Gurpreet Kaur Suri (12106975)

Subjects:

Containing the enlargement factor increases the possibility of identification of the large displacement vectors and the accuracy of the tracking. by Samuel E. Haarman (12908291)

The list of genes whose expression was largely increased by AdNKX2-1 infection. by Yuko Ito (1976692)

Subjects:

Linear regression model with MBI score. by Nadia Yanet Cortés-Álvarez (18611445)

Mean, SD and individual values of mechanical power difference for technique transitions when increasing and decreasing resistive force. by Gertjan Ettema (2802448)

Large deletions detected in sequenced dogs. by Erik Axelsson (201248)

The two mechanisms of increase. by Jakub Köry (17980273)

Mean time to extinction, <i>T</i>, is plotted against the initial frequency of the focal species <i>x</i>. by Immanuel Meyer (12306666)

Subjects:

Large copy number variants detected in sequenced dogs. by Erik Axelsson (201248)

Debiasing Watermarks for Large Language Models via Maximal Coupling by Yangxinyu Xie (21656912)

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. …”