A large degree of genetic structure exists in <i>Porites</i> spp. species complex. by Carly B. Scott (21736069)

Table of accords which are over- and under-represented in the data (large |<i>z</i>| values) and which also effect the number of reviews received by the perfumes in which the accor... by Vaiva Vasiliauskaite (6911651)

Large eccentric compression model. by Lidong Zhao (580657)

The results of a Kruskal Wallis test comparing the various adherence metrics, during increasing and decreasing periods, by pandemic phase are shown as the title of each graph: The <i>H</i> and <i>p</i> values are provided along with the degrees of freedom shown for each <i>H</i> value in brackets. by Barry Smyth (10826056)

Figure 6. Analysis of peptidergic network degree highlights hubs and a large rich club by Lidia Ripoll-Sánchez (17031075)

MS decreases the larger amplitude distribution in adult rats. by Jesús David Ayala-Rodríguez (17364296)

Differential responses to large positive perturbations of varying duration. by Måns Unosson (11851869)

Subjects:

Varying degrees of spatio-temporal partitioning between large carnivores in a fenced reserve, South Africa by Emma E.M. Evers (11575593)

Symmetry plots showing parameters that demonstrate large lateral asymmetry from the midsagittal plane. by Mark Morkos (13229214)

The introduction of mutualisms into assembled communities increases their connectance and complexity while decreasing their richness. by Gui Araujo (22170819)

“…(C) Mutualism also promotes an increase in network connectance when introduced into assembled communities, while stopping mutualistic interactions from entering an assembled system slowly decreases it. …”

Validation of self-reported height and weight in a large, nationwide cohort of U.S. adults - Fig 1 by James M. Hodge (8703657)

Subjects:

Different degrees of alteration. by Stefania Titton (8378721)

A parametric model with 71 attributes permits a large ‘face space’. by Sawitree Wisetchat (18706518)

Presidents' mental models over time (in-degree centrality) by Sami Russell Nour (22185145)

Development of Parallel On-the-Fly <i>Crystal</i> Algorithm for Reaction Discovery in Large and Complex Molecular Systems by Ankit Pandey (9179715)

“…This is achieved by performing an explicit exploration of a comparatively large <i>Crystal</i> configurational subspace, while gradually relaxing the remaining degrees of freedom. …”

MEDOC: A Fast, Scalable, and Mathematically Exact Algorithm for the Site-Specific Prediction of the Protonation Degree in Large Disordered Proteins by Martin J. Fossat (3714079)

“…Our algorithm applies the structure of the <i>q</i>-canonical ensemble, combined with novel strategies to rapidly obtain the minimal set of parameters, thereby circumventing the combinatorial explosion of the number of charge microstates even for proteins containing a large number of ionizable amino acids. …”

Nanofibrous Actuator with an Alignment Gradient for Millisecond-Responsive, Multidirectional, Multimodal, and Multidimensional Large Deformation by Juanrong Qin (9437568)

“…Herein, we employ a structural bionic strategy to design and fabricate a novel water/moisture responsive nanofibrous actuator with an alignment degree gradient. Owing to its different contraction gradient amplitudes along the thickness direction and the unique physical property of the nanofibrous material, the prepared actuator exhibits excellent shape deformation performance, including superfast response (less than 150 ms), controllable deformation directions, multiple actuation models, multiple dimensional deformation (0D–3D, 1D–3D, 2D–3D, and 3D–3D), large bending curvature (25.3 cm^–1), and a repeatability rate of at least 1000. …”

Nanofibrous Actuator with an Alignment Gradient for Millisecond-Responsive, Multidirectional, Multimodal, and Multidimensional Large Deformation by Juanrong Qin (9437568)

“…Herein, we employ a structural bionic strategy to design and fabricate a novel water/moisture responsive nanofibrous actuator with an alignment degree gradient. Owing to its different contraction gradient amplitudes along the thickness direction and the unique physical property of the nanofibrous material, the prepared actuator exhibits excellent shape deformation performance, including superfast response (less than 150 ms), controllable deformation directions, multiple actuation models, multiple dimensional deformation (0D–3D, 1D–3D, 2D–3D, and 3D–3D), large bending curvature (25.3 cm^–1), and a repeatability rate of at least 1000. …”

Nanofibrous Actuator with an Alignment Gradient for Millisecond-Responsive, Multidirectional, Multimodal, and Multidimensional Large Deformation by Juanrong Qin (9437568)

“…Herein, we employ a structural bionic strategy to design and fabricate a novel water/moisture responsive nanofibrous actuator with an alignment degree gradient. Owing to its different contraction gradient amplitudes along the thickness direction and the unique physical property of the nanofibrous material, the prepared actuator exhibits excellent shape deformation performance, including superfast response (less than 150 ms), controllable deformation directions, multiple actuation models, multiple dimensional deformation (0D–3D, 1D–3D, 2D–3D, and 3D–3D), large bending curvature (25.3 cm^–1), and a repeatability rate of at least 1000. …”

Nanofibrous Actuator with an Alignment Gradient for Millisecond-Responsive, Multidirectional, Multimodal, and Multidimensional Large Deformation by Juanrong Qin (9437568)

“…Herein, we employ a structural bionic strategy to design and fabricate a novel water/moisture responsive nanofibrous actuator with an alignment degree gradient. Owing to its different contraction gradient amplitudes along the thickness direction and the unique physical property of the nanofibrous material, the prepared actuator exhibits excellent shape deformation performance, including superfast response (less than 150 ms), controllable deformation directions, multiple actuation models, multiple dimensional deformation (0D–3D, 1D–3D, 2D–3D, and 3D–3D), large bending curvature (25.3 cm^–1), and a repeatability rate of at least 1000. …”