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3 article(s) from Krings, Wencke

Ultrablack color in velvet ant cuticle

Vinicius Marques Lopez,
Wencke Krings,
Juliana Reis Machado,
Stanislav Gorb and
Rhainer Guillermo-Ferreira

Beilstein J. Nanotechnol. 2024, 15, 1554–1565, doi:10.3762/bjnano.15.122

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Figure 1: Examples of ultrablack colors in animals within their natural habitats. (A) Peacock spider (Maratus...

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Figure 2: Velvet ants (Traumatomutilla bifurca, Hymenoptera: Mutillidae) in their natural habitats. The image...

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Figure 3: Reflectance spectra of ultrablack colors in the velvet ant Traumatomutilla bifurca (Hymenoptera: Mu...

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Figure 4: Scanning electron microscopy (SEM) images of the cuticle surface of Traumatomutilla bifurca (Hymeno...

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Figure 5: Scanning (A–D) and transmission (E and F) electron microscopy images of the cuticle structure of Tr...

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Figure 6: Scheme illustrating the functionality of the surface structure in Traumatomutilla bifurca (Hymenopt...

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Figure 7: Confocal laser scanning microscopy micrographs (maximum intensity projections) showing different ty...

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Figure 8: Thermal images of a female Traumatomutilla bifurca (Hymenoptera: Mutillidae). (A) Visible spectrum ...

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Published 02 Dec 2024

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Functional morphology of cleaning devices in the damselfly Ischnura elegans (Odonata, Coenagrionidae)

Silvana Piersanti,
Gianandrea Salerno,
Wencke Krings,
Stanislav Gorb and
Manuela Rebora

Beilstein J. Nanotechnol. 2024, 15, 1260–1272, doi:10.3762/bjnano.15.102

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Figure 1: Left foreleg of Ischnura elegans (female) in SEM (a–e) and semithin section (f) of a grooming devic...

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Figure 2: Confocal laser scanning micrographs (maximum intensity projections) showing differences in the auto...

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Figure 3: Ethograms of different bouts recorded during the grooming of Ischnura elegans. (a) First, (b), seco...

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Figure 4: (a) Frequency and (b) duration of the different recorded acts during the grooming of Ischnura elega...

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Figure 5: Particle removal efficiency in intact (a–c, h, j, k) and ablated (with the foretibial grooming stru...

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Figure 6: Mouthparts of Ischnura elegans dissected immediately after the antennal grooming behavior. (a) Vent...

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Published 16 Oct 2024

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Suspension feeding in Copepoda (Crustacea) – a numerical model of setae acting in concert

Alexander E. Filippov,
Wencke Krings and
Stanislav N. Gorb

Beilstein J. Nanotechnol. 2023, 14, 603–615, doi:10.3762/bjnano.14.50

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Figure 1: Confocal laser scanning micrograph (maximum intensity projection) showing the exoskeleton of a fema...

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Figure 2: Number of eaten particles as a function of the time for systems containing only short setae (lines ...

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Figure 3: The same as Figure 2, but for systems containing both long and short setae. Line 1 corresponds to the optim...

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Figure 4: Number of eaten particles as a function of the time for the systems containing both short and long ...

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Figure 5: Number of eaten particles for different degrees of adhesion of the long setae tips. Multiple experi...

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Figure 6: Time dependencies of N_eaten at different angles of rotation for the basic segments of the short set...

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Figure 7: The same as in Figure 6 for the system containing both long and short setae. The short setae had the optima...

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Figure 8: Density distributions obtained from long-time simulation runs in the (y,z) plane shown by grayscale...

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Figure 9: The same as in Figure 8 for two optimal configurations. (a, c) Only short setae (hard setae with soft tips ...

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Figure 10: Concept of the numerical model. Setae, arranged as two pairs of seta rows (internal short setae and...

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Published 17 May 2023

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