review article | Q7318358 |
scholarly article | Q13442814 |
P2093 | author name string | Yu Tian | |
Hong-Yu Lu | |||
Xiao-Song Li | |||
Jing-Ze Ma | |||
P2860 | cites work | Role of flexibility in the water repellency of water strider legs: Theory and experiment | Q21563743 |
Integrating evo-devo with ecology for a better understanding of phenotypic evolution | Q26862026 | ||
Evolution of a novel appendage ground plan in water striders is driven by changes in the Hox gene Ultrabithorax | Q28752275 | ||
Self-removal of condensed water on the legs of water striders | Q30659703 | ||
Predator strike shapes antipredator phenotype through new genetic interactions in water striders | Q30664296 | ||
Superior water repellency of water strider legs with hierarchical structures: experiments and analysis | Q30830581 | ||
Water striders adjust leg movement speed to optimize takeoff velocity for their morphology | Q30831576 | ||
Skating and diving: Changes in functional morphology of the setal and microtrichial cover during ontogenesis in Aquarius paludum fabricius (Heteroptera, Gerridae). | Q33321283 | ||
Emergence of tissue sensitivity to Hox protein levels underlies the evolution of an adaptive morphological trait. | Q33953859 | ||
A scanning electron microscopic study of mechanoreceptors in the walking legs of the water strider, Gerris remigis | Q34107080 | ||
Superhydrophobic states | Q34207759 | ||
The hydrodynamics of water strider locomotion | Q34220497 | ||
Diversity in Morphology and Locomotory Behavior Is Associated with Niche Expansion in the Semi-aquatic Bugs | Q37541545 | ||
BIOMECHANICS. Jumping on water: Surface tension-dominated jumping of water striders and robotic insects. | Q38389352 | ||
Grooming Behavior as a Mechanism of Insect Disease Defense | Q38606175 | ||
Escape jumping by three age-classes of water striders from smooth, wavy and bubbling water surfaces. | Q39327388 | ||
Elegant Shadow Making Tiny Force Visible- Water Walking Arthropod and Updated Archimedes' Principle | Q39351471 | ||
Key patterning genes contribute to leg elongation in water striders | Q40598966 | ||
Plastron respiration in the Coleoptera | Q44939643 | ||
Taxon-restricted genes at the origin of a novel trait allowing access to a new environment | Q46280018 | ||
Comparative functional analyses of ultrabithorax reveal multiple steps and paths to diversification of legs in the adaptive radiation of semi-aquatic insects. | Q46901662 | ||
Buoyant force and sinking conditions of a hydrophobic thin rod floating on water | Q47950854 | ||
Enhanced load-carrying capacity of hairy surfaces floating on water. | Q51088959 | ||
Condensation on ultrahydrophobic surfaces and its effect on droplet mobility: ultrahydrophobic surfaces are not always water repellant. | Q51252415 | ||
Effects of hydraulic pressure on the stability and transition of wetting modes of superhydrophobic surfaces. | Q51306206 | ||
Transition between superhydrophobic states on rough surfaces. | Q51634023 | ||
Morphology and neurophysiology of tarsal vibration receptors in the water strider Aquarius paludum (Heteroptera: Gerridae). | Q51658363 | ||
Experimental determination of the efficiency of nanostructuring on non-wetting legs of the water strider. | Q51702313 | ||
The load supported by small floating objects. | Q51939033 | ||
Biophysics: water-repellent legs of water striders. | Q52653115 | ||
Locomotion of arthropods in aquatic environment and their applications in robotics. | Q52672316 | ||
Studies on plastron respiration; the biology of Aphelocheirus [Hemiptera, Aphelocheiridae (Naucoridae) and the mechanism of plastron retention. | Q52694688 | ||
Characteristics of water strider legs in hydrodynamic situations. | Q52697069 | ||
Nature's design of hierarchical superhydrophobic surfaces of a water strider for low adhesion and low-energy dissipation. | Q52712287 | ||
Plastron respiration in aquatic insects. | Q52766252 | ||
Biomimetic "water strider leg" with highly refined nanogroove structure and remarkable water-repellent performance. | Q52778052 | ||
A test of the hypothesis of compensatory upstream dispersal using a stream-dwelling waterstrider, Gerris remigis Say. | Q53238037 | ||
How to walk on water | Q59090025 | ||
The genome of the water strider Gerris buenoi reveals expansions of gene repertoires associated with adaptations to life on the water | Q59336099 | ||
The complex contains a single gene that controls bristle development in the semi-aquatic bugs | Q59806255 | ||
Floating Objects with Finite Resistance to Bending | Q63848918 | ||
Sex Discrimination in Gerris remigis: Role of a Surface Wave Signal | Q81083459 | ||
Adhesion forces and contact angles of water strider legs | Q83045732 | ||
Structure and biomechanics of the antennal grooming mechanism in the southern green stink bug Nezara viridula | Q90308423 | ||
Honeybees use their wings for water surface locomotion | Q91329337 | ||
CLADISTIC INFERENCE AND EVOLUTIONARY SCENARIOS: LOCOMOTORY STRUCTURE, FUNCTION, AND PERFORMANCE IN WATER STRIDERS | Q92097167 | ||
Cooption of the pteridine biosynthesis pathway underlies the diversification of embryonic colors in water striders | Q93105155 | ||
P304 | page(s) | 1-11 | |
P577 | publication date | 2020-03-20 | |
P1433 | published in | Zoological Research | Q27714095 |
P1476 | title | Interfacial phenomena of water striders on water surfaces: a review from biology to biomechanics |
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