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Flagella and Motility in Bacteria01:18

Flagella and Motility in Bacteria

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Flagella are specialized, thread-like structures that extend from a bacteria's cell envelope. They play a crucial role in motility and chemotaxis. Their structural organization and functioning exemplify sophisticated biological engineering, enabling bacterial survival and adaptability in diverse environments.Structure of the FlagellumA bacterial flagellum consists of three key components: the filament, the hook, and basal body. The filament, a long, helical structure composed of repeating...
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Rocket Propulsion in Gravitational Field - II01:03

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A rocket's velocity in the presence of a gravitational field is decreased by the amount of force exerted by Earth's gravitational field, which opposes the motion of the rocket. If we consider thrust, that is, the force exerted on a rocket by the exhaust gases, then a rocket's thrust is greater in outer space than in the atmosphere or on a launch pad. In fact, gases are easier to expel in a vacuum.
A rocket's acceleration depends on three major factors, consistent with the...
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Rocket Propulsion in Empty Space - I01:13

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The driving force for the motion of any vehicle is friction, but in the case of rocket propulsion in space, the friction force is not present. The motion of a rocket changes its velocity (and hence its momentum) by ejecting burned fuel gases, thus causing it to accelerate in the direction opposite to the velocity of the ejected fuel. In this situation, the mass and velocity of the rocket constantly change along with the total mass of ejected gases. Due to conservation of momentum, the...
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Rocket Propulsion In Empty Space - II01:12

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The motion of a rocket is governed by the conservation of momentum principle. A rocket's momentum changes by the same amount (with the opposite sign) as the ejected gases. As time goes by, the rocket's mass (which includes the mass of the remaining fuel) continuously decreases, and its velocity increases. Therefore, the principle of conservation of momentum is used to explain the dynamics of a rocket's motion. The ideal rocket equation gives the change in velocity that a rocket...
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Rocket Propulsion in Gravitational Field - I01:20

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Rockets range in size from small fireworks that ordinary people use to the enormous Saturn V that once propelled massive payloads toward the Moon. The propulsion of all rockets, jet engines, deflating balloons, and even squids and octopuses are explained by the same physical principle: Newton's third law of motion. The matter is forcefully ejected from a system, producing an equal and opposite reaction on what remains.
The motion of a rocket in space changes its velocity (and hence its...
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Physiology of the Gastrointestinal System I: Ingestion and Propulsion01:22

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The physiology of the gastrointestinal system begins with ingestion as food enters the mouth.
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Related Experiment Video

Updated: Jan 30, 2026

Helical Organization of Blood Coagulation Factor VIII on Lipid Nanotubes
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Helical Organization of Blood Coagulation Factor VIII on Lipid Nanotubes

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Microswimmer Propulsion by Two Steadily Rotating Helical Flagella.

Henry Shum1

  • 1Department of Applied Mathematics, University of Waterloo, Waterloo, ON N2L 3G1, Canada. henry.shum@uwaterloo.ca.

Micromachines
|January 24, 2019
PubMed
Summary
This summary is machine-generated.

Two flagella enhance bacterial swimming speed and surface mobility compared to single flagella. This research informs bacterial morphology and microrobot design.

Keywords:
bacterial locomotionboundary element methodmagnetotactic bacteriamicroswimmermultiple flagellawall effect

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Area of Science:

  • Microbiology
  • Biophysics
  • Robotics

Background:

  • Bacterial locomotion is often modeled with a single rotating flagellum.
  • Magnetotactic bacteria exhibit unique flagellar arrangements.

Purpose of the Study:

  • To investigate the hydrodynamics of microswimmers with two flagella.
  • To compare the performance of two-flagella swimmers to single-flagella models.

Main Methods:

  • Numerical simulations of microswimmer motion.
  • Analysis of fluid dynamics near solid surfaces.

Main Results:

  • Increased swimming speed and reduced body rotation with flagella positioned farther apart.
  • Two-flagella swimmers exhibit straight or circular trajectories near surfaces.
  • Enhanced surface escape capabilities compared to single-flagella models.

Conclusions:

  • Two flagella significantly impact microswimmer performance and motility.
  • Findings are relevant for understanding bacterial diversity and designing artificial microswimmers.