Euler force
The Euler force, also known as the azimuthal force, is a fictitious force that arises in non-inertial reference frames, specifically those undergoing angular acceleration, such as rotating frames with time-varying angular velocity.[1] It manifests as an apparent force acting on an object of mass m at position \mathbf{r} relative to the frame's origin, given by the vector equation \mathbf{F}_E = -m \dot{\boldsymbol{\omega}} \times \mathbf{r}, where \dot{\boldsymbol{\omega}} denotes the angular acceleration of the frame.[2] This force is perpendicular to both the position vector and the angular acceleration, directing objects tangentially in opposition to changes in the frame's rotation rate, and it vanishes in frames with constant angular velocity.[3] In the broader context of classical mechanics, the Euler force complements other fictitious forces like the centrifugal force (due to constant rotation) and the Coriolis force (due to relative motion within the frame), enabling the application of Newton's laws in rotating coordinates by incorporating these inertial effects into the effective force balance.[1] Its derivation stems from the transport theorem, which relates the time derivative of vectors between inertial and rotating frames, yielding the full acceleration expression:\mathbf{a}_\text{inertial} = \mathbf{a}_\text{rot} + \dot{\boldsymbol{\omega}} \times \mathbf{r} + \boldsymbol{\omega} \times (\boldsymbol{\omega} \times \mathbf{r}) + 2 \boldsymbol{\omega} \times \mathbf{v}_\text{rot},
where the \dot{\boldsymbol{\omega}} \times \mathbf{r} term corresponds to the Euler acceleration.[2] Named after the mathematician Leonhard Euler for his foundational work on rotational dynamics, this force is crucial for analyzing systems where rotational speed varies, such as accelerating gyroscopes, rotating machinery, or planetary motion with tidal influences.[3] Applications of the Euler force extend to engineering, where it influences the stability of rotating structures under varying speeds.[4] It contributes to subtle effects in Earth's rotation, though often negligible compared to constant-\boldsymbol{\omega} terms for daily analyses.[3] In fluid mechanics, analogous terms appear in the Navier-Stokes equations transformed to rotating coordinates.[2] Understanding the Euler force thus provides a unified framework for non-inertial dynamics, bridging theoretical mechanics with practical simulations in fields like aerospace and robotics.[1]
Fundamentals
Definition and Context
In physics, an inertial reference frame is defined as one in which the laws of motion, particularly Newton's first law, hold true without additional corrections: objects not subject to external forces remain at rest or move with constant velocity in straight lines relative to the frame. Non-inertial reference frames, by contrast, are those accelerating or rotating relative to an inertial frame, leading to apparent deviations from these laws that necessitate the inclusion of fictitious forces to restore their validity. Rotating reference frames represent a key subclass of non-inertial frames, where the observer's coordinate system rotates with respect to the stars or another inertial basis. The Euler force is a fictitious or pseudo-force that emerges specifically in a rotating reference frame undergoing angular acceleration, acting on objects within that frame in the direction opposite to the frame's angular acceleration, often manifesting as a tangential component.[5] This force accounts for the apparent motion of objects due to the changing rotation rate of the frame itself, distinguishing it from effects caused by constant rotation.[6] Named after the Swiss mathematician Leonhard Euler, the concept traces its origins to his pioneering contributions to rigid body dynamics in the 18th century, where he formalized equations governing rotational motion of solid bodies around 1750–1760, laying the groundwork for understanding forces in accelerated rotations.[7] Euler's work, including publications like Decouverte d’un nouveau principe de mécanique in 1752, integrated principles of torque and angular momentum that implicitly involve such pseudo-forces in non-inertial analyses.[7] In the context of Newton's second law, the Euler force modifies the effective force balance in a non-inertial rotating frame by adding it—alongside other fictitious forces like the centrifugal and Coriolis terms—to the real forces, enabling the equation \mathbf{F} = m \mathbf{a} to describe observed accelerations as if the frame were inertial.[8] This adjustment ensures that dynamics in rotating systems, such as those in engineering or celestial mechanics, can be analyzed consistently using Newtonian principles.[8]Intuitive Example
Consider a person standing on a merry-go-round that begins to rotate with increasing speed. As the platform accelerates angularly, the rider experiences a tangential force pushing them backward relative to the platform, in the direction opposite to the intended motion. This sensation arises because, from the perspective of the rotating frame, the rider's body resists the change in rotation rate, creating an apparent push.[9] To understand this intuitively, examine the scenario step by step in qualitative terms. In the inertial (non-rotating) frame of reference, the rider initially has a certain angular velocity and tends to maintain it due to inertia, following a straight-line path tangent to the circle of motion. However, as the merry-go-round undergoes angular acceleration—speeding up or slowing down—the platform rotates faster or slower than the rider's inertial motion expects. This mismatch causes the rider to appear to slide or be pushed tangentially within the rotating frame, manifesting as the Euler force directed opposite to the angular acceleration. For instance, when the merry-go-round speeds up, the rider feels shoved backward along the tangent, opposite to the direction of rotation; when it slows down, the sensation reverses, pulling them forward.[1][10] A diagram illustrating this would show the merry-go-round's angular acceleration vector (pointing along the axis of rotation) and arrows indicating the resulting Euler force on the rider, perpendicular to the radius and opposite the acceleration direction, highlighting the tangential displacement.[9] It is important to note a common misconception: the Euler force is not a real interaction like gravity or friction but a fictitious effect perceived solely because the observer is in an angularly accelerating reference frame; in the inertial frame, no such force acts on the rider.[1]Mathematical Formulation
Derivation from Reference Frame Transformations
The derivation of the Euler force begins with the transformation of the acceleration of a particle between an inertial reference frame and a rotating reference frame. In the inertial frame, the absolute acceleration of a point mass at position \vec{r} is given by \vec{a}_{\text{inertial}} = \frac{d^2 \vec{r}}{dt^2}. To relate this to the rotating frame, where the frame rotates with angular velocity \vec{\omega}(t), the position vector \vec{r} is the same in both frames at any instant, but its time derivatives differ due to the rotation.[1] The key to the derivation lies in the transport theorem for the time derivative of a vector \vec{A} in a rotating frame: the absolute (inertial) derivative is \left( \frac{d\vec{A}}{dt} \right)_{\text{inertial}} = \left( \frac{d\vec{A}}{dt} \right)_{\text{rot}} + \vec{\omega} \times \vec{A}. Applying this to the velocity \vec{v}_{\text{rot}} = \left( \frac{d\vec{r}}{dt} \right)_{\text{rot}} in the rotating frame yields the absolute velocity: \vec{v}_{\text{inertial}} = \vec{v}_{\text{rot}} + \vec{\omega} \times \vec{r}. To find the acceleration, differentiate \vec{v}_{\text{inertial}} again using the transport theorem. This involves the product rule for the cross product term: \frac{d}{dt} (\vec{\omega} \times \vec{r}) = \dot{\vec{\omega}} \times \vec{r} + \vec{\omega} \times \frac{d\vec{r}}{dt}. Substituting the rotating-frame derivative gives \vec{v}_{\text{inertial}} = \vec{v}_{\text{rot}} + \vec{\omega} \times \vec{r}, and differentiating leads to the full expression.[11] The resulting acceleration transformation is: \vec{a}_{\text{rot}} = \vec{a}_{\text{inertial}} - \dot{\vec{\omega}} \times \vec{r} - 2 \vec{\omega} \times \vec{v}_{\text{rot}} - \vec{\omega} \times (\vec{\omega} \times \vec{r}), where \vec{a}_{\text{rot}} is the acceleration measured in the rotating frame, \vec{v}_{\text{rot}} is the velocity in the rotating frame, and the terms represent the Euler acceleration -\dot{\vec{\omega}} \times \vec{r}, the Coriolis acceleration -2 \vec{\omega} \times \vec{v}_{\text{rot}}, and the centrifugal acceleration -\vec{\omega} \times (\vec{\omega} \times \vec{r}), respectively. The Euler term arises specifically from the time derivative of the angular velocity \vec{\omega}, capturing the effect of angular acceleration \dot{\vec{\omega}} on the position vector. Isolating this term, the Euler acceleration is -\dot{\vec{\omega}} \times \vec{r}, which, when multiplied by mass m, gives the Euler force \vec{F}_{\text{Euler}} = -m \dot{\vec{\omega}} \times \vec{r} in Newton's second law applied to the rotating frame.[12] This derivation assumes rigid-body rotation of the reference frame and treats the particle as a point mass with no extension, ensuring the cross-product terms apply directly to \vec{r}. For non-rigid bodies or frames with deformation, additional terms would be required to account for relative motions within the body.[1]Key Equations and Components
The Euler force \vec{F}_E in a rotating reference frame is expressed in vector form as \vec{F}_E = -m \dot{\vec{\omega}} \times \vec{r}, where m is the mass of the particle, \dot{\vec{\omega}} is the angular acceleration of the frame (the time derivative of the angular velocity \vec{\omega}), and \vec{r} is the position vector of the particle relative to the frame's origin.[1] This term arises as a fictitious force to account for the frame's changing rotation rate in the transformation between inertial and rotating coordinates.[13] The magnitude of the Euler force is given by F_E = m \dot{\omega} r \sin\theta, where \dot{\omega} = |\dot{\vec{\omega}}| is the magnitude of the angular acceleration, r = |\vec{r}| is the distance from the origin, and \theta is the angle between \vec{r} and \dot{\vec{\omega}}.[1] Its direction is perpendicular to the plane formed by \vec{r} and \dot{\vec{\omega}}, determined by the right-hand rule for the cross product.[1] In the equation of motion for a particle in the rotating frame, the Euler force appears alongside other terms as \vec{F} + \vec{F}_E + \vec{F}_\text{cent} + \vec{F}_\text{Cor} = m \vec{a}_\text{rot}, where \vec{F} is the net real force, \vec{F}_\text{cent} = -m \vec{\omega} \times (\vec{\omega} \times \vec{r}) is the centrifugal force, \vec{F}_\text{Cor} = -2m \vec{\omega} \times \vec{v}_\text{rot} is the Coriolis force, and \vec{a}_\text{rot} is the acceleration measured in the rotating frame.[1] This formulation allows Newton's second law to hold in the non-inertial frame by including these fictitious contributions.[13] The units of the Euler force are newtons (N), equivalent to kg·m/s², as confirmed by dimensional analysis: mass (m, kg) multiplies an acceleration-like term (\dot{\vec{\omega}} \times \vec{r}, with dimensions s⁻² · m = m/s², since radians are dimensionless).[1]Physical Interpretation and Applications
Relation to Other Fictitious Forces
The Euler force, centrifugal force, and Coriolis force are all fictitious forces that emerge in the analysis of motion within rotating reference frames, but they differ fundamentally in their origins and dependencies. The Euler force arises specifically from the angular acceleration \dot{\vec{\omega}} of the frame, manifesting as a tangential effect on objects regardless of their velocity in the frame. In contrast, the centrifugal force stems from the square of the angular velocity \vec{\omega}^2, producing a radial outward push on objects based on their position relative to the rotation axis, while the Coriolis force depends on the cross product of \vec{\omega} and the object's velocity \vec{v} in the frame, resulting in a deflection perpendicular to the motion. These distinctions highlight how the Euler force is transient and tied to changing rotation rates, whereas the centrifugal and Coriolis forces persist in uniformly rotating frames. A key unique aspect of the Euler force is that it vanishes when the angular acceleration is zero (\dot{\vec{\omega}} = 0), such as in constant-speed rotation, making it absent in steady-state scenarios where the centrifugal force remains active. Like the centrifugal force, the Euler force acts on objects that are stationary in the rotating frame (where \vec{v} = 0), but its transient nature—driven by \dot{\vec{\omega}} \times \vec{r}—sets it apart as a short-lived perturbation rather than a persistent influence. The Coriolis force, by comparison, only affects moving objects and does not contribute to stationary cases.| Force Name | Dependency | Direction |
|---|---|---|
| Euler force | \dot{\vec{\omega}} \times \vec{r} (angular acceleration and position) | Tangential, perpendicular to both \dot{\vec{\omega}} and \vec{r} |
| Centrifugal force | \vec{\omega} \times (\vec{\omega} \times \vec{r}) (angular velocity squared and position) | Radial outward, away from rotation axis |
| Coriolis force | $2 \vec{\omega} \times \vec{v} (angular velocity and relative velocity) | Perpendicular to both \vec{\omega} and \vec{v}, deflecting motion |