bend to the right of their motion
All motion in the northern hemisphere is deflected to the right by the coriolis force.
All motion in the Southern Hemisphere is deflected to the left by the coriolis force.
Think of it this way. You're riding along on the equator. When you start to fly north, your speed doesn't change, but you are going faster than the ground underneath you, so you end up east of your original meridian, which is a deflection to the right.
Heading the other way is left as an exercise to the reader.
It's called the 'Coriolis effect'. In the northern hemisphere, they rotate clockwise. South of the equator, they rotate counter-clockwise.
By, instead of a straight current, makes the current curved due to the Coriolis Effect.
The coriolis effect makes ocean currents move in a curved path.
For anything small (like a bathtub), it doesn't - that's an urban legend. The theory is that coriolis forces makes water swirl one way in one hemisphere and the opposite way in the other - but that force is quite utterly negligable on small amounts of liquid or gas - such as your bathtub. The effect DOES work at the scale of ocean currents and hurricanes. Hurricanes in the northern hemisphere rotate counterclockwise, those in the southern hemisphere (which are properly called "Typhoons") rotate clockwise. The coriolis force comes about because the earth rotates. If you think about a wind blowing south from somewhere far into the northern hemisphere, as the wind travels southwards, the planet rotates from west to east causing the air to be spun around in a counter-clockwise direction. The opposite happens in the southern hemisphere.
okay idk how you don't know this but hemispheres are the quadrants of the equator and the meridian something (the line that runs vertically on the earth) so the equator isn't located in a hemisphere bc it makes the hemispheres
Then to the right of their motion
bend to the right of their motion
The coriolis effect makes ocean currents move in a curved path.
The Coriolis effect makes the air turn clockwise.
The Coriolis Effect.
It's called the 'Coriolis effect'. In the northern hemisphere, they rotate clockwise. South of the equator, they rotate counter-clockwise.
There is no theorem named the Coriolis theorem. However, there is the Coriolis effect, which is an inertial force that acts on objects that are in motion relative to a rotating reference frame. The Coriolis effect is what causes objects to deflect to the right in the Northern Hemisphere and to the left in the Southern Hemisphere. [Image of Coriolis effect] The Coriolis effect is named after Gaspard-Gustave de Coriolis, a French mathematician and engineer who first described it in 1835. Coriolis was working on the theory of water wheels when he realized that the rotation of the Earth would cause objects to deflect in different directions depending on their latitude. The Coriolis effect is responsible for a number of natural phenomena, including the direction of ocean currents and the movement of weather systems. It is also used in a number of engineering applications, such as gyroscopes and navigation systems. Here are some examples of how the Coriolis effect is at work in the world around us: **Ocean currents:** The Coriolis effect causes ocean currents to deflect to the right in the Northern Hemisphere and to the left in the Southern Hemisphere. This is why the Gulf Stream, which flows from the Gulf of Mexico to Europe, curves to the east as it crosses the Atlantic Ocean. [Image of Gulf Stream in the Atlantic Ocean] **Weather systems:** The Coriolis effect also affects the movement of weather systems. For example, the Coriolis effect causes hurricanes to spiral counterclockwise in the Northern Hemisphere and clockwise in the Southern Hemisphere. **Gyroscopes:** Gyroscopes use the Coriolis effect to maintain their orientation. A gyroscope is a spinning wheel that is mounted in a way that it can rotate freely about two axes. The Coriolis effect causes the gyroscope to resist any change in its orientation. This makes gyroscopes very useful for navigation and stabilization. **Navigation systems:** Navigation systems, such as the Global Positioning System (GPS), use the Coriolis effect to calculate their position. GPS satellites emit signals that are used to calculate the distance between the satellite and the receiver. The Coriolis effect causes the signals to be slightly curved, and this curvature can be used to calculate the receiver's latitude and longitude. The Coriolis effect is a complex phenomenon, but it is one that has a profound impact on the world around us. By understanding the Coriolis effect, we can better understand the forces that shape our planet and the systems that we rely on every day.
For tropical storms, the Coriolis effect causes the rotation of the storm because of the rotational force of the Earth relative to the position on the storm. This force makes an equilibrium with the pressure gradient force caused by low-pressure in storms. In the Northern Hemisphere, this causes storms to rotate clock-wise; in the Souther Hemisphere, this causes storms to rotate counter-clockwise. Wind Direction
By, instead of a straight current, makes the current curved due to the Coriolis Effect.
The coriolis effect makes ocean currents move in a curved path.
The hemisphere you are in (northern or southern) has an effect on when you experience the seasons. At points in the earth's orbit it is either the southern or northern hemisphere that is tilted further towards the sun. This makes that hemisphere warmer, experiencing summer while the other colder and experiences winter. Then six months later, things are reversed.
Currents to bend to the right in the Northern Hemisphere