Newton's First Law of Motion, also known as the law of inertia, is a fundamental principle in physics that shapes our understanding of how objects behave when forces act upon them. Formulated by Sir Isaac Newton in the 17th century, this law states that an object will remain at rest or continue moving at a constant velocity unless acted upon by an external force. The concept of inertia, introduced in this law, describes the natural tendency of objects to resist changes in their state of motion. In simpler terms, objects do not change their speed or direction unless a force is applied. This principle is foundational in classical mechanics, the branch of physics concerned with the motion of objects and the forces that cause these motions. Newton's First Law is part of a larger framework known as Newton's Laws of Motion, which also include the Second and Third Laws, but it stands alone as an introduction to the relationship between forces and motion. The law provides a baseline for understanding how objects behave in the absence of external influences, allowing scientists to build more complex theories of motion. At its core, the First Law helps explain the concept of inertia. Inertia is the resistance of an object to any change in its state of motion. A stationary object, such as a book resting on a table, will not begin to move unless a force, like a push or pull, is applied to it. Similarly, an object in motion, like a car traveling down the highway, will continue moving at the same speed and direction unless an external force, such as friction or a braking system, alters its motion. The idea of inertia also extends to the concept of a "frame of reference" in physics. A frame of reference is a perspective from which motion is observed and measured. In an inertial frame of reference, objects that are not subjected to external forces will maintain constant motion. However, if you are observing motion from a non-inertial frame of reference, such as inside a car that is rapidly accelerating, objects may appear to move in ways that violate the First Law. This highlights the importance of choosing the correct frame of reference when analyzing motion. One of the most intuitive examples of Newton's First Law can be seen when driving in a car. If the car suddenly stops, your body will lurch forward, because your body was moving at the same velocity as the car before it came to a halt. In this case, your body’s inertia resists the change in motion, causing you to continue moving forward. This is why seat belts are essential in vehicles: they provide an external force to prevent you from continuing to move forward when the car stops abruptly. Newton's First Law also helps explain why it is so difficult to start or stop large objects. The larger an object’s mass, the greater its inertia, meaning it will be harder to change its state of motion. For example, pushing a heavy car is much harder than pushing a bicycle because the car has more mass, and therefore more inertia, resisting the force you apply. This principle is not just confined to everyday experiences but is crucial for understanding the movement of celestial bodies, such as planets and moons, in space. The law of inertia is vital in many aspects of modern physics, including space travel and satellite motion. In space, where friction and air resistance are minimal, objects like satellites continue to travel in a straight line at constant speed unless acted upon by an external force, such as gravity from a planet. This understanding is critical for engineers and astronauts when designing spacecraft and calculating their trajectories. The First Law makes it clear that without significant forces, such as gravity, an object will maintain its motion indefinitely. Another important aspect of Newton’s First Law is its role in simplifying the analysis of motion. In the absence of external forces, an object’s motion is predictable and straightforward. This allows scientists and engineers to calculate how objects will behave in a given environment. For instance, if you know the initial velocity and direction of an object in space, you can predict its motion with great precision, assuming no significant external forces act upon it. However, the First Law also has its limitations. It is most applicable in situations where external forces like friction, air resistance, and other interactions are negligible or absent. In the real world, such forces often play a significant role in motion. For example, on Earth, the presence of friction from the ground or air resistance causes most objects to eventually come to rest, even if no apparent force is applied. This is why, in everyday life, we rarely observe objects continuing indefinitely without external influence. Despite these limitations, Newton's First Law is a powerful tool in understanding the natural world and forms the bedrock for much of classical mechanics. It provides a clear and simple framework for analyzing how objects respond to forces, setting the stage for the more complex laws that govern motion. From the falling of an apple to the motion of planets around the sun, Newton’s First Law remains one of the most enduring and influential principles in physics. It is a testament to the way in which fundamental concepts can shape our understanding of the universe.
(Yeah, so this is about to take me a while to explain all of them) So number one, the whip, the whip is designed to double the amount of force put into the force of the whip, and as we know, force is equal to mass times acceleration, so the whip is designed to double the amount of force that you put into it, which is the first man made object to Surpass or break the sound barrier, which is the sound that you hear when cracking a whip Number two Yeah, so for number two I’m skipping that because yeah that ain’t physics is somebody knows what that is explain to me because yeah I don’t know Number three so the reason why the ball with the curved area went first to the end was because it’s curved area gave it more momentum, causing it to reach the end faster than the ball with a straight line Number four so for number four what practically happens but they don’t show it, but what practically happens in that video is that the man leaves one ball still and pushes the other one will not pushes it. He puts it at a certain angle and let it go and go in contact or the other one that is standing still the one that he let go because well can’t transfer. All of the energy only if the object has a greater mass than the object that he let go, and if he were to let go of both of them at the same time, the the same amount of energy would be let go of the both ball canceling our each other and meeting at the at the middle where they cancel out Number five number five what they do is practically they put a knife only the tip of the knife is in the potato so when the woman hits the top of the knife, she creates a friction, causing the potato to go up, not down Number six so the number six it’s just a lot of calculations to know which one you’re gonna hear which angle and romance are gonna have so you calculate I’m gonna force you need the angular momentum of the balls which is gonna hit you. Also once you get the angler momentum you need to hit the random amount of force which is practically next level to impossible, but it is possible Number seven so what is happening there is that the poop of the dog is sticking to the wall well, some of you might think that it’s because poop is sticky now is because the high attraction level of dog poop is practically attracting to the wall so now you know
The last 😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂🎉😂😂😂😂😂😂😂😂🎉😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂
Brw the works like the rope part is pretty big so when you swing it slows down cuz big part of rope but when it reaches the small part it turns into kenetic energy a ton of it
"Sir, you've been diagnosed with stage five cancer." " *Physics* " (yes,im desperate for likes because i'm posing this comment on every video he makes)
![ละลาย (LALALYE) - DAOU PITTAYA ต้าห์อู๋ พิทยา [OFFICIAL MV]](http://i.ytimg.com/vi/wo6r9TgausI/mqdefault.jpg)
Physics or history? 🧬 📃
history
i do kwon
ask the dog, he must know it after shitting on the wall xD
history
@@webcool4326 fack
wait a second, the last one got me💀💀
Lets go gambling🤓
@@jacob_hates_hidalgali aw, dang it 😞
The last one 💀
Physics on school:🙄🙄
Physics in TH-cam :🥶🥶
Clutchgod_077 in English class: 🗑️🗑️
PhSiCs In ShOrTs:*procedes to show SIMPLE science*
@@A6_Beats-777 I mean I got 20 likes sooo yeah imma fix it alr
@@ChickenBakeMan I don't know why you addressed it as simple science but i understand the grammar mistakes
first one scared the ancestor outta me
NAH-
@@DeziWorld3D it did my black ancestor jumped up
Can u Explain?
The liquid he punches is called oobleck, it’s a mixture of starch and water, it’s solid once force is applied to it, but is liquid when you be gentle
Newton's First Law of Motion, also known as the law of inertia, is a fundamental principle in physics that shapes our understanding of how objects behave when forces act upon them. Formulated by Sir Isaac Newton in the 17th century, this law states that an object will remain at rest or continue moving at a constant velocity unless acted upon by an external force. The concept of inertia, introduced in this law, describes the natural tendency of objects to resist changes in their state of motion. In simpler terms, objects do not change their speed or direction unless a force is applied.
This principle is foundational in classical mechanics, the branch of physics concerned with the motion of objects and the forces that cause these motions. Newton's First Law is part of a larger framework known as Newton's Laws of Motion, which also include the Second and Third Laws, but it stands alone as an introduction to the relationship between forces and motion. The law provides a baseline for understanding how objects behave in the absence of external influences, allowing scientists to build more complex theories of motion.
At its core, the First Law helps explain the concept of inertia. Inertia is the resistance of an object to any change in its state of motion. A stationary object, such as a book resting on a table, will not begin to move unless a force, like a push or pull, is applied to it. Similarly, an object in motion, like a car traveling down the highway, will continue moving at the same speed and direction unless an external force, such as friction or a braking system, alters its motion.
The idea of inertia also extends to the concept of a "frame of reference" in physics. A frame of reference is a perspective from which motion is observed and measured. In an inertial frame of reference, objects that are not subjected to external forces will maintain constant motion. However, if you are observing motion from a non-inertial frame of reference, such as inside a car that is rapidly accelerating, objects may appear to move in ways that violate the First Law. This highlights the importance of choosing the correct frame of reference when analyzing motion.
One of the most intuitive examples of Newton's First Law can be seen when driving in a car. If the car suddenly stops, your body will lurch forward, because your body was moving at the same velocity as the car before it came to a halt. In this case, your body’s inertia resists the change in motion, causing you to continue moving forward. This is why seat belts are essential in vehicles: they provide an external force to prevent you from continuing to move forward when the car stops abruptly.
Newton's First Law also helps explain why it is so difficult to start or stop large objects. The larger an object’s mass, the greater its inertia, meaning it will be harder to change its state of motion. For example, pushing a heavy car is much harder than pushing a bicycle because the car has more mass, and therefore more inertia, resisting the force you apply. This principle is not just confined to everyday experiences but is crucial for understanding the movement of celestial bodies, such as planets and moons, in space.
The law of inertia is vital in many aspects of modern physics, including space travel and satellite motion. In space, where friction and air resistance are minimal, objects like satellites continue to travel in a straight line at constant speed unless acted upon by an external force, such as gravity from a planet. This understanding is critical for engineers and astronauts when designing spacecraft and calculating their trajectories. The First Law makes it clear that without significant forces, such as gravity, an object will maintain its motion indefinitely.
Another important aspect of Newton’s First Law is its role in simplifying the analysis of motion. In the absence of external forces, an object’s motion is predictable and straightforward. This allows scientists and engineers to calculate how objects will behave in a given environment. For instance, if you know the initial velocity and direction of an object in space, you can predict its motion with great precision, assuming no significant external forces act upon it.
However, the First Law also has its limitations. It is most applicable in situations where external forces like friction, air resistance, and other interactions are negligible or absent. In the real world, such forces often play a significant role in motion. For example, on Earth, the presence of friction from the ground or air resistance causes most objects to eventually come to rest, even if no apparent force is applied. This is why, in everyday life, we rarely observe objects continuing indefinitely without external influence.
Despite these limitations, Newton's First Law is a powerful tool in understanding the natural world and forms the bedrock for much of classical mechanics. It provides a clear and simple framework for analyzing how objects respond to forces, setting the stage for the more complex laws that govern motion. From the falling of an apple to the motion of planets around the sun, Newton’s First Law remains one of the most enduring and influential principles in physics. It is a testament to the way in which fundamental concepts can shape our understanding of the universe.
The last one was so funny 😂
"don't pee on the wall"
Dog:alr I'll just ◼️ on the wall.
The dog poop: 💩
Physic in equilibrium
New Sub! 😮
ありがとうございます
Great song
Damn bro literally cross the limit
The last one💀
nice dog
(Yeah, so this is about to take me a while to explain all of them)
So number one, the whip, the whip is designed to double the amount of force put into the force of the whip, and as we know, force is equal to mass times acceleration, so the whip is designed to double the amount of force that you put into it, which is the first man made object to Surpass or break the sound barrier, which is the sound that you hear when cracking a whip
Number two
Yeah, so for number two I’m skipping that because yeah that ain’t physics is somebody knows what that is explain to me because yeah I don’t know
Number three so the reason why the ball with the curved area went first to the end was because it’s curved area gave it more momentum, causing it to reach the end faster than the ball with a straight line
Number four so for number four what practically happens but they don’t show it, but what practically happens in that video is that the man leaves one ball still and pushes the other one will not pushes it. He puts it at a certain angle and let it go and go in contact or the other one that is standing still the one that he let go because well can’t transfer. All of the energy only if the object has a greater mass than the object that he let go, and if he were to let go of both of them at the same time, the the same amount of energy would be let go of the both ball canceling our each other and meeting at the at the middle where they cancel out
Number five number five what they do is practically they put a knife only the tip of the knife is in the potato so when the woman hits the top of the knife, she creates a friction, causing the potato to go up, not down
Number six so the number six it’s just a lot of calculations to know which one you’re gonna hear which angle and romance are gonna have so you calculate I’m gonna force you need the angular momentum of the balls which is gonna hit you. Also once you get the angler momentum you need to hit the random amount of force which is practically next level to impossible, but it is possible
Number seven so what is happening there is that the poop of the dog is sticking to the wall well, some of you might think that it’s because poop is sticky now is because the high attraction level of dog poop is practically attracting to the wall so now you know
Nah "@daddy physics" is crazy💀💀
What my brain thinks of when im not paying attention for one sec in the exam
The last 😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😅😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂🎉😂😂😂😂😂😂😂😂🎉😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂😂
Physics is so cool
the last one 😂😂😂😂😂
The first one: get back to school, I said get back to school. You Moro-
Bro had the wrong type of masters degree 💀
Learning on school 🥱😮💨😑 learning on TH-cam 🥶😎🧐
Sir is strong 💪
Brw the works like the rope part is pretty big so when you swing it slows down cuz big part of rope but when it reaches the small part it turns into kenetic energy a ton of it
"He is walked"
-Physics
Daddy physics
Me who was waiting for the whole damn video for the main beat to come at Chemistry 💀
The last one w the dog.......😭😭😭😭
Physics in class😑
Physics in practical 👽☠️💀
Qual é a música por favor.
Untiled #13
Wow nice superb 🫰👏👏👏👏👏
С разноцветными шариками точно обман.
00:33 неньютоновская жидкость
Want 2 nd clip
Физичка с ножом,молотком и самое страшное с картошкой☠️
The coffee one confused me the most
second one was chemistry
My FREE ENERGY installation is also interesting
The ending...
Me takes a dump in the toilet
No one:
This guy: physics
Daddy physics
whats the song name
Slowed version of kerosene
Song?
"Sir, you've been diagnosed with stage five cancer."
" *Physics* "
(yes,im desperate for likes because i'm posing this comment on every video he makes)
100th comment, the last one though is a bit different
What name this song???
The slave pov:💀☠️
Is called science
The frist one is mitsuri sword bro
Link music 🤨🤨
Bolo physics mata ki JAI😂😂
Final bad dog😂
✋🏿👦🏿🤚🏿
uumm, why is "daddy physics" showing in back ground
Music?????
kerosene (slowed) --crystal castles
Sun💪
Last
Last one💀
did that dog poo on the wall!!?!??!?!?!
Türkiye as bayrakları as as
Last one😂😂😂
Chemistry x physics
DADDY PHYCHIS
why does he have a wip is my question
😮
good
2024😊 1900😢😢😢
Man the second one is not physics 😂😂😂😂
This broke my brain y'all 😮
poopy sticy dont u dare touch that poopy
Bro that woman with knife looks like a killer💀
G❤
What🙂😂
Oblek
Hyra>
the left arrow it on right and the right arrow is on the left
Non of these are actually physcics
idet
that's some extra sticky oobleck you got there :3
i'm sure some quicksand fetishists would love to be in some of that >:3c
Best Physics Man is prophets and IMAM ALI and his Ehlibeyt. just look.
Wow
Pin?
its not physics
Wtf is that dog doing with physics 🫣
Bad this is a fake😢
Poo poo
Just some arab things🗣🤌
(Second one)