Physics is tough 🤡 Physics is interesting 🗿

Everything is hard when you are lazy Everything is easy when you are crazy 😅

Physics also has some requirements:- 1st)- comman sense 2nd)-Imagination of physics 3rd)- understanding skills

Nothing is tough Everything is new

If you go in depth and understand its basics clearly then it become easy also interesting

IIT motivation ❎ IIT demotivation ✅

Physics may not be easy sometimes but is always very interesting

IMPOSSIBLE But I M POSSIBLE😈

🗣️: Physics Is Tough Saleemians : Really?

Physics is not hard maths is what it makes tough😊

This is Quantum physics bro Out of our Aukaat

Mujhe to physics simple hi lagti h kyuki me Motion se apni preparation kar rhi hu😍 #motionites

Physics is tough but interesting 😊😊

Bro The Fact is : TOUGH NAHI HAI, JUST NAYA HAI..!!🔥❤️😊

Physics ko dekhne se tough lagta lakin jab usse samjho ga to normal h

Forget physics The edit💀🔥🔥

If you even assume that Physics is boring, then you're a *criminal* ~ Prof. Walter Lewin Huge respect for Physics and its true preachers✨

Physics wahi jo diwana bna de

Le studenta after class 10 with the stream science ""aree ye toh hamare roj ka routine hai " 💀😅🗿

Quantum physics, also known as quantum mechanics, deals with the fundamental principles that govern the behavior of matter and energy on the smallest scales, such as atoms and subatomic particles. Here are some long-answer type questions that delve into various aspects of quantum physics: 1. Explain the concept of wave-particle duality. How does it manifest in both light and matter? In classical physics, light was thought to behave strictly as a wave (as in the wave theory of light), while matter was considered to consist of particles. However, quantum mechanics revealed that both light and matter can exhibit properties of both waves and particles, depending on how they are observed. Wave-particle duality of light: Describe experiments like the double-slit experiment, which demonstrates that light can behave like a wave, showing interference patterns. On the other hand, in the photoelectric effect (explained by Einstein), light is shown to behave as particles (photons), with quantized energy levels. Wave-particle duality of matter: Explain the de Broglie hypothesis, which suggests that particles such as electrons also have wave-like properties, as confirmed in experiments like the electron diffraction experiment. The answer should explore the historical development of these ideas and discuss their implications in quantum mechanics. 2. What is the Heisenberg Uncertainty Principle, and how does it challenge classical notions of determinism? The Heisenberg Uncertainty Principle states that certain pairs of physical properties, such as position and momentum, cannot be simultaneously measured with arbitrary precision. The more precisely one property is known, the less precisely the other can be known. This is not due to measurement limitations but is a fundamental property of quantum systems. Mathematical formulation: Provide the equation , where is the uncertainty in position, is the uncertainty in momentum, and is the reduced Planck’s constant. Implications for determinism: Discuss how the uncertainty principle refutes the classical idea of determinism, where the exact state of a system at one point in time determines its future behavior. In quantum mechanics, only probabilistic predictions can be made about a system’s future state. The answer should also address how this principle affects the interpretation of quantum systems and their measurement. 3. What is quantum superposition, and how is it demonstrated through Schrödinger's cat thought experiment? Quantum superposition is a fundamental principle that states a quantum system can exist in multiple states simultaneously until it is measured. When observed, the system collapses into one of the possible states. Schrödinger's cat: Explain how Erwin Schrödinger’s thought experiment illustrates the concept of superposition. The cat in a box is considered to be both alive and dead until the box is opened, representing a superposition of states. Mathematical description: Use the formalism of quantum mechanics to describe superposition states using wavefunctions. Implications for measurement: Discuss the role of measurement in collapsing a superposition and how this has led to different interpretations of quantum mechanics, such as the Copenhagen interpretation and the Many-Worlds interpretation. 4. Describe the process of quantum entanglement. How does it challenge classical notions of locality and realism? Quantum entanglement is a phenomenon where two or more particles become correlated in such a way that the state of one particle instantly determines the state of the other, regardless of the distance between them. This correlation persists even if the particles are separated by vast distances. EPR Paradox and Bell’s Theorem: Introduce the Einstein-Podolsky-Rosen (EPR) paradox, where Einstein argued that quantum mechanics must be incomplete due to what he called "spooky action at a distance." Discuss Bell’s theorem, which experimentally refuted the idea of hidden variables, showing that entanglement is a real quantum effect. Implications for locality and realism: Classical physics holds that information cannot travel faster than the speed of light (locality), and objects have definite properties independent of observation (realism). Entanglement defies both of these principles, challenging our understanding of the universe. The answer should also cover experimental confirmations of entanglement, such as Aspect's experiments, and how entanglement is used in modern technologies like quantum computing and quantum cryptography. 5. What is the role of the observer in quantum mechanics? Discuss the measurement problem and its possible interpretations. In quantum mechanics, the role of the observer is pivotal due to the measurement problem, which arises from the collapse of the wavefunction. Before measurement, quantum systems exist in a superposition of states. Upon measurement, the system "collapses" into a definite state, but the nature of this collapse is not fully understood. Copenhagen Interpretation: Describe this interpretation where the act of observation causes the wavefunction to collapse. Many-Worlds Interpretation: In contrast, this interpretation posits that all possible outcomes of a quantum event occur, but in separate, branching universes, avoiding the need for wavefunction collapse. Quantum decoherence: Explain how decoherence can be used to describe the transition from quantum superposition to classical states without invoking wavefunction collapse. The answer should also explore the philosophical implications of the measurement problem and the different interpretations of quantum mechanics. 6. How does quantum tunneling occur, and what are its real-world applications? Quantum tunneling is the phenomenon where particles can pass through a potential energy barrier that they classically should not be able to surmount due to insufficient energy. This is a purely quantum mechanical effect explained by the probabilistic nature of wavefunctions. Explanation of tunneling: Describe how the wavefunction of a particle extends through the barrier, giving a non-zero probability that the particle will appear on the other side. Mathematical description: Use Schrödinger’s equation to show how the probability of tunneling can be calculated. Applications: Discuss real-world applications of tunneling, such as semiconductor technology (in tunnel diodes), nuclear fusion (tunneling allows protons to overcome the Coulomb barrier in stars), and scanning tunneling microscopy (STM). These questions require deep understanding and offer opportunities to explain key concepts, mathematical formulations, and real-world applications of quantum mechanics.

Just prepare for olympaid , you will see the level of thoughness🥶

Utro kabhi physical pharmaceutical mai🔥

U r motivating us or demotivating us man..

Khatarnak 😊

In simple terms, anything can be hard until u try it. Just do it and you'll surely find it interesting and easy. Yeah it may be hard at first but that doesn't mean it's hard. To me, physics is one of the most interesting fields.

I take physics as a game

The fact that its the subject you can easily dominate from start if you work hard

Physics videos feel magical as they reveal the universe's hidden wonders.

To understand Physics there is needs of only one thing "brain"

Man scrolls, man see, man finds physics hard, man scroll, man forgets.... .Physics remains easy

Mujhe laga 2016 vala question dikhayga 😂😂😂

The principles and governing equations of quantum physics, which describe the behavior and interactions of matter and energy at the subatomic level. These laws include concepts such as wave-particle duality, uncertainty principle, quantization of energy levels, superposition, and entanglement. Each of these foundational ideas plays a crucial role in understanding phenomena that cannot be explained by classical physics, highlighting the complex and often counterintuitive nature of the quantum realm.

You found very easy and interesting with respected ❤❤ himanshu sir ❤ God of physics

Physics is interesting and logical ❤❤

Everything is easy when you know it

Everything is temporary until you are lazy Everything is easy when you are crazy❤

Its just a matter of understanding as long as you understand it will be easIER

Just have the courage and mindset of doing everything you achieve it

ab physics hi mera strongest subject h all thanks to NV sir

Physics is not hard it's interesting

If you Tell nursery class students That Nursery is easy But 1st class is🤯.....Of course he got feared So moral of Thought.......

Kuch bhe tough nahi hota , bass jab tum uske baare me complete information rakhoge tab wo aasan ho jata hai. For example: jab ham chote classes me hote hai tab ham sochte hai ki bhaiya log itne bade bade questions kaise karte hai😅 Phir jab ham uss class me pohonchte hain to wo bade bade questions easy lagne lagte hai . Waise he same jo jee advanced level ke questions karta hai toh uske liye wahi easy ho jata hai 😅

If we practice everyday everything in this world gets easier 😀😀

WE JUST MAKE IT TOUGH.. THATS IT !😂

Nice video

Hey Susy, you light up my world like nobody else 😉

Quantum physics (or quantum mechanics) is a fundamental theory in physics that describes the behavior of matter and energy on very small scales, typically at the level of atoms and subatomic particles. It represents a departure from classical physics and has radically changed our understanding of the physical world. Let's break down the key concepts of quantum physics in detail: 1. Wave-Particle Duality One of the core ideas in quantum physics is that particles such as electrons and photons (light particles) exhibit both wave-like and particle-like properties, depending on how they are observed. Particles: At one level, particles behave like discrete entities. For instance, an electron is often described as a "particle" with a specific position and momentum. Waves: At another level, particles like electrons can also exhibit wave-like behavior, such as interference and diffraction patterns. This was famously demonstrated in the double-slit experiment (more on this below). In this experiment, particles such as electrons or photons pass through two slits and create an interference pattern on a screen, similar to waves in water. However, when measured or observed, the particles behave like discrete objects. This duality is one of the most profound and puzzling features of quantum mechanics. 2. The Uncertainty Principle The Heisenberg Uncertainty Principle, formulated by Werner Heisenberg in 1927, states that it is impossible to simultaneously know certain pairs of properties of a particle with absolute precision. For example: You cannot know both the exact position and the exact momentum (mass times velocity) of a particle at the same time with perfect accuracy. The more precisely one of these quantities is measured, the less precisely the other can be known. This is not due to the limitations of measurement technology but rather a fundamental property of nature. This principle challenges the deterministic view of the universe that was prevalent in classical physics. 3. Superposition In quantum mechanics, particles like electrons do not have a single, well-defined state until they are measured. Instead, they exist in a superposition of all possible states. For example: An electron in an atom might not have a single position but instead be in a superposition of all possible positions around the nucleus. When a measurement is made (e.g., detecting the electron’s position), the superposition collapses, and the electron is found in one specific state (location, energy level, etc.). This is famously illustrated in the thought experiment known as Schrödinger's cat, where a cat in a sealed box is simultaneously in a state of being both alive and dead until it is observed. 4. Quantum Entanglement Quantum entanglement is another strange and non-intuitive feature of quantum mechanics. When two or more particles become entangled, their properties are linked in such a way that the state of one particle instantly affects the state of the other, regardless of the distance between them. This happens even if the particles are separated by vast distances (a phenomenon famously called "spooky action at a distance" by Albert Einstein). For example, if two entangled particles are created in a specific way, measuring one particle's spin will instantly determine the spin of the other, even if they are light-years apart. Entanglement has been experimentally confirmed, and it is at the heart of emerging quantum technologies, such as quantum computing and quantum cryptography. 5. Quantum Tunneling Quantum tunneling is a phenomenon where particles move through energy barriers that they classically should not be able to pass. This happens because of the wave-like nature of particles in quantum mechanics. The wave function (which describes the probability of a particle being in a particular state) can extend beyond a barrier, meaning there’s a nonzero probability that the particle will tunnel through the barrier. This effect is crucial in many processes, such as: Nuclear fusion in stars, including our Sun, where particles (such as protons) can overcome electrostatic repulsion due to quantum tunneling. Semiconductor devices like tunnel diodes and transistors rely on tunneling to work at very small scales. 6. Quantum States and the Schrödinger Equation In quantum mechanics, the state of a system (e.g., a particle) is described by a mathematical object called the wave function, typically denoted by the Greek letter Ψ (Psi). The wave function provides the probabilities of finding a particle in various positions, energies, and other properties. The wave function evolves over time according to the Schrödinger equation, which is a fundamental equation of motion in quantum mechanics. The equation is deterministic, meaning that if you know the wave function of a system at one point in time, you can predict how it will evolve. However, when you actually measure a quantum system, the wave function "collapses," and you obtain a specific outcome (such as finding a particle at a particular position). 7. Quantum Measurement and the Collapse of the Wave Function One of the most puzzling aspects of quantum mechanics is the role of measurement. Before measurement, particles exist in a superposition of states. However, when we measure them, the wave function "collapses" to a definite state. This process raises deep questions about the nature of reality and the role of the observer in determining physical outcomes. This is a central point in the famous Copenhagen interpretation of quantum mechanics, which proposes that the wave function describes the probabilities of outcomes, and it is only when we observe a quantum system that these probabilities become actualized as definite outcomes. However, there are other interpretations, such as the Many-Worlds Interpretation (which suggests that all possible outcomes of a quantum measurement actually occur, but in different "branches" or parallel universes) and the de Broglie-Bohm theory (which maintains determinism but with hidden variables). 8. Quantum Computing Quantum mechanics has led to the development of quantum computing, a new paradigm for computation that takes advantage of quantum bits (qubits). Unlike classical bits, which are either 0 or 1, qubits can exist in a superposition of both 0 and 1 simultaneously. This allows quantum computers to process an exponentially large number of possibilities at the same time, potentially solving certain problems far more efficiently than classical computers. Quantum computers also rely on quantum entanglement and quantum interference to perform computations in ways that classical computers cannot. While practical, large-scale quantum computing is still in the early stages, it holds promise for breakthroughs in fields such as cryptography, material science, and artificial intelligence. 9. Quantum Field Theory (QFT) Quantum Field Theory is the theoretical framework that combines quantum mechanics with special relativity. It treats particles as excited states of an underlying quantum field. Every type of particle is associated with a corresponding quantum field (e.g., the electron is associated with the electron field, the photon with the electromagnetic field). QFT underpins the Standard Model of particle physics, which describes the fundamental particles and forces (except gravity) in the universe. The interactions between particles are described as the exchange of force-carrying particles, such as photons for the electromagnetic force and gluons for the strong nuclear force. 10. Quantum Gravity and the Search for a Unified Theory Quantum mechanics works incredibly well for describing the behavior of small particles and fields. However, it has not yet been successfully combined with general relativity, Einstein’s theory of gravity. This is because general relativity describes gravity as the curvature of spacetime, while quantum mechanics deals with discrete particles and fields. The search for a theory of quantum gravity is one of the biggest open questions in physics. Two leading candidates for this unified theory are string theory and loop quantum gravity, but neither has been experimentally verified yet. Conclusion Quantum physics is a profound and often counterintuitive framework that governs the behavior of the microscopic world. It has not only reshaped our understanding of the universe at the smallest scales but has also led to groundbreaking technologies, including transistors, lasers, and quantum computers. Despite its successes, quantum mechanics raises deep philosophical and conceptual questions about the nature of reality, measurement, and the role of the observer. The journey to fully understand quantum mechanics is ongoing, and it continues to be a fascinating and evolving field of study. if you understand it its easy

Physics speaking. Thanks bro

It's easy and interesting if understand it well..... 😅😅

Imagination is everything!!

Those branch of physics are tough because of mathematics

Pov. student of 8 class got scared after watching this💀 tysm for demotivating me sir👁👄👁

Physics in 10th 🤡🤡🤡 Physics in jee 😈😱👽🙏 Physics in real life 💀☠️💀

Everything is hard when you are lazy Everything is easy when you are crazy

But Next topper Aarambh batch walo ke liye kuchh bhi imposible nahi ❤❤

It is really so eazy❤🎉❤🎉❤🎉😊

Song name???💀

I got goosebumps.. that’s how hard physics is!?

Nice edit ❤❤

*Physics is Easy* A sentence I have never heard in my life 💀

The phisycs aura♾️

Le me : jo abhi 7 ma ha or physics dekh rhi ah😂

If we understand it it is easy but of you learn it fir the sake of learning or practice the answer it is hard for you

Physics may or may not be easy but it is definitely interesting and if it's interesting it is not tough

Who thinks that physics is hard he need to know this one proverb"A bad working man always blame his tools."

MATH'S: 🗿

Physics hard reallyyy saleemians such batana ❤❤❤ saleemmmm sir alllllwayysssss opppppppppp.

Bro i am in fifth class 😂

Not Tough, Just New 🔥♥️😗

Mujhe to 11th class me hi physics tough lag rahi hai😢😢

Woww now students will do research in their school😮

Impossible also says I am possible 🗿

This is love❤

Mechanics in JEE also >>>>>

If u learn in a good way it os really very easy, you just need a good space where u think u can dive in this subject

Physics is interesting ❤❤❤no matter how hard it is physics is just amazing ❤

First we can learn and we known 👍👍👍

abhi mai 10th me hu koi batayega quantum physics hard hota h kya sochna padega science lena h ya nahi😂 ye reel dekh ke dar lag gaya

Bro forgot when thermo, thermal and heat transfer makes a trio and gives a question 🔥🔥🔥🔥

After watching this video,I get started studying

I'm here because I'm the 100th comment (i love physics) bye :)

Physics is tough and interesting💀

Everything is possible but,conditional.

I used to get D+ on physics exam

Bro no one says Physics is easy until they are crazy for that subject..

If you didn't do anything so everything is hard So, it depends

Physics is interesting with NV Sir @motionite🖤✨

Physics and maths is easy 😂 But chemistry is hard 😢

I search Physics zero to hero lecture ……. And I see This 😂

Dada,,,,for IIT ,,best class of KZbin?????????

Physics is my fav subj it's very interesting ❤

Yes physics is easy.... Unless you love or study

And still I love physics🙌

Easy hai bro mere liye toh💯

does quantum physics look like this pls tell me 😊

To be honest, jee adv physics is really much easy for a person who cracked inpho with top rank and got selected for camp of ipho. Yes I am that person...

Who is that person who said PHYSICS is EASY!!?☠️ He/She probably studying the spelling 👾

It's very interesting.my favorite.

Bro it is easy take interest in physics you will know about world it is very. Interesting

Im commenting on every video related to physics