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Maxwell's equations are a set of fundamental equations in classical electromagnetism that describe the behavior of electric and magnetic fields and their interactions with charges and currents. They were formulated by James Clerk Maxwell in the 19th century and played a crucial role in unifying the understanding of electricity, magnetism, and light. The four Maxwell's equations are: 1. Gauss's Law for Electric Fields: This equation relates the electric flux through a closed surface to the total electric charge enclosed within that surface. It states that the electric flux out of any closed surface is proportional to the total electric charge enclosed by that surface. ∮E · dA = (1/ε₀) ∫ρ dV where E is the electric field, dA is an infinitesimal area vector on the closed surface, ε₀ is the permittivity of free space, ρ is the charge density, and the integrals are taken over the closed surface and the volume enclosed by it, respectively. 2. Gauss's Law for Magnetic Fields: This equation states that the magnetic field lines are always closed loops, and there are no magnetic monopoles (isolated magnetic charges). It relates the magnetic flux through a closed surface to the absence of magnetic monopoles. ∮B · dA = 0 where B is the magnetic field and the integral is taken over a closed surface. 3. Faraday's Law of Electromagnetic Induction: This equation describes how a changing magnetic field induces an electric field. It states that the electromotive force (EMF) around a closed loop is equal to the negative rate of change of magnetic flux through that loop. ∮E · dl = - dΦB/dt where E is the electric field, dl is an infinitesimal vector element along the closed loop, dΦB/dt is the rate of change of magnetic flux through the loop, and the integral is taken around the closed loop. 4. Ampere's Law with Maxwell's Addition: This equation relates the circulation of the magnetic field around a closed loop to the sum of the conduction current and the displacement current passing through the loop. The displacement current accounts for the time-varying electric fields and is a modification made by Maxwell. ∮B · dl = μ₀ (I_c + ε₀ dΦE/dt) where B is the magnetic field, dl is an infinitesimal vector element along the closed loop, I_c is the conduction current passing through the loop, dΦE/dt is the rate of change of electric flux through the loop, μ₀ is the permeability of free space, ε₀ is the permittivity of free space, and the integral is taken around the closed loop. These four equations, together with appropriate boundary conditions, form a complete set of equations that describe the behavior of electric and magnetic fields, their generation, propagation, and interaction with charges and currents. They are fundamental to the understanding of classical electromagnetism and have had profound implications in various areas, including the development of telecommunications, electronics, and the theory of light.
Dear sir ! Aaj mera b.sc ka result aya hai or mai physics mai boht ache number k sath pass ho gya hun... Ye sabh aap ki kirpa ki vjhan se hua hai ... Mere pas labhj nhi hai aapko sukhriya khne k liye 🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏 Thankyou so much sir g 💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙
Waah.... Aap se acha EMT koi kya padhaega... Itne difficult subject pe kitni achi command hai aapki aur kitna smoothly and in such a easy way me padhate ho aap.... And most importantly aapne Jo inke application ki baat kahi wo bada acha laga because kisi bhi college school ya coaching me sirf marks and how to solve the problem bas ispe dhyan diya jata hai... Maine aaj tak kisi bhi faculty ko applications ki baat karte nahi dekha (especially in this subject and in mathematics)... But u know what u r teaching and why it is necessary to be known.. Thank you sir.
Sir I am very much impressed by your explanation. I am studying B.E civil from Tribuvan University . I would like you to make video on charging and discharging of capacitor
Sir please make a video on physical interpretation of wave function, only this topic is not there on your yt channel for quantum mechanics,rest all exists
Thank you soo much sir, Sir can you upload ''tuned collector oscillation'' nd ''Wien- Bridge oscillator'' please if you will upload then as soon as possible.
Ham ICFAI University,Tripura se hu sir....mujhe electrodynaics ke bare me ek detail vedio dekhna he...plz isko leke ek vedio banie...me Msc physics ka hu
Sir is question pr video bnaeea plzz obtain maxwell law of distribution of velocity for the molecules of gas with velocities range C and C+dC plzz sir help me
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@technical physics jrur sir please aap questions papers serious chalaye
Sir displacement current par ek vedio banaye
Sir schrodinger equations 3daimention bsc second year ka ek vedio bna dijiye
👍
Done sir
Watching from NIT Agartala😊
Sir you are a wonderful teacher . Because of you I will scored 80 - 90 marks in physics btech 1year exam .
Thank you so much sir ☺️☺️☺️
Aktu main ?
@@varunthakkar6349 ktau anim
Hii bro
Have u scored 😂
Maxwell's equations are a set of fundamental equations in classical electromagnetism that describe the behavior of electric and magnetic fields and their interactions with charges and currents. They were formulated by James Clerk Maxwell in the 19th century and played a crucial role in unifying the understanding of electricity, magnetism, and light.
The four Maxwell's equations are:
1. Gauss's Law for Electric Fields:
This equation relates the electric flux through a closed surface to the total electric charge enclosed within that surface. It states that the electric flux out of any closed surface is proportional to the total electric charge enclosed by that surface.
∮E · dA = (1/ε₀) ∫ρ dV
where E is the electric field, dA is an infinitesimal area vector on the closed surface, ε₀ is the permittivity of free space, ρ is the charge density, and the integrals are taken over the closed surface and the volume enclosed by it, respectively.
2. Gauss's Law for Magnetic Fields:
This equation states that the magnetic field lines are always closed loops, and there are no magnetic monopoles (isolated magnetic charges). It relates the magnetic flux through a closed surface to the absence of magnetic monopoles.
∮B · dA = 0
where B is the magnetic field and the integral is taken over a closed surface.
3. Faraday's Law of Electromagnetic Induction:
This equation describes how a changing magnetic field induces an electric field. It states that the electromotive force (EMF) around a closed loop is equal to the negative rate of change of magnetic flux through that loop.
∮E · dl = - dΦB/dt
where E is the electric field, dl is an infinitesimal vector element along the closed loop, dΦB/dt is the rate of change of magnetic flux through the loop, and the integral is taken around the closed loop.
4. Ampere's Law with Maxwell's Addition:
This equation relates the circulation of the magnetic field around a closed loop to the sum of the conduction current and the displacement current passing through the loop. The displacement current accounts for the time-varying electric fields and is a modification made by Maxwell.
∮B · dl = μ₀ (I_c + ε₀ dΦE/dt)
where B is the magnetic field, dl is an infinitesimal vector element along the closed loop, I_c is the conduction current passing through the loop, dΦE/dt is the rate of change of electric flux through the loop, μ₀ is the permeability of free space, ε₀ is the permittivity of free space, and the integral is taken around the closed loop.
These four equations, together with appropriate boundary conditions, form a complete set of equations that describe the behavior of electric and magnetic fields, their generation, propagation, and interaction with charges and currents. They are fundamental to the understanding of classical electromagnetism and have had profound implications in various areas, including the development of telecommunications, electronics, and the theory of light.
Thanks helped me a lot along with the video.
@@aditisingh3483Ur welcome
thankyou
Best physics teacher I have ever seen on RUclips
Thank you so much sir
Dear sir ! Aaj mera b.sc ka result aya hai or mai physics mai boht ache number k sath pass ho gya hun... Ye sabh aap ki kirpa ki vjhan se hua hai ... Mere pas labhj nhi hai aapko sukhriya khne k liye
🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏🙏
Thankyou so much sir g
💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙💙
Waah.... Aap se acha EMT koi kya padhaega... Itne difficult subject pe kitni achi command hai aapki aur kitna smoothly and in such a easy way me padhate ho aap.... And most importantly aapne Jo inke application ki baat kahi wo bada acha laga because kisi bhi college school ya coaching me sirf marks and how to solve the problem bas ispe dhyan diya jata hai... Maine aaj tak kisi bhi faculty ko applications ki baat karte nahi dekha (especially in this subject and in mathematics)... But u know what u r teaching and why it is necessary to be known.. Thank you sir.
Seeing this video from IIT 😊
most welcome
I have completed my engineering few years back, I don't know why am here but I wish we had sir like him in our college.
Bhai aapa kya karre hoo ith🤔🙂
Excellent explanation of physics through Mathematics.
Sir ,you are great teacher in the world...any quality of student can learn from you becz you teach us from basic....
Now watching this awesome video after 4 yrs. From mp Jiwaji University
All students welcome @shailybaghel2933 mp Jiwaji University
Amazing sir ....aap se acha koi ni h youtube par .
Thank you sir
I am from Nepal
I study in Tribhuvan University
B.E in electrical engineering
Kun college ho bro?
Thank you so much sir. Because of your physics playlist, I was able to secure 96 in my sem finals.
Funny how I don’t understand India but I understood this a 100% . Thank you
RUclips me sabse best video 🎈🎈😍😍
thanks a lot sir ............................ i m so lucky for teaching from u ......😊👍👍👍👍👌👌👌👌🙌👧👧
B.s.c.final year ki math ki video banayie
This channel needs 1 million😊
Thank you Sir. Although I do not understand Hindi, I got the lecture 100%. Great lecturer indeed!
Hats off to u
Wah sir kitne ache hai aap
Lakshman Perera lol me too
It is helpful for Electrical Engineering aspirants also, I'm an Electrical Engineer🙏
Best lecture ❤️and best teacher for enginnering physics 🙏
Sir mai BTech 2nd year electrical engineering kar raha hu.
Aapka ye video mere liye bhut helpful raha
Excelent teaching level....now I have got cleared this concept sir👌👌👌🙏🙏🙏👏👏👏👍👍👍
Very very good sir...
From B R A B U university Muzaffarpur Bihar
*yeah ! i have subscribed ur on recommandation of manisha marwaha didi* 😊😊😊
Thanks for you sir ji ❤
Love the way of your teaching sir ❤️
Explain tecnic is awesome. Everything is clear when the video ended.
Wish you all the best
Share channel link among your friends a
Sir please make a series of general relativity
Yes plz sir
Hey l lawlight
Bhai agar apne notes bnne ho to send krdo
Aktu
Uptu
Thank you so much sir.very well explained
From VIT Vellore❤
video start at 3:30
Sir I am very much impressed by your explanation. I am studying B.E civil from Tribuvan University . I would like you to make video on charging and discharging of capacitor
Tribhuwan university from Nepal sir!!
pokhara university🙏
sir aap bhut acha pdhate ho kass apke jysa mere collage me bhi pdhate tab sab kuch samajh me aata
Sir your teaching style is awesome thank you for your efforts
❣️❣️❣️❣️Thankyou sir mere bahut sare doubts clear ho gye.....
sir maxwell velocity distribution law pe koi video bayayiye plzz
Sir please make a video on physical interpretation of wave function, only this topic is not there on your yt channel for quantum mechanics,rest all exists
welcome
Watching from nit hamirpur ❤
Topic- Time dependent perturbation theory
University- ALIAH UNIVERSITY, KOLKATA
Is topic k upar er video chaiye sir...... As quickly as possible.
Waching from IIT dholakpur❤❤
Suggest to change your pic for more attraction to subscribers
Sir please make for IGDTUW college , our college is waiting for your videos ❤
Thank u sir ❤️ Your teaching skill is amazing.
Thanks 👍
Wow, excellent way of teaching sir,, seeing this video in patna,,(MSC-2d sem)
Thanks for lecture
Sir Mai Allahabad university se hu aapke video bahut helpful hai
Sir we need Schrödinger wave equation,please make a video on it
Thank you sir msc physics 1st year student, beautiful teaching
You are really awesome sir 💯 God bless you sir 💯💯💯
i was searching for this kind of neat and clean video
Thank you
lovely professional university in jhalandhar
Most welcome
JNU Delhi
Sir watch lot of videos but the way u teach is really appreciated. Thank you very much.
This channel Recommend by Ajay raj and DTU students. Totally worth it 🍷
Great way of teaching sir I wish this channel grows more ...
Sir aapka video dekh ke bohot accha lagta hai.
Thank you soo much sir,
Sir can you upload ''tuned collector oscillation'' nd ''Wien- Bridge oscillator'' please if you will upload then as soon as possible.
Hi
Hello
well explained sir , i am from HBTU kanpur
De-ringing of integral signs is necessary in the surface integrals of the last two equations (Maxwell's 3rd and 4th}.
what bro I can't understood? I think has given on 3rd but note given on 4th
Very helpful sir
Nice
Thankyou sir aap mast padhte ha bas aapkee vajhs se pass ho gaye hum aur ache number aaye ha thankyou so much sir
Vellore institute of technology 🎯
Welcome
watching from NIT
Poynting theorem for dispersive medium b upload kr dan sir plzzzzz
Thanks very much for the uploading video
Sir concept of displacement current ko capacitance and resistance ke form ispe video banayiye please
lots of love to u sir
ur vidoes are extremly good , I have shared with alll my friends and now my entire college watches your videos
Ham ICFAI University,Tripura se hu sir....mujhe electrodynaics ke bare me ek detail vedio dekhna he...plz isko leke ek vedio banie...me Msc physics ka hu
Thank you sir, mere doubt clear ho gaya
Thankyou sir for an excellent explanation
And Sir can you please make a playlist on CRYSTAL STRUCTURE AND SEMICONDUCTOR
Thank you so much sir 🙏🏻🙏🏻🙏🏻 just because you I can get good marks in university exam .....Thank you co much
Sir.... AKU bihar ke syllabus se kuch btaea ....wave and optics se ...plzzzz🙏🙏🙏🙏
very nice sir..
love from NIT agartala
Classical electrodynamics and special theory of relativity
kl st1 h aur aaj pdhna start krunga😎
Sir time varying field or static field me point and integral form batao
I am from BTech first year student ...... thank you sir
Sir is question pr video bnaeea plzz obtain maxwell law of distribution of velocity for the molecules of gas with velocities range C and C+dC plzz sir help me
Excellent way of teaching.. Thank you so much Sir🙏
Sir electrostatics ka 👉electric field intensity due to dipole at perpendicular bisector 🙋uska bhi ek video please 🙏
Top level ❤❤❤ teaching skill sir 💪💪 so thanks sir..want more vedio
Sure 👍
your video seem really cool, but if you make it in English, I will be able to understand it as well.
Best explanation sirr😊😊😀
Hello Sir I love ur techniques of teaching ☺️... Can u plz discuss about concept of Retarded Potential plz sir ....
Sir Galilean Transformation prr video bnado *punjabi university patiala*
Sir u r great i am pakistani you explain very well
Jo IIT dholakpur me padhta hai vo attendance de 🤪🤪😂😂🤣🤣
Sir app kya mere liye Maxwell's displacement current ak video bana sakte hai
Integral kaa 3 form closed integral wrong had,yaa mistake hai
Sir app bhot achha samjhate ho 😊😊
Rajasthan university i am ankit kumar meena sir please make a video electric field in matter
It is very helpful for me thank you sir very much
Most welcome
dr abdul kalam technical university lucknow
Hi Sir best depth of knowledge
Electrostatic .. and bsc 2nd year , 3 and 4 sem
Sir as read in book Displacement density vector is equal to rho plus polarization vector