Timestamps: 1:03 Moving charges & Magnetism 6:52 Oersted Experiment 11:20 Magnetic Field 12:30 Magnetic Force 22:12 Magnetic force on a current carrying conductor 31:55 Problem 1 35:59 Motion of a charged particle in Magnetic Field 43:20 Helical Motion 49:15 Biot-Savart law 58:18 Magnetic field due to straight current carrying conductor 1:08:10 Magnetic field due to circular loop 1:14:38 Problem 1 1:21:06 Problem 2 1:23:38 Ampere’s circuital law 1:27:03 Magnetic field due to straight current carrying conductor 1:32:24 Problem 1 1:40:39 Ampere’s circuital law 1:41:24 Solenoid 1:44:10 Solenoid:Magnetic field 1:50:37 Where do we use solenoids? 1:51:23 Problem 1 1:53:00 Problem 2 1:55:59 Force between parallel currents 2:09:28 Definition of Ampere 2:12:17 Torque on a current loop 2:31:34 Circular current loop as a magnetic dipole 2:38:46 Magnetic dipole vs. Electric dipole 44:53 Magnetic dipole moment of a revolving electron 2:39:50 Problem 1 2:42:03 Problem 2 2:44:01 Problem 3 2:46:13 Moving coil galvanometer 3:02:14 Galvanometer:Usage 3:02:33 Galvanometer as a detector 3:03:34 Galvanometer as Ammeter 3:12:39 Galvanometer as voltmeter thanks me later
1:03 Moving charges & Magnetism 6:52 Oersted Experiment 11:20 Magnetic Field 12:30 Magnetic Force 22:12 Magnetic force on a current carrying conductor 31:55 Problem 1 35:59 Motion of a charged particle in Magnetic Field 43:20 Helical Motion 49:15 Biot-Savart law 58:18 Magnetic field due to straight current carrying conductor 1:08:10 Magnetic field due to circular loop 1:14:38 Problem 1 1:21:06 Problem 2 1:23:38 Ampere’s circuital law 1:27:03 Magnetic field due to straight current carrying conductor 1:32:24 Problem 1 1:40:39 Ampere’s circuital law 1:41:24 Solenoid 1:44:10 Solenoid:Magnetic field 1:50:37 Where do we use solenoids? 1:51:23 Problem 1 1:53:00 Problem 2 1:55:59 Force between parallel currents 2:09:28 Definition of Ampere 2:12:17 Torque on a current loop 2:31:34 Circular current loop as a magnetic dipole 2:38:46 Magnetic dipole vs. Electric dipole 44:53 Magnetic dipole moment of a revolving electron 2:39:50 Problem 1 2:42:03 Problem 2 2:44:01 Problem 3 2:46:13 Moving coil galvanometer 3:02:14 Galvanometer:Usage 3:02:33 Galvanometer as a detector 3:03:34 Galvanometer as Ammeter 3:12:39 Galvanometer as voltmeter
{ HIGHLIGHTS OF THIS VIDEO👇} 00:03 Moving charges produce magnetic fields 02:36 Electricity and magnetism are closely related 07:06 When charges move, they produce a magnetic field. 09:49 Current-carrying conductor behaves like a magnet. 14:28 Exploring the mathematical definition of Lorentz Force and its implications 16:55 Moving charges experience magnetic force as a vector quantity. 21:22 The Unit of the magnetic field is Tesla 23:23 Understanding charge density and number density in a conductor 28:20 Current density (J) and its relationship with magnetic field (B) 30:38 Understanding the concept of the external magnetic field with a current-carrying rod. 35:10 Charged particles inside a magnetic field exhibit specific motions. 37:30 Understanding the interaction of magnetic fields on charged particles. 41:35 Charged particle motion in a magnetic field results in a spiral path 43:39 Understanding the concept of magnetic force on a charged particle moving in a circular path. 48:32 Explaining Byte Severt Law and its application in determining magnetic fields. 50:40 Understanding magnetic fields around current-carrying conductors 55:59 Byte Savat Law and its similarities with other laws 58:07 Understanding the magnetic field around a current carrying conductor 1:02:56 Discussing the angles and extremes of magnetic fields with a current carrying conductor 1:05:20 Discussing angles and directions with current flow 1:09:24 Understanding the impact of coil configuration on the magnetic field 1:11:40 Understanding how to calculate magnetic field strength around circular coils. 1:15:51 Explaining the effect of magnetic fields on a semi-circular coil 1:17:59 Determining magnetic field direction for different arcs 1:22:55 Explaining Ampere's Circuit Law and its relation to electrostatics 1:25:04 Understanding Ampere's Circuital Law in Detail 1:30:33 Magnetic field due to current-carrying conductor following cylinder symmetry. 1:32:53 Magnetic field calculation for different circles 1:37:30 Explanation of current distribution and Ampere's circuital law 1:39:56 Relationship between the magnetic field and current in a solenoid 1:45:05 Solenoids and magnetic fields 1:48:33 Understanding number density and direction using turns and current 1:53:27 Calculation of magnetic field inside a solenoid 1:56:31 Magnetic forces between current carrying conductors 2:01:24 Understanding the direction of force using the right-hand rule 2:03:41 Understanding the force and direction of the magnetic field on conductor B. 2:07:41 Explanation of the direction of magnetic field and current 2:10:09 Defining ampere through current flowing between conductors 2:14:38 Understanding the relationship between current, magnetic field, and force 2:16:30 Discussion on forces and torque in magnetic fields. 2:21:13 Understanding the direction of magnetic fields using the right-hand rule 2:23:20 Net force is zero but torque acts, leading to rotation. 2:27:50 Current loop experiences torque due to magnetic field. 2:30:36 Circular current loop behaves like a magnetic dipole 2:35:07 Derivation of magnetic field expression in a circular current loop 2:37:15 Understanding the relationship between electric and magnetic fields in circular current loops 2:41:30 Calculating magnetic moment and torque for a square coil 2:43:48 Calculating the force on a 10 cm section of wire. 2:48:27 When a current-carrying coil is placed in a magnetic field, it experiences torque and rotates, creating a pointer or needle-type effect. 2:50:24 Applying torque to a current-carrying coil leads to rotation due to the magnetic field. 2:54:55 Explaining Radial Magnetic Field Generation 2:57:05 Soft iron core enhances magnetic field strength 3:01:38 Galvanometer usage as a detector in circuits 3:03:33 A Galvanometer can be used as an ammeter with proper modifications. 3:07:26 Determining the value of shunt resistance for an ammeter. 3:09:33 Understanding the potential difference and current division in a parallel setup 3:14:21 Understanding voltage measurement using a galvanometer and resistor manipulation 3:16:20 Calibration of a galvanometer with a large resistor for voltage drop measurement 3:20:32 Understanding moving charges and magnetism theory with clarity {HOPE THIS WILL HELP🙂}
@@himanshumusicofficial3787 bro me muje pta hai. Lekin only video dakhne se kush ni hota. Khud revision karni padti hai Verna exam me sare formule bhul jate hai
Ma'am, plz share the information either at the beginning or at the end of the video because of it , it breaks our concentration. Otherwise your lectures are awesome.
2:11:53 You have made a mistake ma'am. If μ0/4π=10^-7 , then μ0/2π will be equal to 1/2 × 10^-7 But you have mistakenly written μ0/2π = 2 × 10^-7 , which is wrong !
Mam lot of thank you for you you are the best teacher in the world ❤😊 11th se aab thak aap ki hi vajah sa mein science mein hu super duper 😊 god always bless you mam❤
thankyou so much maám all of my doubts are cleared A great teacher inspires and motivates students, creating a positive and engaging learning environment. They are patient, understanding, and passionate about their subject, making even the most complex topics accessible and interesting. Effective teachers adapt their teaching methods to cater to diverse learning styles, ensuring every student can succeed. They foster critical thinking, creativity, and a love for learning, encouraging students to explore and grow. Additionally, they provide support and guidance, helping students navigate challenges both academically and personally. A great teacher leaves a lasting impact, shaping not only students' knowledge but also their character and future success.
chal jayga😀she explains well .But if you want then you can also se munil sir chanel he also explains well due to him I got good marks in physics and chemistry
@@Rifats12 rough overview ho skta hai lekin sb detail me padne ke liye nhi hai sufficient, revision ke liye hota hai one shot Tension mat le bro maine bhi nhi padha hai aur mera kal hi paper hai
Timestamps: 1:03 Moving charges & Magnetism 6:52 Oersted Experiment 11:20 Magnetic Field 12:30 Magnetic Force 22:12 Magnetic force on a current carrying conductor 31:55 Problem 1 35:59 Motion of a charged particle in Magnetic Field 43:20 Helical Motion 49:15 Biot-Savart law 58:18 Magnetic field due to straight current carrying conductor 1:08:10 Magnetic field due to circular loop 1:14:38 Problem 1 1:21:06 Problem 2 1:23:38 Ampere’s circuital law 1:27:03 Magnetic field due to straight current carrying conductor 1:32:24 Problem 1 1:40:39 Ampere’s circuital law 1:41:24 Solenoid 1:44:10 Solenoid:Magnetic field 1:50:37 Where do we use solenoids? 1:51:23 Problem 1 1:53:00 Problem 2 1:55:59 Force between parallel currents 2:09:28 Definition of Ampere 2:12:17 Torque on a current loop 2:31:34 Circular current loop as a magnetic dipole 2:38:46 Magnetic dipole vs. Electric dipole 44:53 Magnetic dipole moment of a revolving electron 2:39:50 Problem 1 2:42:03 Problem 2 2:44:01 Problem 3 2:46:13 Moving coil galvanometer 3:02:14 Galvanometer:Usage 3:02:33 Galvanometer as a detector 3:03:34 Galvanometer as Ammeter 3:12:39 Galvanometer as voltmeter
