Numerical Problems | Statistical Mechanics & Thermodynamics |Chapter 16 | Physics 12| LEC 5
Numerical Problems | Statistical Mechanics & Thermodynamics |Chapter 16 | Physics 12| LEC 5
#FederalBoard #ModelTownHumak #EducationalChannel #siranjumteaches #nationalbookfoundation
📚 Physics Class 12 – Chapter 16: Statistical Mechanics & Thermodynamics
🎓 Lecture 5: Solved Numerical Problems | Root Mean Square Speed & Related Concepts
📘 Textbook: National Book Foundation (NBF) | Board: FBISE
This lecture includes important numerical problems from Chapter 16 of Class 12 Physics. These questions help you understand the concept of root mean square speed, temperature dependence, gas molecule energy, and molecular count at STP. Each problem is solved step-by-step with full concept explanation.
🕐 Video Timestamps:
00:00 – RMS Speed of Helium at 15°C
→ Root mean square speed of helium atom (T = 15°C, m = 6.64×10⁻²⁷ kg)
03:02 – Temperature for RMS Speed Equal to Escape Velocity
→ Find temperature where RMS speed of oxygen equals Earth's escape velocity (v = 11.2 km/s)
06:40 – RMS Speed & Kinetic Energy at 400 K
→ Calculate RMS speed and kinetic energy of gas (T = 400 K, m = 6.4×10⁻²⁷ kg)
09:59 – Temperature for Double RMS Speed from 27°C
→ At what temperature does RMS speed become double of its value at 27°C?
15:25 – RMS Speed of Argon at 40°C
→ Root mean square speed of argon gas at 40°C (Molar mass = 39.95 g/mol)
18:10 – Number of Molecules in 1 m³ Gas at STP
→ Calculate number of gas molecules in 1 cubic meter at standard temperature and pressure (STP)
21:46 – RMS Speed & Pressure Comparison: Hydrogen vs Oxygen
→ Compare RMS speeds and pressures of H₂ and O₂ (same mass, different volumes)
📌 Learn the physics behind each formula:
* v_rms = √(3kT / m)
* Gas laws & kinetic theory in action
* Concepts of temperature, pressure, molar mass, and molecular count
🔔 Don’t forget to LIKE, COMMENT, SHARE, and SUBSCRIBE to _Sir Anjum Teaches_ for more board-focused Physics lectures!
Keywords:
statistical mechanics
thermodynamics physics 12
physics 12 chapter 16
federal board physics
national book foundation physics 12
statistical mechanics and thermodynamics
ideal gas law
pv = 1/3nm(c^2)
root mean square speed
mean square speed of gas
kinetic theory of gases
translational kinetic energy of gas
rms speed derivation
pv = 1/3nmv^2 derivation
molecular motion and pressure
kinetic molecular theory
ideal and non ideal gases
behavior of real gases
non ideal gases
gas pressure due to molecular motion
degenerate matter
neutron stars and degenerate matter
neutron degenerate matter
white dwarfs and neutron stars
boson and fermion gases
bose-einstein condensate
superconductivity and superfluidity
quantum states of matter
unusual states of matter
bose einstein condensates
degenerate gas in astrophysics
stars and statistical mechanics
statistical mechanics model
pv = 1/3Nm(c^2)
microscopic theory of gases
gas laws from molecular model
average kinetic energy of gas
superfluidity in quantum physics
superconductivity phenomenon
ideal gas assumptions
kinetic energy of molecules
pressure in terms of kinetic energy
microscopic model of pressure
statistical physics class 12
chapter 16 physics 12 fbise
physics 12 federal board
physics 12 nbf
nbf physics class 12
chapter 16 kinetic theory
gas laws derivation
mean square speed and pressure
rms speed and temperature
ideal gas equation explained
statistical mechanics introduction
ideal gas behavior
quantum mechanics and gas theory
physics of stars and gases
physics 12 thermodynamics
physics 12 statistical mechanics
fbise class 12 physics chapter 16
✅ 📛 Hashtags:
#Physics12 #Thermodynamics #StatisticalMechanics #RMSspeed #FBISE #Class12Physics #Chapter16Physics #GasLaws #MolecularSpeed #PhysicsNumericals #BoardExamPrep #PhysicsLecture #NBFPhysics
Видео Numerical Problems | Statistical Mechanics & Thermodynamics |Chapter 16 | Physics 12| LEC 5 канала SIR ANJUM TEACHES
#FederalBoard #ModelTownHumak #EducationalChannel #siranjumteaches #nationalbookfoundation
📚 Physics Class 12 – Chapter 16: Statistical Mechanics & Thermodynamics
🎓 Lecture 5: Solved Numerical Problems | Root Mean Square Speed & Related Concepts
📘 Textbook: National Book Foundation (NBF) | Board: FBISE
This lecture includes important numerical problems from Chapter 16 of Class 12 Physics. These questions help you understand the concept of root mean square speed, temperature dependence, gas molecule energy, and molecular count at STP. Each problem is solved step-by-step with full concept explanation.
🕐 Video Timestamps:
00:00 – RMS Speed of Helium at 15°C
→ Root mean square speed of helium atom (T = 15°C, m = 6.64×10⁻²⁷ kg)
03:02 – Temperature for RMS Speed Equal to Escape Velocity
→ Find temperature where RMS speed of oxygen equals Earth's escape velocity (v = 11.2 km/s)
06:40 – RMS Speed & Kinetic Energy at 400 K
→ Calculate RMS speed and kinetic energy of gas (T = 400 K, m = 6.4×10⁻²⁷ kg)
09:59 – Temperature for Double RMS Speed from 27°C
→ At what temperature does RMS speed become double of its value at 27°C?
15:25 – RMS Speed of Argon at 40°C
→ Root mean square speed of argon gas at 40°C (Molar mass = 39.95 g/mol)
18:10 – Number of Molecules in 1 m³ Gas at STP
→ Calculate number of gas molecules in 1 cubic meter at standard temperature and pressure (STP)
21:46 – RMS Speed & Pressure Comparison: Hydrogen vs Oxygen
→ Compare RMS speeds and pressures of H₂ and O₂ (same mass, different volumes)
📌 Learn the physics behind each formula:
* v_rms = √(3kT / m)
* Gas laws & kinetic theory in action
* Concepts of temperature, pressure, molar mass, and molecular count
🔔 Don’t forget to LIKE, COMMENT, SHARE, and SUBSCRIBE to _Sir Anjum Teaches_ for more board-focused Physics lectures!
Keywords:
statistical mechanics
thermodynamics physics 12
physics 12 chapter 16
federal board physics
national book foundation physics 12
statistical mechanics and thermodynamics
ideal gas law
pv = 1/3nm(c^2)
root mean square speed
mean square speed of gas
kinetic theory of gases
translational kinetic energy of gas
rms speed derivation
pv = 1/3nmv^2 derivation
molecular motion and pressure
kinetic molecular theory
ideal and non ideal gases
behavior of real gases
non ideal gases
gas pressure due to molecular motion
degenerate matter
neutron stars and degenerate matter
neutron degenerate matter
white dwarfs and neutron stars
boson and fermion gases
bose-einstein condensate
superconductivity and superfluidity
quantum states of matter
unusual states of matter
bose einstein condensates
degenerate gas in astrophysics
stars and statistical mechanics
statistical mechanics model
pv = 1/3Nm(c^2)
microscopic theory of gases
gas laws from molecular model
average kinetic energy of gas
superfluidity in quantum physics
superconductivity phenomenon
ideal gas assumptions
kinetic energy of molecules
pressure in terms of kinetic energy
microscopic model of pressure
statistical physics class 12
chapter 16 physics 12 fbise
physics 12 federal board
physics 12 nbf
nbf physics class 12
chapter 16 kinetic theory
gas laws derivation
mean square speed and pressure
rms speed and temperature
ideal gas equation explained
statistical mechanics introduction
ideal gas behavior
quantum mechanics and gas theory
physics of stars and gases
physics 12 thermodynamics
physics 12 statistical mechanics
fbise class 12 physics chapter 16
✅ 📛 Hashtags:
#Physics12 #Thermodynamics #StatisticalMechanics #RMSspeed #FBISE #Class12Physics #Chapter16Physics #GasLaws #MolecularSpeed #PhysicsNumericals #BoardExamPrep #PhysicsLecture #NBFPhysics
Видео Numerical Problems | Statistical Mechanics & Thermodynamics |Chapter 16 | Physics 12| LEC 5 канала SIR ANJUM TEACHES
Root Mean Square Speed RMS speed Physics Class 12 Chapter 16 Physics Thermodynamics Statistical Mechanics Kinetic Theory of Gases Numerical Problems Physics Numericals Class 12 Thermodynamics FBISE Physics NBF Book Physics Velocity of Gas Molecules Molar Mass and Speed Kinetic Energy Escape Velocity STP Gas Molecules Oxygen Molecule Argon RMS Speed Gas Properties Pressure Comparison Temperature and Speed
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24 июня 2025 г. 6:45:04
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