Non-equilibrium thermodynamics
A two-dimensional gas is a collection of objects constrained to move in a planar or other two-dimensional space in a gaseous state. The objects can be: classical ideal gas elements such as rigid disks undergoing elastic collisions; elementary particles, or any ensemble of individual objects in physics which obeys laws of motion without binding interactions. The concept of a two-dimensional gas is used either because: 1. * the issue being studied actually takes place in two dimensions (as certain surface molecular phenomena); or, 2. * the two-dimensional form of the problem is more tractable than the analogous mathematically more complex three-dimensional problem. While physicists have studied simple two body interactions on a plane for centuries, the attention given to the two-dimensional gas (having many bodies in motion) is a 20th-century pursuit. Applications have led to better understanding of superconductivity, gas thermodynamics, certain solid state problems and several questions in quantum mechanics. (Wikipedia).
Physics - Thermodynamics: States: (5 of 10) Ideal Gas Equation
Visit http://ilectureonline.com for more math and science lectures! In this video I will explain and show you how to find temperature using the ideal gas equation. Next video in this series can be seen at: https://youtu.be/SUzaH162LY4
From playlist PHYSICS - THERMODYNAMICS
A Visual Example Of MASS Density!! #Chemistry #Physics #Engineering #Density #NicholasGKK #Shorts
From playlist Heat and Chemistry
The Incorrect Assumptions of the Ideal Gas Model - and Why It Still Works!
What exactly IS an Ideal Gas? And why do physicists use this model to represent real gases? In this video we'll compare the assumptions made by the ideal gas model with the properties of real gases, as well as how we can improve the ideal gas law in certain scenarios. As with every model
From playlist Thermodynamics by Parth G
Three-Dimensional Coordinates and the Right-Hand Rule
We've done tons of stuff with the coordinate plane, but that depicts only two spatial dimensions. We experience the world in three spatial dimensions, so sometimes we will need to communicate coordinates in three-dimensional space. Let's look at some rules regarding this system, and a few
From playlist Mathematics (All Of It)
Three-Dimensional Shapes Part 2: Calculating Volume
We introduced a number of three-dimensional shapes in the last clip, but we still just talked about two-dimensional surface area. What's up with that? Alright, alright, let's learn how to calculate the three-dimensional volume that a shape will occupy. This is like the amount of water that
From playlist Geometry
Chemistry of Gases (35 of 40) Diffusion of Gases: Basics
Visit http://ilectureonline.com for more math and science lectures! In this video I will explain the basics of the diffusion of gases.
From playlist CHEMISTRY 10 THE CHEMISTRY OF GASES
Physics - Thermodynamics: States: (1 of 10) State Variables Of Gas
Visit http://ilectureonline.com for more math and science lectures! In this video I will explain the different state variables of a gas. Next video in this series can be seen at: https://youtu.be/MG1Fp0vphew
From playlist PHYSICS - THERMODYNAMICS
Thermodynamics 4a - Entropy and the Second Law I
The Second Law of Thermodynamics is one of the most important laws in all of physics. But it is also one of the more difficult to understand. Central to it are the concepts of reversibility and entropy. Note on the definition of a "closed system." I am using the term "closed system" in th
From playlist Thermodynamics
Quantum Transport, Lecture 5: Ballistic Transport
Instructor: Sergey Frolov, University of Pittsburgh, Spring 2013 http://sergeyfrolov.wordpress.com/ Summary: Drude model, electron focusing, quantum point contacts, scanning gate microscopy. Quantum Transport course development supported in part by the National Science Foundation under gra
From playlist Quantum Transport
Lecture 8 | Modern Physics: Statistical Mechanics
May 19, 2009 - Leonard Susskind lectures on a new class of systems, magnetic systems. He goes on to talk about mean field approximations of molecules in multidimensional lattice systems. Stanford University: http://www.stanford.edu/ Stanford Continuing Studies Program: http://csp.s
From playlist Lecture Collection | Modern Physics: Statistical Mechanics
8.01x - Lect 33 - Kinetic Gas Theory, Ideal Gas Law, Phase Transitions
Kinetic Gas Theory - Ideal Gas Law - Isothermal Atmosphere - Phase Diagrams - Phase Transitions Lecture Notes, Ideal Gas Law and Comments on Phase Transitions: http://freepdfhosting.com/d0b182fb10.pdf Assignments Lecture 33 and 34: http://freepdfhosting.com/9abfa7fb57.pdf Solutions Lecture
From playlist 8.01x - MIT Physics I: Classical Mechanics
Introduction to Solid State Physics, Lecture 21: Physics of Two-Dimensional Systems
Upper-level undergraduate course taught at the University of Pittsburgh in the Fall 2015 semester by Sergey Frolov. The course is based on Steven Simon's "Oxford Solid State Basics" textbook. Lectures recorded using Panopto, to see them in Panopto viewer follow this link: https://pitt.host
From playlist Introduction to Solid State Physics
Quantum Transport, Lecture 3: Materials for Quantum Transport
Instructor: Sergey Frolov, University of Pittsburgh, Spring 2013 http://sergeyfrolov.wordpress.com/ Summary: In this lecture materials commonly used in quantum transport are discussed. They include semiconductors (2DEGs, nanowires, self-assembled quantum dots), graphene and carbon nanotube
From playlist Quantum Transport
Quantum Transport, Lecture 6: Quantum Point Contacts II
Instructor: Sergey Frolov, University of Pittsburgh, Spring 2013 http://sergeyfrolov.wordpress.com/ Summary: Advanced topics related to one-dimensional quantum transport. 1) Non-linear regime in Quantum Point Contacts 2) Landauer-Buttiker formalism 3) Spin filtering properties of Quantum P
From playlist Quantum Transport
Generalized Hydrodynamics on an Atom Chip by Jerome Dubail
PROGRAM THERMALIZATION, MANY BODY LOCALIZATION AND HYDRODYNAMICS ORGANIZERS: Dmitry Abanin, Abhishek Dhar, François Huveneers, Takahiro Sagawa, Keiji Saito, Herbert Spohn and Hal Tasaki DATE : 11 November 2019 to 29 November 2019 VENUE: Ramanujan Lecture Hall, ICTS Bangalore How do is
From playlist Thermalization, Many Body Localization And Hydrodynamics 2019
Discretization and modelling of the non-cutoff Boltzmann collision operator using Hermite spectral
Zhenning Cai National University of Singapore, Singapore
From playlist 2018 Modeling and Simulation of Interface Dynamics in Fluids/Solids and Their Applications
Surface Law and Charge Rigidity for the Coulomb Gas on Zd - Christophe Garban
Probability Seminar Topic: Surface Law and Charge Rigidity for the Coulomb Gas on Zd Speaker: Christophe Garban Affiliation: University of Lyon Date: January 27, 2023 I will start by introducing and motivating the (two-component) Coulomb gas on the d-dimensional lattice Zd. I will then p
From playlist Mathematics
Random forests and hyperbolic symmetry - Roland Bauerschmidt
Special Seminar Topic: Random forests and hyperbolic symmetry Speaker: Roland Bauerschmidt Affiliation: University of Cambridge Date: November 10, 2021 Given a finite graph, the arboreal gas is the measure on forests (subgraphs without cycles) in which each edge is weighted by a paramete
From playlist Mathematics
States of matter for gases | U2 | ATAR Chemistry QCE
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From playlist Topic 1 Stoichiometry - at a slower pace...
Mod-01 Lec-33 Physics of scattering, emmision and absorption
Introduction to Atmospheric Science by Science Prof. C. Balaji,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
From playlist IIT Madras: Introduction to Atmospheric Science | CosmoLearning.org