- published: 05 Dec 2020
- views: 17368
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Phase change
Phase change may refer to:
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Phase_change
Phase change (waves)
A phase change or phase shift is a change in the phase of a wave.
Optics
Light waves change phase by 180 degrees when they reflect from the surface of a medium with higher refractive index than that of the medium in which they are travelling. A light wave travelling in air that is reflected by a glass barrier will undergo a 180 degree phase change, while light travelling in glass will not undergo a phase change if it is reflected by a boundary with air. For this reason, optical boundaries are normally specified as an ordered pair (air-glass, glass-air); indicating which material the light is moving out of, and in to, respectively.
The phase changes that take place upon reflection play an important part in thin film interference.
Sound waves
Regarding longitudinal sound waves, when propagation occurs from a solid boundary to an air boundary the wave that is reflected back into the solid will experience a phase reversal.
References
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Phase_change_(waves)
Phase transition
A phase transition is the transformation of a thermodynamic system from one phase or state of matter to another one by heat transfer. The term is most commonly used to describe transitions between solid, liquid and gaseous states of matter, and, in rare cases, plasma. A phase of a thermodynamic system and the states of matter have uniform physical properties. During a phase transition of a given medium certain properties of the medium change, often discontinuously, as a result of the change of some external condition, such as temperature, pressure, or others. For example, a liquid may become gas upon heating to the boiling point, resulting in an abrupt change in volume. The measurement of the external conditions at which the transformation occurs is termed the phase transition. Phase transitions are common in nature and used today in many technologies.
Types of phase transition
Examples of phase transitions include:
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Phase_transition
Tangerine Dream
Tangerine Dream are a German electronic music group founded in 1967 by Edgar Froese. The group has seen many personnel changes over the years, with Froese being the only continuous member until his death in January 2015. Noted electronic music artist, drummer, and composer Klaus Schulze was briefly a member in an early lineup. The best known and most constant line-up of the group, which worked during their most influential mid-1970s period, was a trio with Froese, Christopher Franke, and Peter Baumann. In the late 1970s, Johannes Schmoelling replaced Baumann, and this lineup was stable and extremely productive as well.
Tangerine Dream's recorded output has been prolific, having released over one hundred albums. Their work with the Ohr electronic music label, a period called the "Pink Years" because of a pink ear included in Ohr's logo, produced albums that had a pivotal role in the development of the musical genre known as krautrock. Their "Virgin Years," so-called because of their association with Virgin Records, produced albums that helped define what became known as the Berlin School of electronic music. These and later albums were influential in both the development of electronic dance music and also new-age music, although the band themselves disliked that term. From the late 1990s into the 2000s, Tangerine Dream continued to explore other styles of electronica.
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Tangerine_Dream
Tangerine Dream (song)
"Tangerine Dream" is the first single by Do As Infinity, released in 1999. "Faces" and "Simple Minds" were never included in any album.
This song was included in the band's compilation albums Do the Best and Do the A-side.
Track listing
Chart positions
External links
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Tangerine_Dream_(song)
Tangerine Dream (disambiguation)
Tangerine Dream is a German electronic music band.
Tangerine Dream may refer to:
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Tangerine_Dream_(disambiguation)
Podcasts:
-
Phase Transitions
Looking at the Gibbs energy shows us that ordered phases (like a solid) will always undergo a transition and convert to more disordered phases (like a gas) if the temperature is increased enough.
published: 05 Dec 2020 -
Phase Diagrams of Water & CO2 Explained - Chemistry - Melting, Boiling & Critical Point
This chemistry video tutorial explains the concepts behind the phase diagram of CO2 / Carbon Dioxide and the phase diagram of water / H2O. This video contains plenty of examples and practice problems: Chapter 10 - Video Lessons: https://www.video-tutor.net/liquids-and-solids.html ______________________________ Boyle's Law Practice Problems: https://www.youtube.com/watch?v=v8r_AU_TlPg How Does a Bike Pump Work? https://www.youtube.com/watch?v=I0b_i6-HLBA Charles Law: https://www.youtube.com/watch?v=uZ2d79NFx2w Gay Lussac's Law: https://www.youtube.com/watch?v=RszgzH_2A9k Avogadro's Law: https://www.youtube.com/watch?v=Czo2rIai5u0 Ideal Gas Law Problems: https://www.youtube.com/watch?v=LZUs6nawHAk _____________________________ Translational Kinetic Energy: https://www.you...
published: 06 Oct 2016 -
Phase Transition - Your Guide (Official Music Video)
Follow us: Instagram: https://www.instagram.com/phase.transition.official/ Facebook: http://facebook.com/phase.transition.official TikTok: https://www.tiktok.com/@phasetransition MUSIC Vocals - Sofia Beco Guitar - Luís Dias Bass - Zé Pereira Drums - Fernando Maia Mixed and Mastered by Afonso Aguiar at TitanForged Productions. Recorded by Afonso Aguiar. VÍDEO Vídeo Produced by Coalblur. Concept by Phase Transition and Coalblur. Directed by Sara Gonçalves. Filmed by João Martins and Tiago Sousa. Edited by Tiago Sousa.
published: 12 May 2023 -
Phase Changes, Heats of Fusion and Vaporization, and Phase Diagrams
What the heck is dry ice and why is it so spooky? Learn this and more when we investigate phase changes and phase diagrams! Watch the whole General Chemistry playlist: http://bit.ly/ProfDaveGenChem Study for the AP Chemistry exam with me: https://bit.ly/ProfDaveAPChem Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem Biology Tutorials: http://bit.ly/ProfDaveBio Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1 Modern Physics Tutorials: http://bit.ly/ProfDavePhysics2 Mathematics Tutorials: http://bit.ly/ProfDaveMaths EMAIL► ProfessorDaveExplains@gmail.com PATREON► http://patreon.com/ProfessorDaveExplains Check out "Is This Wi-Fi Organic?", my book on disarming pseudoscience! Amazon: https://amzn.to/2HtNpVH Booksho...
published: 05 Dec 2015 -
Phase Changes
To see all my Chemistry videos, check out http://socratic.org/chemistry What does a phase change look like at the molecular level? We'll look at the molecular structure in solid, liquid, and gas phases, and see how the kinetic energy of the particles changes. We'll talking about melting, vaporization, condensation, and freezing.
published: 06 Oct 2011 -
Percolation: a Mathematical Phase Transition
—————SOURCES———————————————————————— Percolation – Béla Bollobás and Oliver Riordan Cambridge University Press, New York, 2006. Sixty Years of Percolation – Hugo Duminil-Copin https://www.ihes.fr/~duminil/publi/2018ICM.pdf Percolation – Geoffrey Grimmett volume 321 of Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences]. Springer-Verlag, Berlin, second edition, 1999. —————NOTES————————————————————————— Note at 10:42 – The uniqueness of the infinite cluster is known for the d-dimenional lattice since the works of Aizenman, Kesten and Newman - [Uniqueness of the infinite cluster and continuity of connectivity functions for short and long range percolation (1987)] and Burton and Keane - [Density and uniqueness in percolation (1989)]. It does n...
published: 09 Aug 2022 -
What is a phase transition?
Try Audible and get up to two free audiobooks: https://amzn.to/3Torkbc Hey everyone! I am back with a new guest speaker, Steven Silber. In this video Steven motivates the topic of thermodynamic phase transitions in preparation for his follow-up videos on modelling them. Recommended textbooks: Quantum mechanics: https://amzn.to/3Ar5dbn or https://amzn.to/3ckXkfL Statistical mechanics: https://amzn.to/3QYcere or https://amzn.to/3cmZb3u Quantum information: https://amzn.to/3Kpjt96 or https://amzn.to/3KpjAl2 My publication list: https://scholar.google.com/citations?user=V2UZXZMAAAAJ&hl;=en Instagram: https://www.instagram.com/stat.mech.in.action/ TikTok: https://www.tiktok.com/@stat.mech.in.action?lang=en Twitter: https://twitter.com/JonathonRiddell Discord: https://discord.gg/QK9HhuXBEF...
published: 15 Sep 2021 -
PHASE CHANGES | Science 8 Quarter 3:Module 2
published: 19 Feb 2022 -
Railroader Ep 17 - Phase 3 finish Ela Bridge open
Experience the romance of the transition era as you take the reins of vintage locomotives, master intricate operations, and witness the beauty of a bygone era brought to life. Railroader is an operations-focused railroad simulator set in transition era Appalachia. Manage and run your railroad to your desire while using period steam and diesel locomotives and rolling stock.
published: 27 Dec 2023 -
Phase Transitions & Bifurcations
Take the full course: https://www.systemsinnovation.network/courses/7297973/ Twitter: http://bit.ly/2JuNmXX LinkedIn: http://bit.ly/2YCP2U6 A phase transition is the transformation of a system from one state to another through a period of rapid change. The classical example of this is the transition between solid, liquid and gaseous states that water passes through given some change in temperature, phase transitions are another hallmark of nonlinear systems. In this module we discuss the concept in tandem with its counterpart bifurcation theory. Transcription excerpt: Bifurcations & Phase transitions As we have previously discussed the qualitative dynamic behavior of nonlinear systems is largely defined by the positive and negative feedback loops that regulate their development, with ne...
published: 13 Apr 2015
9:38
Phase Transitions
- Order: Reorder
- Duration: 9:38
- Uploaded Date: 05 Dec 2020
- views: 17368
Looking at the Gibbs energy shows us that ordered phases (like a solid) will always undergo a transition and convert to more disordered phases (like a gas) if t...
Looking at the Gibbs energy shows us that ordered phases (like a solid) will always undergo a transition and convert to more disordered phases (like a gas) if the temperature is increased enough.
https://wn.com/Phase_Transitions
Looking at the Gibbs energy shows us that ordered phases (like a solid) will always undergo a transition and convert to more disordered phases (like a gas) if the temperature is increased enough.
10:28
Phase Diagrams of Water & CO2 Explained - Chemistry - Melting, Boiling & Critical Point
- Order: Reorder
- Duration: 10:28
- Uploaded Date: 06 Oct 2016
- views: 711022
This chemistry video tutorial explains the concepts behind the phase diagram of CO2 / Carbon Dioxide and the phase diagram of water / H2O. This video contains ...
This chemistry video tutorial explains the concepts behind the phase diagram of CO2 / Carbon Dioxide and the phase diagram of water / H2O. This video contains plenty of examples and practice problems:
Chapter 10 - Video Lessons:
https://www.video-tutor.net/liquids-and-solids.html
______________________________
Boyle's Law Practice Problems:
https://www.youtube.com/watch?v=v8r_AU_TlPg
How Does a Bike Pump Work?
https://www.youtube.com/watch?v=I0b_i6-HLBA
Charles Law:
https://www.youtube.com/watch?v=uZ2d79NFx2w
Gay Lussac's Law:
https://www.youtube.com/watch?v=RszgzH_2A9k
Avogadro's Law:
https://www.youtube.com/watch?v=Czo2rIai5u0
Ideal Gas Law Problems:
https://www.youtube.com/watch?v=LZUs6nawHAk
_____________________________
Translational Kinetic Energy:
https://www.youtube.com/watch?v=bg5d5BFANVU
Molecular Speed of Gases:
https://www.youtube.com/watch?v=0m25oTKMv1Y
Mean Free Path and Free Time:
https://www.youtube.com/watch?v=ypK7h3NKe1E
RMS vs Average Speed:
https://www.youtube.com/watch?v=hBlwfG6IBLg
Molar Heat Capacities of Gases:
https://www.youtube.com/watch?v=SwMODT8m4Ls
____________________________
Relative Humidity & Dew Point:
https://www.youtube.com/watch?v=BqFVtlQa-2w
Fick's Law of Diffusion:
https://www.youtube.com/watch?v=JgAKv1Zlgcw
Open Vs Closed Vs Isolated System:
https://www.youtube.com/watch?v=TFP6SvWPOQc
First Law of Thermodynamics:
https://www.youtube.com/watch?v=7Siv2NNCFag
Final Exams and Video Playlists:
https://www.video-tutor.net/
Physics PDF Worksheets:
https://www.video-tutor.net/physics-basic-introduction.html
Here is a list of topics:
1. Phase Changes
2. Freezing - Liquid to Solid
3. Melting - Solid to Liquid
4. Vaporization - Liquid to Gas
5. Condensation - Gas to Liquid
6. Sublimation - Solid to Gas
7. Deposition - Gas to Solid
8. Phase Diagram of CO2 - Carbon Dioxide - Sublimation
9. Melting Point Curve vs Boiling Point Curve
10. Normal Atmospheric Pressure of 1 Atm
11. Definition of Normal Melting Point and Normal Boiling Point
12. Solid, Liquid, and Gas Phases
13. Critical Point, Critical Temperature, and Critical Pressure
14. Supercritical Fluids -
15. Density of Solids vs Liquids for CO2
16. Why ice is less dense that water
17. Melting Point Curve - Negative Slope for H2O vs Positive Slope for CO2 - Density & Pressure
https://wn.com/Phase_Diagrams_Of_Water_Co2_Explained_Chemistry_Melting,_Boiling_Critical_Point
This chemistry video tutorial explains the concepts behind the phase diagram of CO2 / Carbon Dioxide and the phase diagram of water / H2O. This video contains plenty of examples and practice problems:
Chapter 10 - Video Lessons:
https://www.video-tutor.net/liquids-and-solids.html
______________________________
Boyle's Law Practice Problems:
https://www.youtube.com/watch?v=v8r_AU_TlPg
How Does a Bike Pump Work?
https://www.youtube.com/watch?v=I0b_i6-HLBA
Charles Law:
https://www.youtube.com/watch?v=uZ2d79NFx2w
Gay Lussac's Law:
https://www.youtube.com/watch?v=RszgzH_2A9k
Avogadro's Law:
https://www.youtube.com/watch?v=Czo2rIai5u0
Ideal Gas Law Problems:
https://www.youtube.com/watch?v=LZUs6nawHAk
_____________________________
Translational Kinetic Energy:
https://www.youtube.com/watch?v=bg5d5BFANVU
Molecular Speed of Gases:
https://www.youtube.com/watch?v=0m25oTKMv1Y
Mean Free Path and Free Time:
https://www.youtube.com/watch?v=ypK7h3NKe1E
RMS vs Average Speed:
https://www.youtube.com/watch?v=hBlwfG6IBLg
Molar Heat Capacities of Gases:
https://www.youtube.com/watch?v=SwMODT8m4Ls
____________________________
Relative Humidity & Dew Point:
https://www.youtube.com/watch?v=BqFVtlQa-2w
Fick's Law of Diffusion:
https://www.youtube.com/watch?v=JgAKv1Zlgcw
Open Vs Closed Vs Isolated System:
https://www.youtube.com/watch?v=TFP6SvWPOQc
First Law of Thermodynamics:
https://www.youtube.com/watch?v=7Siv2NNCFag
Final Exams and Video Playlists:
https://www.video-tutor.net/
Physics PDF Worksheets:
https://www.video-tutor.net/physics-basic-introduction.html
Here is a list of topics:
1. Phase Changes
2. Freezing - Liquid to Solid
3. Melting - Solid to Liquid
4. Vaporization - Liquid to Gas
5. Condensation - Gas to Liquid
6. Sublimation - Solid to Gas
7. Deposition - Gas to Solid
8. Phase Diagram of CO2 - Carbon Dioxide - Sublimation
9. Melting Point Curve vs Boiling Point Curve
10. Normal Atmospheric Pressure of 1 Atm
11. Definition of Normal Melting Point and Normal Boiling Point
12. Solid, Liquid, and Gas Phases
13. Critical Point, Critical Temperature, and Critical Pressure
14. Supercritical Fluids -
15. Density of Solids vs Liquids for CO2
16. Why ice is less dense that water
17. Melting Point Curve - Negative Slope for H2O vs Positive Slope for CO2 - Density & Pressure
- published: 06 Oct 2016
- views: 711022
2:47
Phase Transition - Your Guide (Official Music Video)
- Order: Reorder
- Duration: 2:47
- Uploaded Date: 12 May 2023
- views: 1594
Follow us:
Instagram: https://www.instagram.com/phase.transition.official/
Facebook: http://facebook.com/phase.transition.official
TikTok: https://www.tiktok.co...
Follow us:
Instagram: https://www.instagram.com/phase.transition.official/
Facebook: http://facebook.com/phase.transition.official
TikTok: https://www.tiktok.com/@phasetransition
MUSIC
Vocals - Sofia Beco
Guitar - Luís Dias
Bass - Zé Pereira
Drums - Fernando Maia
Mixed and Mastered by Afonso Aguiar at TitanForged Productions.
Recorded by Afonso Aguiar.
VÍDEO
Vídeo Produced by Coalblur.
Concept by Phase Transition and Coalblur.
Directed by Sara Gonçalves.
Filmed by João Martins and Tiago Sousa.
Edited by Tiago Sousa.
https://wn.com/Phase_Transition_Your_Guide_(Official_Music_Video)
Follow us:
Instagram: https://www.instagram.com/phase.transition.official/
Facebook: http://facebook.com/phase.transition.official
TikTok: https://www.tiktok.com/@phasetransition
MUSIC
Vocals - Sofia Beco
Guitar - Luís Dias
Bass - Zé Pereira
Drums - Fernando Maia
Mixed and Mastered by Afonso Aguiar at TitanForged Productions.
Recorded by Afonso Aguiar.
VÍDEO
Vídeo Produced by Coalblur.
Concept by Phase Transition and Coalblur.
Directed by Sara Gonçalves.
Filmed by João Martins and Tiago Sousa.
Edited by Tiago Sousa.
- published: 12 May 2023
- views: 1594
4:51
Phase Changes, Heats of Fusion and Vaporization, and Phase Diagrams
- Order: Reorder
- Duration: 4:51
- Uploaded Date: 05 Dec 2015
- views: 353761
What the heck is dry ice and why is it so spooky? Learn this and more when we investigate phase changes and phase diagrams!
Watch the whole General Chemistry p...
What the heck is dry ice and why is it so spooky? Learn this and more when we investigate phase changes and phase diagrams!
Watch the whole General Chemistry playlist: http://bit.ly/ProfDaveGenChem
Study for the AP Chemistry exam with me: https://bit.ly/ProfDaveAPChem
Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem
Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem
Biology Tutorials: http://bit.ly/ProfDaveBio
Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1
Modern Physics Tutorials: http://bit.ly/ProfDavePhysics2
Mathematics Tutorials: http://bit.ly/ProfDaveMaths
EMAIL► ProfessorDaveExplains@gmail.com
PATREON► http://patreon.com/ProfessorDaveExplains
Check out "Is This Wi-Fi Organic?", my book on disarming pseudoscience!
Amazon: https://amzn.to/2HtNpVH
Bookshop: https://bit.ly/39cKADM
Barnes and Noble: https://bit.ly/3pUjmrn
Book Depository: http://bit.ly/3aOVDlT
https://wn.com/Phase_Changes,_Heats_Of_Fusion_And_Vaporization,_And_Phase_Diagrams
What the heck is dry ice and why is it so spooky? Learn this and more when we investigate phase changes and phase diagrams!
Watch the whole General Chemistry playlist: http://bit.ly/ProfDaveGenChem
Study for the AP Chemistry exam with me: https://bit.ly/ProfDaveAPChem
Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem
Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem
Biology Tutorials: http://bit.ly/ProfDaveBio
Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1
Modern Physics Tutorials: http://bit.ly/ProfDavePhysics2
Mathematics Tutorials: http://bit.ly/ProfDaveMaths
EMAIL► ProfessorDaveExplains@gmail.com
PATREON► http://patreon.com/ProfessorDaveExplains
Check out "Is This Wi-Fi Organic?", my book on disarming pseudoscience!
Amazon: https://amzn.to/2HtNpVH
Bookshop: https://bit.ly/39cKADM
Barnes and Noble: https://bit.ly/3pUjmrn
Book Depository: http://bit.ly/3aOVDlT
- published: 05 Dec 2015
- views: 353761
9:33
Phase Changes
- Order: Reorder
- Duration: 9:33
- Uploaded Date: 06 Oct 2011
- views: 413970
To see all my Chemistry videos, check out
http://socratic.org/chemistry
What does a phase change look like at the molecular level? We'll look at the molecular ...
To see all my Chemistry videos, check out
http://socratic.org/chemistry
What does a phase change look like at the molecular level? We'll look at the molecular structure in solid, liquid, and gas phases, and see how the kinetic energy of the particles changes. We'll talking about melting, vaporization, condensation, and freezing.
https://wn.com/Phase_Changes
To see all my Chemistry videos, check out
http://socratic.org/chemistry
What does a phase change look like at the molecular level? We'll look at the molecular structure in solid, liquid, and gas phases, and see how the kinetic energy of the particles changes. We'll talking about melting, vaporization, condensation, and freezing.
- published: 06 Oct 2011
- views: 413970
26:52
Percolation: a Mathematical Phase Transition
- Order: Reorder
- Duration: 26:52
- Uploaded Date: 09 Aug 2022
- views: 334471
—————SOURCES————————————————————————
Percolation – Béla Bollobás and Oliver Riordan
Cambridge University Press, New York, 2006.
Sixty Years of Percolation – H...
—————SOURCES————————————————————————
Percolation – Béla Bollobás and Oliver Riordan
Cambridge University Press, New York, 2006.
Sixty Years of Percolation – Hugo Duminil-Copin
https://www.ihes.fr/~duminil/publi/2018ICM.pdf
Percolation – Geoffrey Grimmett
volume 321 of Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences]. Springer-Verlag, Berlin, second edition, 1999.
—————NOTES—————————————————————————
Note at 10:42 – The uniqueness of the infinite cluster is known for the d-dimenional lattice since the works of Aizenman, Kesten and Newman - [Uniqueness of the infinite cluster and continuity of connectivity functions for short and long range percolation (1987)] and Burton and Keane - [Density and uniqueness in percolation (1989)]. It does not hold in general: when the graph in question is a regular tree for example, there are always infinitely many clusters during the supercritical phase.
The two last results shown here are only known for site percolation (in which vertices are open or closed instead of edges) in the triangular lattice, where a scaling limit for the boundaries of critical clusters was proved to exist (more on that in the third note). It is believed that these results are universal, that is, valid in great generality for planar percolation processes near criticality.
The third result is from an appendix by Gábor Pete in the paper [Scaling limits for the threshold window: When does a monotone Boolean function flip its outcome? (2017)] by Ahlberg and Steif. Consider an n by n box, and the event where there exists a left-right crossing of said box. Recall the uniform coupling from the video: intuitively, the result is saying that the point at which this crossing emerges in the uniform coupling is with high probability inside an interval of size n^{-3/4} around 1/2.
The fourth result is saying that the average size of the cluster of the origin (or any other given point) goes to infinity as we let p approach the critical parameter like a specific power of the distance between p and p_c. This power is called a critical exponent. The existence of these exponents was proved by Smirnov and Werner in the paper [Critical exponents for two-dimensional percolation (2001)].
Note at 10:52 – Hugo Duminil-Copin has several major contributions to the study of processes arising in statistical physics, including Bernoulli percolation. Among his works on Ising and Ising-like processes we can cite [Random Currents and Continuity of Ising Model’s Spontaneous Magnetization (2015)] with Aizenman and Sidoravicius and [Sharp phase transition for the random-cluster and Potts models via decision trees (2019)] with Raoufi and Tassion.
Note at 12:38 – In the triangular lattice site percolation, Stanislav Smirnov proved the conformal invariance of crossing probabilities at criticality (see https://www.unige.ch/~smirnov/papers/icmp-final.pdf for an overview), which led to the proof of the existence of scaling limits of exploration curves as Schramm–Loewner evolution processes. See [Critical percolation in the plane (2009)] by Smirnov. This provided a deep understanding of the critical phase in the triangular lattice site percolation, which to this day is not extended to the square lattice.
Note at 17:52 – It is not at all obvious that the probability of being connected to infinity is continuous above criticality. This result can be proved in the d-dimenional hypercubic lattices using the uniqueness of the infinite cluster, and more generally it was proved for transitive graphs (intuitively, graphs in which all vertices look the same) by Häggström, Peres and Schonmann in [Percolation on transitive graphs as a coalescent process: Relentless merging followed by simultaneous uniqueness (1999)].
—————SECTIONS———————————————————————
0:00 Introduction
1:37 Definition – Bernoulli Percolation
5:23 Definition – Uniform Coupling
7:56 Exploration – High-Resolution Square Grid
9:40 Exploration – Questions and Kesten's Theorem
10:58 Exploration – Ising Model
11:54 Exploration – Critical Percolation
12:50 Exploration – Three-Dimensional Cubic Lattice and Beyond
14:13 Proof – Theorem Statement
15:14 Proof – Simplifications
16:29 Proof – Definition of Critical Parameter
18:41 Proof – Critical Parameter is Greater Than Zero
20:44 Proof – Duality Definition
21:56 Proof – Critical Parameter is Less Than One
25:16 Proof – Summary and Idea for Kesten's Theorem
26:11 Conclusion
—————CREDITS————————————————————————
Caio Alves – writing, 3D animation
Aranka Hrušková – writing, clarinet
Vilas Winstein – writing, 2D animation, editing, voice-over
Special thanks to Anisah Awad, Gábor Pete, Jyotsna Sreenivasan, Angie Zavala
This video is an entry in the second Summer of Mathematics Exposition (#SoME2)
The photographs used in this video are licensed under the Creative Commons Attribution-ShareAlike license:
https://creativecommons.org/licenses/by-sa/4.0/deed.en
https://wn.com/Percolation_A_Mathematical_Phase_Transition
—————SOURCES————————————————————————
Percolation – Béla Bollobás and Oliver Riordan
Cambridge University Press, New York, 2006.
Sixty Years of Percolation – Hugo Duminil-Copin
https://www.ihes.fr/~duminil/publi/2018ICM.pdf
Percolation – Geoffrey Grimmett
volume 321 of Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences]. Springer-Verlag, Berlin, second edition, 1999.
—————NOTES—————————————————————————
Note at 10:42 – The uniqueness of the infinite cluster is known for the d-dimenional lattice since the works of Aizenman, Kesten and Newman - [Uniqueness of the infinite cluster and continuity of connectivity functions for short and long range percolation (1987)] and Burton and Keane - [Density and uniqueness in percolation (1989)]. It does not hold in general: when the graph in question is a regular tree for example, there are always infinitely many clusters during the supercritical phase.
The two last results shown here are only known for site percolation (in which vertices are open or closed instead of edges) in the triangular lattice, where a scaling limit for the boundaries of critical clusters was proved to exist (more on that in the third note). It is believed that these results are universal, that is, valid in great generality for planar percolation processes near criticality.
The third result is from an appendix by Gábor Pete in the paper [Scaling limits for the threshold window: When does a monotone Boolean function flip its outcome? (2017)] by Ahlberg and Steif. Consider an n by n box, and the event where there exists a left-right crossing of said box. Recall the uniform coupling from the video: intuitively, the result is saying that the point at which this crossing emerges in the uniform coupling is with high probability inside an interval of size n^{-3/4} around 1/2.
The fourth result is saying that the average size of the cluster of the origin (or any other given point) goes to infinity as we let p approach the critical parameter like a specific power of the distance between p and p_c. This power is called a critical exponent. The existence of these exponents was proved by Smirnov and Werner in the paper [Critical exponents for two-dimensional percolation (2001)].
Note at 10:52 – Hugo Duminil-Copin has several major contributions to the study of processes arising in statistical physics, including Bernoulli percolation. Among his works on Ising and Ising-like processes we can cite [Random Currents and Continuity of Ising Model’s Spontaneous Magnetization (2015)] with Aizenman and Sidoravicius and [Sharp phase transition for the random-cluster and Potts models via decision trees (2019)] with Raoufi and Tassion.
Note at 12:38 – In the triangular lattice site percolation, Stanislav Smirnov proved the conformal invariance of crossing probabilities at criticality (see https://www.unige.ch/~smirnov/papers/icmp-final.pdf for an overview), which led to the proof of the existence of scaling limits of exploration curves as Schramm–Loewner evolution processes. See [Critical percolation in the plane (2009)] by Smirnov. This provided a deep understanding of the critical phase in the triangular lattice site percolation, which to this day is not extended to the square lattice.
Note at 17:52 – It is not at all obvious that the probability of being connected to infinity is continuous above criticality. This result can be proved in the d-dimenional hypercubic lattices using the uniqueness of the infinite cluster, and more generally it was proved for transitive graphs (intuitively, graphs in which all vertices look the same) by Häggström, Peres and Schonmann in [Percolation on transitive graphs as a coalescent process: Relentless merging followed by simultaneous uniqueness (1999)].
—————SECTIONS———————————————————————
0:00 Introduction
1:37 Definition – Bernoulli Percolation
5:23 Definition – Uniform Coupling
7:56 Exploration – High-Resolution Square Grid
9:40 Exploration – Questions and Kesten's Theorem
10:58 Exploration – Ising Model
11:54 Exploration – Critical Percolation
12:50 Exploration – Three-Dimensional Cubic Lattice and Beyond
14:13 Proof – Theorem Statement
15:14 Proof – Simplifications
16:29 Proof – Definition of Critical Parameter
18:41 Proof – Critical Parameter is Greater Than Zero
20:44 Proof – Duality Definition
21:56 Proof – Critical Parameter is Less Than One
25:16 Proof – Summary and Idea for Kesten's Theorem
26:11 Conclusion
—————CREDITS————————————————————————
Caio Alves – writing, 3D animation
Aranka Hrušková – writing, clarinet
Vilas Winstein – writing, 2D animation, editing, voice-over
Special thanks to Anisah Awad, Gábor Pete, Jyotsna Sreenivasan, Angie Zavala
This video is an entry in the second Summer of Mathematics Exposition (#SoME2)
The photographs used in this video are licensed under the Creative Commons Attribution-ShareAlike license:
https://creativecommons.org/licenses/by-sa/4.0/deed.en
- published: 09 Aug 2022
- views: 334471
12:10
What is a phase transition?
- Order: Reorder
- Duration: 12:10
- Uploaded Date: 15 Sep 2021
- views: 3514
Try Audible and get up to two free audiobooks: https://amzn.to/3Torkbc
Hey everyone!
I am back with a new guest speaker, Steven Silber. In this video Steven...
Try Audible and get up to two free audiobooks: https://amzn.to/3Torkbc
Hey everyone!
I am back with a new guest speaker, Steven Silber. In this video Steven motivates the topic of thermodynamic phase transitions in preparation for his follow-up videos on modelling them.
Recommended textbooks:
Quantum mechanics:
https://amzn.to/3Ar5dbn or https://amzn.to/3ckXkfL
Statistical mechanics:
https://amzn.to/3QYcere or https://amzn.to/3cmZb3u
Quantum information:
https://amzn.to/3Kpjt96 or https://amzn.to/3KpjAl2
My publication list: https://scholar.google.com/citations?user=V2UZXZMAAAAJ&hl;=en
Instagram: https://www.instagram.com/stat.mech.in.action/
TikTok: https://www.tiktok.com/@stat.mech.in.action?lang=en
Twitter: https://twitter.com/JonathonRiddell
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https://wn.com/What_Is_A_Phase_Transition
Try Audible and get up to two free audiobooks: https://amzn.to/3Torkbc
Hey everyone!
I am back with a new guest speaker, Steven Silber. In this video Steven motivates the topic of thermodynamic phase transitions in preparation for his follow-up videos on modelling them.
Recommended textbooks:
Quantum mechanics:
https://amzn.to/3Ar5dbn or https://amzn.to/3ckXkfL
Statistical mechanics:
https://amzn.to/3QYcere or https://amzn.to/3cmZb3u
Quantum information:
https://amzn.to/3Kpjt96 or https://amzn.to/3KpjAl2
My publication list: https://scholar.google.com/citations?user=V2UZXZMAAAAJ&hl;=en
Instagram: https://www.instagram.com/stat.mech.in.action/
TikTok: https://www.tiktok.com/@stat.mech.in.action?lang=en
Twitter: https://twitter.com/JonathonRiddell
Discord: https://discord.gg/QK9HhuXBEF
- published: 15 Sep 2021
- views: 3514
4:01
PHASE CHANGES | Science 8 Quarter 3:Module 2
- Order: Reorder
- Duration: 4:01
- Uploaded Date: 19 Feb 2022
- views: 35722
- published: 19 Feb 2022
- views: 35722
30:36
Railroader Ep 17 - Phase 3 finish Ela Bridge open
- Order: Reorder
- Duration: 30:36
- Uploaded Date: 27 Dec 2023
- views: 28
Experience the romance of the transition era as you take the reins of vintage locomotives, master intricate operations, and witness the beauty of a bygone era b...
Experience the romance of the transition era as you take the reins of vintage locomotives, master intricate operations, and witness the beauty of a bygone era brought to life.
Railroader is an operations-focused railroad simulator set in transition era Appalachia. Manage and run your railroad to your desire while using period steam and diesel locomotives and rolling stock.
https://wn.com/Railroader_Ep_17_Phase_3_Finish_Ela_Bridge_Open
Experience the romance of the transition era as you take the reins of vintage locomotives, master intricate operations, and witness the beauty of a bygone era brought to life.
Railroader is an operations-focused railroad simulator set in transition era Appalachia. Manage and run your railroad to your desire while using period steam and diesel locomotives and rolling stock.
- published: 27 Dec 2023
- views: 28
6:24
Phase Transitions & Bifurcations
- Order: Reorder
- Duration: 6:24
- Uploaded Date: 13 Apr 2015
- views: 25542
Take the full course: https://www.systemsinnovation.network/courses/7297973/
Twitter: http://bit.ly/2JuNmXX
LinkedIn: http://bit.ly/2YCP2U6
A phase transition i...
Take the full course: https://www.systemsinnovation.network/courses/7297973/
Twitter: http://bit.ly/2JuNmXX
LinkedIn: http://bit.ly/2YCP2U6
A phase transition is the transformation of a system from one state to another through a period of rapid change. The classical example of this is the transition between solid, liquid and gaseous states that water passes through given some change in temperature, phase transitions are another hallmark of nonlinear systems. In this module we discuss the concept in tandem with its counterpart bifurcation theory.
Transcription excerpt:
Bifurcations & Phase transitions
As we have previously discussed the qualitative dynamic behavior of nonlinear systems is largely defined by the positive and negative feedback loops that regulate their development, with negative feedback working to dampen down or constrain change to a linear progression, while positive feedback works to amplify change typically in an super-linear fashion.
As opposed to negative feedback where we get a gradual and often stable development over a prolonged period of time, what we might call a normal or equilibrium state of development, positive feedback is characteristic of a system in a state of nonequilibrium. Positive feedback development is fundamentally unsustainable because all systems in reality exist in an environment that will ultimately place a limit on this grown.
From this we can see how the exponential grow enabled by positive feedback loops is what we might say special, it can only exist for a relatively brief period of time, when we look around us we see the vast majority of things are in a stable configuration constrained by some negative feedback loop whether this is the law of gravity, predator prey dynamics or the economic laws of having to get out of bed and go to work every day. These special periods of positive feedback development are characteristic and a key diver of what we call phase transitions.
A phase transition may be defined as some smooth, small change in a quantitative input variable that results in a qualitative change in the system’s state. The transition of ice to steam is one example of a phase transition. At some critical temperature a small change in the systems input temperature value results in a systemic change in the substance after which it is governed by a new set of parameters and properties, for example we can talk about cracking ice but not water, or we can talk about the viscosity of a liquid but not a gas as these are in different phases under different physical regimes and thus we describe them with respect to different parameters.
Another example of a phase transition may be the changes within a colony of bacteria that when we change the heat and nutrient input to the system we change the local interactions between the bacteria and get a new emergent structure to the colony, although this change in input value may only be a linear progression it resulted in a qualitatively different pattern emerging on the macro level of the colony. It is not simply that a new order or structure has emerged but the actual rules that govern the system change and thus we use the word regime and talk about it as a regime shift, as some small changes in a parameter that affected the system on the local level leads to different emergent structures that then feedback to define a different regime that the elements now have to operate under.
Another way of talking about this is in the language of bifurcation theory, whereas with phase transitions we are talking about qualitative changes in the properties of the system, bifurcation theory really talks about how a small change in parameter can causes a topological change in a system’s environment resulting in new attractor states emerging. A bifurcation means a branching, in this case we are talking about a point where the future trajectory of an element in the system divides or branches out, as new attractor states emerge, from this critical point it can go in two different trajectories which are the product of these attractors, each branch represents a trajectory into a new basin of attraction with a new regime and equilibrium.
https://wn.com/Phase_Transitions_Bifurcations
Take the full course: https://www.systemsinnovation.network/courses/7297973/
Twitter: http://bit.ly/2JuNmXX
LinkedIn: http://bit.ly/2YCP2U6
A phase transition is the transformation of a system from one state to another through a period of rapid change. The classical example of this is the transition between solid, liquid and gaseous states that water passes through given some change in temperature, phase transitions are another hallmark of nonlinear systems. In this module we discuss the concept in tandem with its counterpart bifurcation theory.
Transcription excerpt:
Bifurcations & Phase transitions
As we have previously discussed the qualitative dynamic behavior of nonlinear systems is largely defined by the positive and negative feedback loops that regulate their development, with negative feedback working to dampen down or constrain change to a linear progression, while positive feedback works to amplify change typically in an super-linear fashion.
As opposed to negative feedback where we get a gradual and often stable development over a prolonged period of time, what we might call a normal or equilibrium state of development, positive feedback is characteristic of a system in a state of nonequilibrium. Positive feedback development is fundamentally unsustainable because all systems in reality exist in an environment that will ultimately place a limit on this grown.
From this we can see how the exponential grow enabled by positive feedback loops is what we might say special, it can only exist for a relatively brief period of time, when we look around us we see the vast majority of things are in a stable configuration constrained by some negative feedback loop whether this is the law of gravity, predator prey dynamics or the economic laws of having to get out of bed and go to work every day. These special periods of positive feedback development are characteristic and a key diver of what we call phase transitions.
A phase transition may be defined as some smooth, small change in a quantitative input variable that results in a qualitative change in the system’s state. The transition of ice to steam is one example of a phase transition. At some critical temperature a small change in the systems input temperature value results in a systemic change in the substance after which it is governed by a new set of parameters and properties, for example we can talk about cracking ice but not water, or we can talk about the viscosity of a liquid but not a gas as these are in different phases under different physical regimes and thus we describe them with respect to different parameters.
Another example of a phase transition may be the changes within a colony of bacteria that when we change the heat and nutrient input to the system we change the local interactions between the bacteria and get a new emergent structure to the colony, although this change in input value may only be a linear progression it resulted in a qualitatively different pattern emerging on the macro level of the colony. It is not simply that a new order or structure has emerged but the actual rules that govern the system change and thus we use the word regime and talk about it as a regime shift, as some small changes in a parameter that affected the system on the local level leads to different emergent structures that then feedback to define a different regime that the elements now have to operate under.
Another way of talking about this is in the language of bifurcation theory, whereas with phase transitions we are talking about qualitative changes in the properties of the system, bifurcation theory really talks about how a small change in parameter can causes a topological change in a system’s environment resulting in new attractor states emerging. A bifurcation means a branching, in this case we are talking about a point where the future trajectory of an element in the system divides or branches out, as new attractor states emerge, from this critical point it can go in two different trajectories which are the product of these attractors, each branch represents a trajectory into a new basin of attraction with a new regime and equilibrium.
- published: 13 Apr 2015
- views: 25542
PLAYLIST TIME:
PLAYLIST TIME:
9:38
Phase Transitions
Looking at the Gibbs energy shows us that ordered phases (like a solid) will always underg...
published: 05 Dec 2020
Phase Transitions
Phase Transitions
- Report rights infringement
- published: 05 Dec 2020
- views: 17368
Looking at the Gibbs energy shows us that ordered phases (like a solid) will always undergo a transition and convert to more disordered phases (like a gas) if the temperature is increased enough.
10:28
Phase Diagrams of Water & CO2 Explained - Chemistry - Melting, Boiling & Critical Point
This chemistry video tutorial explains the concepts behind the phase diagram of CO2 / Carb...
published: 06 Oct 2016
Phase Diagrams of Water & CO2 Explained - Chemistry - Melting, Boiling & Critical Point
Phase Diagrams of Water & CO2 Explained - Chemistry - Melting, Boiling & Critical Point
- Report rights infringement
- published: 06 Oct 2016
- views: 711022
This chemistry video tutorial explains the concepts behind the phase diagram of CO2 / Carbon Dioxide and the phase diagram of water / H2O. This video contains plenty of examples and practice problems:
Chapter 10 - Video Lessons:
https://www.video-tutor.net/liquids-and-solids.html
______________________________
Boyle's Law Practice Problems:
https://www.youtube.com/watch?v=v8r_AU_TlPg
How Does a Bike Pump Work?
https://www.youtube.com/watch?v=I0b_i6-HLBA
Charles Law:
https://www.youtube.com/watch?v=uZ2d79NFx2w
Gay Lussac's Law:
https://www.youtube.com/watch?v=RszgzH_2A9k
Avogadro's Law:
https://www.youtube.com/watch?v=Czo2rIai5u0
Ideal Gas Law Problems:
https://www.youtube.com/watch?v=LZUs6nawHAk
_____________________________
Translational Kinetic Energy:
https://www.youtube.com/watch?v=bg5d5BFANVU
Molecular Speed of Gases:
https://www.youtube.com/watch?v=0m25oTKMv1Y
Mean Free Path and Free Time:
https://www.youtube.com/watch?v=ypK7h3NKe1E
RMS vs Average Speed:
https://www.youtube.com/watch?v=hBlwfG6IBLg
Molar Heat Capacities of Gases:
https://www.youtube.com/watch?v=SwMODT8m4Ls
____________________________
Relative Humidity & Dew Point:
https://www.youtube.com/watch?v=BqFVtlQa-2w
Fick's Law of Diffusion:
https://www.youtube.com/watch?v=JgAKv1Zlgcw
Open Vs Closed Vs Isolated System:
https://www.youtube.com/watch?v=TFP6SvWPOQc
First Law of Thermodynamics:
https://www.youtube.com/watch?v=7Siv2NNCFag
Final Exams and Video Playlists:
https://www.video-tutor.net/
Physics PDF Worksheets:
https://www.video-tutor.net/physics-basic-introduction.html
Here is a list of topics:
1. Phase Changes
2. Freezing - Liquid to Solid
3. Melting - Solid to Liquid
4. Vaporization - Liquid to Gas
5. Condensation - Gas to Liquid
6. Sublimation - Solid to Gas
7. Deposition - Gas to Solid
8. Phase Diagram of CO2 - Carbon Dioxide - Sublimation
9. Melting Point Curve vs Boiling Point Curve
10. Normal Atmospheric Pressure of 1 Atm
11. Definition of Normal Melting Point and Normal Boiling Point
12. Solid, Liquid, and Gas Phases
13. Critical Point, Critical Temperature, and Critical Pressure
14. Supercritical Fluids -
15. Density of Solids vs Liquids for CO2
16. Why ice is less dense that water
17. Melting Point Curve - Negative Slope for H2O vs Positive Slope for CO2 - Density & Pressure
2:47
Phase Transition - Your Guide (Official Music Video)
Follow us:
Instagram: https://www.instagram.com/phase.transition.official/
Facebook: http:...
published: 12 May 2023
Phase Transition - Your Guide (Official Music Video)
Phase Transition - Your Guide (Official Music Video)
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- published: 12 May 2023
- views: 1594
Follow us:
Instagram: https://www.instagram.com/phase.transition.official/
Facebook: http://facebook.com/phase.transition.official
TikTok: https://www.tiktok.com/@phasetransition
MUSIC
Vocals - Sofia Beco
Guitar - Luís Dias
Bass - Zé Pereira
Drums - Fernando Maia
Mixed and Mastered by Afonso Aguiar at TitanForged Productions.
Recorded by Afonso Aguiar.
VÍDEO
Vídeo Produced by Coalblur.
Concept by Phase Transition and Coalblur.
Directed by Sara Gonçalves.
Filmed by João Martins and Tiago Sousa.
Edited by Tiago Sousa.
4:51
Phase Changes, Heats of Fusion and Vaporization, and Phase Diagrams
What the heck is dry ice and why is it so spooky? Learn this and more when we investigate ...
published: 05 Dec 2015
Phase Changes, Heats of Fusion and Vaporization, and Phase Diagrams
Phase Changes, Heats of Fusion and Vaporization, and Phase Diagrams
- Report rights infringement
- published: 05 Dec 2015
- views: 353761
What the heck is dry ice and why is it so spooky? Learn this and more when we investigate phase changes and phase diagrams!
Watch the whole General Chemistry playlist: http://bit.ly/ProfDaveGenChem
Study for the AP Chemistry exam with me: https://bit.ly/ProfDaveAPChem
Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem
Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem
Biology Tutorials: http://bit.ly/ProfDaveBio
Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1
Modern Physics Tutorials: http://bit.ly/ProfDavePhysics2
Mathematics Tutorials: http://bit.ly/ProfDaveMaths
EMAIL► ProfessorDaveExplains@gmail.com
PATREON► http://patreon.com/ProfessorDaveExplains
Check out "Is This Wi-Fi Organic?", my book on disarming pseudoscience!
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9:33
Phase Changes
To see all my Chemistry videos, check out
http://socratic.org/chemistry
What does a phase...
published: 06 Oct 2011
Phase Changes
Phase Changes
- Report rights infringement
- published: 06 Oct 2011
- views: 413970
To see all my Chemistry videos, check out
http://socratic.org/chemistry
What does a phase change look like at the molecular level? We'll look at the molecular structure in solid, liquid, and gas phases, and see how the kinetic energy of the particles changes. We'll talking about melting, vaporization, condensation, and freezing.
26:52
Percolation: a Mathematical Phase Transition
—————SOURCES————————————————————————
Percolation – Béla Bollobás and Oliver Riordan
Cambr...
published: 09 Aug 2022
Percolation: a Mathematical Phase Transition
Percolation: a Mathematical Phase Transition
- Report rights infringement
- published: 09 Aug 2022
- views: 334471
—————SOURCES————————————————————————
Percolation – Béla Bollobás and Oliver Riordan
Cambridge University Press, New York, 2006.
Sixty Years of Percolation – Hugo Duminil-Copin
https://www.ihes.fr/~duminil/publi/2018ICM.pdf
Percolation – Geoffrey Grimmett
volume 321 of Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences]. Springer-Verlag, Berlin, second edition, 1999.
—————NOTES—————————————————————————
Note at 10:42 – The uniqueness of the infinite cluster is known for the d-dimenional lattice since the works of Aizenman, Kesten and Newman - [Uniqueness of the infinite cluster and continuity of connectivity functions for short and long range percolation (1987)] and Burton and Keane - [Density and uniqueness in percolation (1989)]. It does not hold in general: when the graph in question is a regular tree for example, there are always infinitely many clusters during the supercritical phase.
The two last results shown here are only known for site percolation (in which vertices are open or closed instead of edges) in the triangular lattice, where a scaling limit for the boundaries of critical clusters was proved to exist (more on that in the third note). It is believed that these results are universal, that is, valid in great generality for planar percolation processes near criticality.
The third result is from an appendix by Gábor Pete in the paper [Scaling limits for the threshold window: When does a monotone Boolean function flip its outcome? (2017)] by Ahlberg and Steif. Consider an n by n box, and the event where there exists a left-right crossing of said box. Recall the uniform coupling from the video: intuitively, the result is saying that the point at which this crossing emerges in the uniform coupling is with high probability inside an interval of size n^{-3/4} around 1/2.
The fourth result is saying that the average size of the cluster of the origin (or any other given point) goes to infinity as we let p approach the critical parameter like a specific power of the distance between p and p_c. This power is called a critical exponent. The existence of these exponents was proved by Smirnov and Werner in the paper [Critical exponents for two-dimensional percolation (2001)].
Note at 10:52 – Hugo Duminil-Copin has several major contributions to the study of processes arising in statistical physics, including Bernoulli percolation. Among his works on Ising and Ising-like processes we can cite [Random Currents and Continuity of Ising Model’s Spontaneous Magnetization (2015)] with Aizenman and Sidoravicius and [Sharp phase transition for the random-cluster and Potts models via decision trees (2019)] with Raoufi and Tassion.
Note at 12:38 – In the triangular lattice site percolation, Stanislav Smirnov proved the conformal invariance of crossing probabilities at criticality (see https://www.unige.ch/~smirnov/papers/icmp-final.pdf for an overview), which led to the proof of the existence of scaling limits of exploration curves as Schramm–Loewner evolution processes. See [Critical percolation in the plane (2009)] by Smirnov. This provided a deep understanding of the critical phase in the triangular lattice site percolation, which to this day is not extended to the square lattice.
Note at 17:52 – It is not at all obvious that the probability of being connected to infinity is continuous above criticality. This result can be proved in the d-dimenional hypercubic lattices using the uniqueness of the infinite cluster, and more generally it was proved for transitive graphs (intuitively, graphs in which all vertices look the same) by Häggström, Peres and Schonmann in [Percolation on transitive graphs as a coalescent process: Relentless merging followed by simultaneous uniqueness (1999)].
—————SECTIONS———————————————————————
0:00 Introduction
1:37 Definition – Bernoulli Percolation
5:23 Definition – Uniform Coupling
7:56 Exploration – High-Resolution Square Grid
9:40 Exploration – Questions and Kesten's Theorem
10:58 Exploration – Ising Model
11:54 Exploration – Critical Percolation
12:50 Exploration – Three-Dimensional Cubic Lattice and Beyond
14:13 Proof – Theorem Statement
15:14 Proof – Simplifications
16:29 Proof – Definition of Critical Parameter
18:41 Proof – Critical Parameter is Greater Than Zero
20:44 Proof – Duality Definition
21:56 Proof – Critical Parameter is Less Than One
25:16 Proof – Summary and Idea for Kesten's Theorem
26:11 Conclusion
—————CREDITS————————————————————————
Caio Alves – writing, 3D animation
Aranka Hrušková – writing, clarinet
Vilas Winstein – writing, 2D animation, editing, voice-over
Special thanks to Anisah Awad, Gábor Pete, Jyotsna Sreenivasan, Angie Zavala
This video is an entry in the second Summer of Mathematics Exposition (#SoME2)
The photographs used in this video are licensed under the Creative Commons Attribution-ShareAlike license:
https://creativecommons.org/licenses/by-sa/4.0/deed.en
12:10
What is a phase transition?
Try Audible and get up to two free audiobooks: https://amzn.to/3Torkbc
Hey everyone!
I...
published: 15 Sep 2021
What is a phase transition?
What is a phase transition?
- Report rights infringement
- published: 15 Sep 2021
- views: 3514
Try Audible and get up to two free audiobooks: https://amzn.to/3Torkbc
Hey everyone!
I am back with a new guest speaker, Steven Silber. In this video Steven motivates the topic of thermodynamic phase transitions in preparation for his follow-up videos on modelling them.
Recommended textbooks:
Quantum mechanics:
https://amzn.to/3Ar5dbn or https://amzn.to/3ckXkfL
Statistical mechanics:
https://amzn.to/3QYcere or https://amzn.to/3cmZb3u
Quantum information:
https://amzn.to/3Kpjt96 or https://amzn.to/3KpjAl2
My publication list: https://scholar.google.com/citations?user=V2UZXZMAAAAJ&hl;=en
Instagram: https://www.instagram.com/stat.mech.in.action/
TikTok: https://www.tiktok.com/@stat.mech.in.action?lang=en
Twitter: https://twitter.com/JonathonRiddell
Discord: https://discord.gg/QK9HhuXBEF
4:01
PHASE CHANGES | Science 8 Quarter 3:Module 2
published: 19 Feb 2022
PHASE CHANGES | Science 8 Quarter 3:Module 2
PHASE CHANGES | Science 8 Quarter 3:Module 2
- Report rights infringement
- published: 19 Feb 2022
- views: 35722
30:36
Railroader Ep 17 - Phase 3 finish Ela Bridge open
Experience the romance of the transition era as you take the reins of vintage locomotives,...
published: 27 Dec 2023
Railroader Ep 17 - Phase 3 finish Ela Bridge open
Railroader Ep 17 - Phase 3 finish Ela Bridge open
- Report rights infringement
- published: 27 Dec 2023
- views: 28
Experience the romance of the transition era as you take the reins of vintage locomotives, master intricate operations, and witness the beauty of a bygone era brought to life.
Railroader is an operations-focused railroad simulator set in transition era Appalachia. Manage and run your railroad to your desire while using period steam and diesel locomotives and rolling stock.
6:24
Phase Transitions & Bifurcations
Take the full course: https://www.systemsinnovation.network/courses/7297973/
Twitter: http...
published: 13 Apr 2015
Phase Transitions & Bifurcations
Phase Transitions & Bifurcations
- Report rights infringement
- published: 13 Apr 2015
- views: 25542
Take the full course: https://www.systemsinnovation.network/courses/7297973/
Twitter: http://bit.ly/2JuNmXX
LinkedIn: http://bit.ly/2YCP2U6
A phase transition is the transformation of a system from one state to another through a period of rapid change. The classical example of this is the transition between solid, liquid and gaseous states that water passes through given some change in temperature, phase transitions are another hallmark of nonlinear systems. In this module we discuss the concept in tandem with its counterpart bifurcation theory.
Transcription excerpt:
Bifurcations & Phase transitions
As we have previously discussed the qualitative dynamic behavior of nonlinear systems is largely defined by the positive and negative feedback loops that regulate their development, with negative feedback working to dampen down or constrain change to a linear progression, while positive feedback works to amplify change typically in an super-linear fashion.
As opposed to negative feedback where we get a gradual and often stable development over a prolonged period of time, what we might call a normal or equilibrium state of development, positive feedback is characteristic of a system in a state of nonequilibrium. Positive feedback development is fundamentally unsustainable because all systems in reality exist in an environment that will ultimately place a limit on this grown.
From this we can see how the exponential grow enabled by positive feedback loops is what we might say special, it can only exist for a relatively brief period of time, when we look around us we see the vast majority of things are in a stable configuration constrained by some negative feedback loop whether this is the law of gravity, predator prey dynamics or the economic laws of having to get out of bed and go to work every day. These special periods of positive feedback development are characteristic and a key diver of what we call phase transitions.
A phase transition may be defined as some smooth, small change in a quantitative input variable that results in a qualitative change in the system’s state. The transition of ice to steam is one example of a phase transition. At some critical temperature a small change in the systems input temperature value results in a systemic change in the substance after which it is governed by a new set of parameters and properties, for example we can talk about cracking ice but not water, or we can talk about the viscosity of a liquid but not a gas as these are in different phases under different physical regimes and thus we describe them with respect to different parameters.
Another example of a phase transition may be the changes within a colony of bacteria that when we change the heat and nutrient input to the system we change the local interactions between the bacteria and get a new emergent structure to the colony, although this change in input value may only be a linear progression it resulted in a qualitatively different pattern emerging on the macro level of the colony. It is not simply that a new order or structure has emerged but the actual rules that govern the system change and thus we use the word regime and talk about it as a regime shift, as some small changes in a parameter that affected the system on the local level leads to different emergent structures that then feedback to define a different regime that the elements now have to operate under.
Another way of talking about this is in the language of bifurcation theory, whereas with phase transitions we are talking about qualitative changes in the properties of the system, bifurcation theory really talks about how a small change in parameter can causes a topological change in a system’s environment resulting in new attractor states emerging. A bifurcation means a branching, in this case we are talking about a point where the future trajectory of an element in the system divides or branches out, as new attractor states emerge, from this critical point it can go in two different trajectories which are the product of these attractors, each branch represents a trajectory into a new basin of attraction with a new regime and equilibrium.
Phase change
Phase change may refer to:
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Phase_change
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Is Your Love Strong Enough
by: Tangerine DreamJust one step at a time
And closer to destiny
I knew at a glance
There'd always be a chance for me
With someone I could live for
Nowhere I would rather be
Is your love strong enough
Like a rock in the sea
Am I asking too much
Is your love strong enough?
Just one beat of your heart
And stranger than fantasy
I knew from the start
It had to be the place for me
Someone that I would die for
There's no way I could ever leave
Is your love strong enough
Like a rock in the sea
Am I asking too much
Is your love strong enough?
Is your love strong enough?
Just one beat of your heart
Is your love strong enough?
Is your love strong enough?
Is your love strong enough?
Is your love strong enough?
Is your love strong enough?
Just one beat of your heart
Strong enough?
Strong enough?
Just one beat of your heart
Strong enough?
Strong enough?
Just one beat of your heart
Strong enough?
Strong enough?
Just one beat of your heart
Strong enough?
Strong enough?
Just one beat of your heart
Strong enough?
Strong enough?
Just one beat of your heart