- published: 10 Oct 2023
- views: 239373
Create your page here
-
remove the playlistElementary Particle
- remove the playlistElementary Particle
Please tell us which country and city you'd like to see the weather in.
'+tempC+' °C
'
}
weather_info += '- Pressure: '+weather_data.main.pressure+' hPa ' if (weather_data.main.humidity) { weather_info += '
- Humidity: '+weather_data.main.humidity+' % '; } if (clouds) { weather_info += '
- Clounds: '+clouds.all+'% ' } if (weather) { weather_info += '
- '+weather.description+' ' } weather_info += '
'+mobj.calendar()+'
';
weather_info += '
'
weather_info += ''
if (country == 'United States'){
weather_info += '
'+tempF+' °F
'
}else{
weather_info += ''+tempC+' °C
'
}
weather_info += '- '+value.pressure+' hPa ' if (value.humidity) { weather_info += '
- Humidity: '+value.humidity+' % '; } if (clouds) { weather_info += '
- Clouds: '+clouds+'% ' } if (weather) { weather_info += '
- ' +weather.description+' ' } weather_info += '
Elementary particle
In particle physics, an elementary particle or fundamental particle is a particle whose substructure is unknown, thus it is unknown whether it is composed of other particles. Known elementary particles include the fundamental fermions (quarks, leptons, antiquarks, and antileptons), which generally are "matter particles" and "antimatter particles", as well as the fundamental bosons (gauge bosons and the Higgs boson), which generally are "force particles" that mediate interactions among fermions. A particle containing two or more elementary particles is a composite particle.
Everyday matter is composed of atoms, once presumed to be matter's elementary particles—atom meaning "indivisible" in Greek—although the atom's existence remained controversial until about 1910, as some leading physicists regarded molecules as mathematical illusions, and matter as ultimately composed of energy. Soon, subatomic constituents of the atom were identified. As the 1930s opened, the electron and the proton had been observed, along with the photon, the particle of electromagnetic radiation. At that time, the recent advent of quantum mechanics was radically altering the conception of particles, as a single particle could seemingly span a field as would a wave, a paradox still eluding satisfactory explanation.
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Elementary_particle
Aube
Aube (French pronunciation: [ob]) is a French department in the Alsace-Champagne-Ardenne-Lorraine region of north-eastern France. As with sixty departments in France, this department is named after a river: the Aube. With 305,606 inhabitants (2012), Aube is 76th department in terms of population. The inhabitants of the department are known as Aubois or Auboises
The department was constituted as it is today by a decree of the National Assembly of 15 January 1790.
Geography
Location
The Aube department is located in the south-west side of the Alsace-Champagne-Ardenne-Lorraine region. It borders the departments of Marne in the north (about 130 km long), Haute-Marne to the east (about 100 km long), Côte-d'Or in the south-east (about 45 km long), Yonne in the south-west (about 175 km long), and Seine-et-Marne in the west (about 45 km long).
Subregions of Aube
Within the department regions of natural or traditional countryside can be identified as follows:
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Aube
Aube (disambiguation)
Aube is a department in the northeastern part of France.
Aube may also refer to:
See also
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Aube_(disambiguation)
Aube (river)
The Aube is a river in France, right tributary of the Seine. It is 248 kilometres (154 mi) long. The river gives its name to the Aube département.
Its source is in the Haute-Marne département, on the plateau of Langres, near the town Auberive. It flows through the départements Haute-Marne, Côte-d'Or, Aube, and Marne. It flows into the river Seine near Marcilly-sur-Seine. Cities along the river include Bar-sur-Aube and Arcis-sur-Aube.
Main tributaries
Departments and towns crossed
See also
References
External links
Media related to Aube River at Wikimedia Commons
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Aube_(river)
Radio Stations - Département de l'Aube
SEARCH FOR RADIOS
Podcasts:
Aube
ALBUMS
- Variable Ambit released: 2011
- Metal on Metal released: 2008
- Ambera Planeta Wawar released: 2007
- Imagery Resonance released: 2007
- Reworks Nimh, Volume 1 released: 2007
- Comet released: 2006
- Reworks Maurizio Bianchi, Volume 2 released: 2006
- Mectpyo Saisei released: 2005
- Junkyo released: 2005
- Chain [Re] Action released: 2005
- Reworks Maurizio Bianchi, Volume 1 released: 2005
- Reworks Stefano Gentile released: 2005
- Duplex-Sphere released: 2004
- Tapes 1992-1997 released: 2003
- Vinyls 1996 + 1998 released: 2003
- Vinyls 1995 + 1997 released: 2003
- Data-X released: 2002
- Redintegration released: 2002
- Spatio Temporal Cluster released: 2002
- Millennium released: 2002
- Millennium: December released: 2002
- Millennium: November released: 2002
- Millennium: October released: 2002
- RM4 released: 2002
- Howling Obsession (Revised) released: 2002
- Timemind released: 2001
- Millennium: Iulius released: 2001
- Millennium: Augustus released: 2001
- Millennium: September released: 2001
- Sensorial Inducement released: 2000
- 365-2001 released: 2000
- Millennium: Iunius released: 2000
- Millennium: Maius released: 2000
- Millennium: Aprilis released: 2000
- Millennium: Februarius released: 2000
- Millennium: Ianuarius released: 2000
- Millennium: Martius released: 2000
- Triad Thread released: 2000
- Set On released: 2000
- Solid Pressure released: 2000
- Suppression Disorder released: 1999
- Shade-Away released: 1999
- Ricochetentrance released: 1999
- 108 released: 1999
- Mutation released: 1999
- Blood-Brain Barrier released: 1999
- Deglaze released: 1998
- Cerebral Disturbance released: 1998
- 3 Cadavres Exquis released: 1998
- Splinter Clear Cut / Joyous Smash released: 1998
- Flare released: 1998
- Substructural Penetration 1991-1995 released: 1998
- Flush released: 1998
- Embers released: 1998
- Pages From the Book released: 1998
- Evocation released: 1998
- Vas in Euthymic Violet released: 1997
- Throb in Manic Red released: 1997
- Sigh in Depressive Blue released: 1997
- Aube / Knurl Split released: 1997
- Stared Gleam released: 1997
- New Forms of Free Entertainment released: 1997
- Dazzle Reflexion released: 1997
- Aqua Syndrome released: 1997
- Cardiac Strain released: 1997
- Grind Carve released: 1996
- Feed the Fishes released: 1996
- Quadrotation released: 1996
- Infinitely Orbit released: 1996
- Maschinenwerk released: 1996
- The Mind of a Missile released: 1996
- Métal de Métal released: 1996
- Pulse Resonator released: 1995
- Metalustration released: 1995
- Entangle Spirant released: 1995
- Magnetostriction released: 1995
- Purification to Numbness released: 1995
- Wired Trap released: 1995
- Frequency for Collapse released: 1994
- Emotional Oscillation released: 1994
- Recycled released: 1994
- E-Power released: 1994
- Flood-Gate released: 1993
- Luminous released: 1993
- Flash-Point released: 1993
- Spindrift released: 1992
Aube
ALBUMS
- ケミカルサーカス released: 2012
-
All Fundamental Forces and Particles Explained Simply | Elementary particles
The standard model of particle physics (In this video I explained all the four fundamental forces and elementary particles) To know more about Elementary particles, I recommend to read this book (Facts and Mysteries in Elementary Particle) : https://amzn.to/46RFcSu To support on patreon (video script with high-res art works) : https://patreon.com/Klonusk975 Contact : [email protected] #standardmodel #force
published: 10 Oct 2023 -
What’s the smallest thing in the universe? - Jonathan Butterworth
Check out our Patreon page: https://www.patreon.com/teded View full lesson: https://ed.ted.com/lessons/the-standard-model-of-particle-physics-jonathan-butterworth If you were to take a coffee cup, and break it in half, then in half again, and keep carrying on, where would you end up? Could you keep on going forever? Or would you eventually find a set of indivisible building blocks out of which everything is made? Jonathan Butterworth explains the Standard Model theory and how it helps us understand the world we live in. Lesson by Jon Butterworth, directed by Nick Hilditch. Thank you so much to our patrons for your support! Without you this video would not be possible! Jennifer Kurkoski, phkphk12321, Arlene Weston, Mehmet Yusuf Ertekin, Ten Cha, Les Howard, Kevin O'Leary, Francisco Leo...
published: 15 Nov 2018 -
The Map of Particle Physics | The Standard Model Explained
In this video I explain all the basics of particle physics and the standard model of particle physics. Check out Brilliant here: https://brilliant.org/DOS/ Buy the poster here: https://store.dftba.com/collections/domain-of-science/products/map-of-fundamental-particles Digital version here: https://www.flickr.com/photos/95869671@N08 The standard model of particle physics is our fundamental description of the stuff in the universe. It doesn’t answer why anything exists, but does describe what exists and how it behaves, and that’s what we’ll be discovering in this video. We will cover the fermions, which contain the quarks and the leptons, as well as the bosons or force carriers. As well as which of the fundamental forces each of these fundamental particles interact with, along with the Higg...
published: 01 May 2021 -
All Elementary Particles Explained
---------------------------------------------------------------------------------------------------- In case you'd like to support me: patreon.com/sub2MAKiT my discord: https://discord.gg/TSEBQvsWBr ---------------------------------------------------------------------------------------------------- Other MAKiTs: @MAKiTResearch @mktcharity @makitmovies @makitshitpost ----------------------------------------------------------------------------------------------------- Sources: https://archive.org/details/deepdownthingsbr00schu/mode/1up https://www.hep.phy.cam.ac.uk/~thomson/lectures/partIIIparticles/Handout7_2009.pdf https://www.osti.gov/biblio/4008239 https://pdglive.lbl.gov/Particle.action?node=Q004&init=0 https://arxiv.org/pdf/2204.07269 https://home.cern/news/news/physics/first-obs...
published: 04 Dec 2024 -
The Standard Model of Particle Physics
Once you start learning about modern physics, you start to hear about weird particles like quarks and muons and neutrinos. What are all these things? Why are there so many? How do we know they exist? What do they do? Let's check out the standard model of particle physics. Watch the whole Modern Physics playlist: http://bit.ly/ProfDavePhysics2 Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1 Mathematics Tutorials: http://bit.ly/ProfDaveMaths General Chemistry Tutorials: http://bit.ly/ProfDaveGenChem Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem Biology Tutorials: http://bit.ly/ProfDaveBio EMAIL► [email protected] PATREON► http://patreon.com/ProfessorDaveExplains Check out "Is This Wi-Fi Organic?"...
published: 05 Jun 2017 -
Classification of Elementary Particles | Jeya P | Department of Physics
Nuclear Particle and Astro Physics #NuclearPhysics #ParticlePhysics #AstroPhysics
published: 12 Jan 2021 -
Particle Physics Explained Visually in 20 min | Feynman diagrams
Get MagellanTV here: https://try.magellantv.com/arvinash and get an exclusive offer for our viewers: an extended, month-long trial, FREE. MagellanTV has the largest and best collection of Science content anywhere, including Space, Physics, Technology, Nature, Mind and Body, and a growing collection of 4K. This new streaming service has 3000 great documentaries. Check out our personal recommendation and MagellanTV’s exclusive playlists: https://www.magellantv.com/genres/science-and-tech If you didn't understand this video, these may help: https://youtu.be/xZqID1zSm0k -- Mechanism of the fundamental forces https://youtu.be/jlEovwE1oHI -- What are quantum fields? 0:00 - Intro & Fields 2:22 - Special offer 3:09 - Particles, charges, forces 6:32 - Recap 7:13 - Electromagnetism 10:04 - Weak f...
published: 20 Dec 2020 -
The Standard Model of Particle Physics: A Triumph of Science
The Standard Model of particle physics is the most successful scientific theory of all time. It describes how everything in the universe is made of 12 different types of matter particles, interacting with three forces, all bound together by a rather special particle called the Higgs boson. It’s the pinnacle of 400 years of science and gives the correct answer to hundreds of thousands of experiments. In this explainer, Cambridge University physicist David Tong recreates the model, piece by piece, to provide some intuition for how the fundamental building blocks of our universe fit together. At the end of the video, he also points out what’s missing from the model and what work is left to do in order to complete the Theory of Everything. **Correction: At 13'50", the photon should be includ...
published: 16 Jul 2021 -
LIVE! PSW 2506 The Science Driving Particle Physics and Big Accelerators
Join PSW Science® on December 6th at 8 PM as we welcome speaker JoAnne Hewett, Director of Brookhaven National Laboratory. This presentation will describe the decadal vision laid out in the recent national strategic plan for particle physics, how it dovetails with global endeavors, and how it places the nation on the threshold of a new era of insight and discovery. During the question and answer period, in-person attendees and live stream viewers may ask the speaker questions, and in-person attendees may also engage with the speaker during the post-lecture reception. Refreshments are served. For more information on this meeting, please visit: https://pswscience.org/meeting/2506/ The meeting will be held in the John Wesley Powell Auditorium, adjacent to the Cosmos Club. The Powell Auditori...
published: 07 Dec 2024 -
Classification of Particles - A Level Physics
From the standard model, we can classify particles into two categories, hadrons and leptons. Examples of hadrons are protons and neutrons. Electrons are leptons because they are fundamental particles. Music credit: Song: Dipcrusher - Islands (Vlog No Copyright Music) Music provided by Vlog No Copyright Music. Video Link: https://youtu.be/CpFneq3zIt4 Music credit
published: 27 Mar 2020
developed with YouTube
19:13
All Fundamental Forces and Particles Explained Simply | Elementary particles
- Order: Reorder
- Duration: 19:13
- Uploaded Date: 10 Oct 2023
- views: 239373
The standard model of particle physics (In this video I explained all the four fundamental forces and elementary particles)
To know more about Elementary part...
The standard model of particle physics (In this video I explained all the four fundamental forces and elementary particles)
To know more about Elementary particles, I recommend to read this book (Facts and Mysteries in Elementary Particle) : https://amzn.to/46RFcSu
To support on patreon (video script with high-res art works) : https://patreon.com/Klonusk975
Contact : [email protected]
#standardmodel #force
https://wn.com/All_Fundamental_Forces_And_Particles_Explained_Simply_|_Elementary_Particles
The standard model of particle physics (In this video I explained all the four fundamental forces and elementary particles)
To know more about Elementary particles, I recommend to read this book (Facts and Mysteries in Elementary Particle) : https://amzn.to/46RFcSu
To support on patreon (video script with high-res art works) : https://patreon.com/Klonusk975
Contact : [email protected]
#standardmodel #force
5:21
What’s the smallest thing in the universe? - Jonathan Butterworth
- Order: Reorder
- Duration: 5:21
- Uploaded Date: 15 Nov 2018
- views: 1272541
Check out our Patreon page: https://www.patreon.com/teded
View full lesson: https://ed.ted.com/lessons/the-standard-model-of-particle-physics-jonathan-butterwo...
Check out our Patreon page: https://www.patreon.com/teded
View full lesson: https://ed.ted.com/lessons/the-standard-model-of-particle-physics-jonathan-butterworth
If you were to take a coffee cup, and break it in half, then in half again, and keep carrying on, where would you end up? Could you keep on going forever? Or would you eventually find a set of indivisible building blocks out of which everything is made? Jonathan Butterworth explains the Standard Model theory and how it helps us understand the world we live in.
Lesson by Jon Butterworth, directed by Nick Hilditch.
Thank you so much to our patrons for your support! Without you this video would not be possible! Jennifer Kurkoski, phkphk12321, Arlene Weston, Mehmet Yusuf Ertekin, Ten Cha, Les Howard, Kevin O'Leary, Francisco Leos, Robert Patrick, Jorge, Marcus Appelbaum, Alan Wilder, Amin Talaei, Mohamed Elsayed, Angel Pantoja, Eimann P. Evarola, Claire Ousey, Carlos H. Costa, Tariq Keblaoui, Bela Namyslik, Nick Johnson, Won Jang, Johnnie Graham, Junjie Huang, Harshita Jagdish Sahijwani, Amber Alexander, Yelena Baykova, Laurence McMillan, John C. Vesey, Karmi Nguyen, Chung Wah Gnapp, Andrew Sprott, Jane White, Ayan Doss, BRENDAN NEALE, Lawrence Teh Swee Kiang, Alex Pierce, Nick Cozby, Jeffrey Segrest, Anthony Arcis, Ugur Doga Sezgin, Kathryn Vacha, Allyson Martin, Srinivasa C Pasumarthi, 张晓雨, Ann Marie Reus, Nishant Suneja, Javier Lara Rosado, Jerry Yang and Shubham Arora.
https://wn.com/What’S_The_Smallest_Thing_In_The_Universe_Jonathan_Butterworth
Check out our Patreon page: https://www.patreon.com/teded
View full lesson: https://ed.ted.com/lessons/the-standard-model-of-particle-physics-jonathan-butterworth
If you were to take a coffee cup, and break it in half, then in half again, and keep carrying on, where would you end up? Could you keep on going forever? Or would you eventually find a set of indivisible building blocks out of which everything is made? Jonathan Butterworth explains the Standard Model theory and how it helps us understand the world we live in.
Lesson by Jon Butterworth, directed by Nick Hilditch.
Thank you so much to our patrons for your support! Without you this video would not be possible! Jennifer Kurkoski, phkphk12321, Arlene Weston, Mehmet Yusuf Ertekin, Ten Cha, Les Howard, Kevin O'Leary, Francisco Leos, Robert Patrick, Jorge, Marcus Appelbaum, Alan Wilder, Amin Talaei, Mohamed Elsayed, Angel Pantoja, Eimann P. Evarola, Claire Ousey, Carlos H. Costa, Tariq Keblaoui, Bela Namyslik, Nick Johnson, Won Jang, Johnnie Graham, Junjie Huang, Harshita Jagdish Sahijwani, Amber Alexander, Yelena Baykova, Laurence McMillan, John C. Vesey, Karmi Nguyen, Chung Wah Gnapp, Andrew Sprott, Jane White, Ayan Doss, BRENDAN NEALE, Lawrence Teh Swee Kiang, Alex Pierce, Nick Cozby, Jeffrey Segrest, Anthony Arcis, Ugur Doga Sezgin, Kathryn Vacha, Allyson Martin, Srinivasa C Pasumarthi, 张晓雨, Ann Marie Reus, Nishant Suneja, Javier Lara Rosado, Jerry Yang and Shubham Arora.
- published: 15 Nov 2018
- views: 1272541
31:48
The Map of Particle Physics | The Standard Model Explained
- Order: Reorder
- Duration: 31:48
- Uploaded Date: 01 May 2021
- views: 1578467
In this video I explain all the basics of particle physics and the standard model of particle physics. Check out Brilliant here: https://brilliant.org/DOS/
Buy ...
In this video I explain all the basics of particle physics and the standard model of particle physics. Check out Brilliant here: https://brilliant.org/DOS/
Buy the poster here: https://store.dftba.com/collections/domain-of-science/products/map-of-fundamental-particles
Digital version here: https://www.flickr.com/photos/95869671@N08
The standard model of particle physics is our fundamental description of the stuff in the universe. It doesn’t answer why anything exists, but does describe what exists and how it behaves, and that’s what we’ll be discovering in this video. We will cover the fermions, which contain the quarks and the leptons, as well as the bosons or force carriers. As well as which of the fundamental forces each of these fundamental particles interact with, along with the Higgs field. We’ll also look at the conservation rules of particle physics, symmetries in physics and the various quantum numbers that rule which particle interactions are valid and which are not.
#particlephysics #standardmodel #DomainOfScience
--- Posters ----
DFTBA Store: https://store.dftba.com/collections/domain-of-science
RedBubble Store: https://www.redbubble.com/people/DominicWalliman
I have also made posters available for educational use which you can find here: https://www.flickr.com/photos/95869671@N08/
-- Some Awesome People ---
And many thanks to my $10 supporters on Patreon, you are awesome!
Bob Milano
Alex Polo
Eric Epstein
Kevin Delaney
Mark Pickenheim
noggieB
Raj Duphare
Reggie Fourmyle
Sandy Toye
Sebastian
Terrence Masson
Join the gang and help support me produce free and high quality science content:
https://www.patreon.com/domainofscience
--- Special Thanks ---
Special thanks to Sarah Johnson https://twitter.com/SJDJ and Henry Reich https://www.youtube.com/user/minutephysics for their fact checking help.
--- My Science Books ----
I also write science books for kids called Professor Astro Cat. You can see them all here:
http://profastrocat.com
--- Follow me around the internet ---
http://dominicwalliman.com
https://twitter.com/DominicWalliman
https://www.instagram.com/dominicwalliman
--- Credits ---
Art, animation, presented by Dominic Walliman
References
[1] good summary
https://physics.info/standard/
[2] CPT symmetry
en.wikipedia.org/wiki/CP_violation
[3] Arvin Ash video
https://youtu.be/gkHmXhhAF2Y
[4] Conservation rules video
https://www.youtube.com/watch?v=dkFr3BGO8Dg
[5] More conservation rules
https://www.youtube.com/watch?v=qbf7y7Uv6d4
[6] Particle conservation laws
https://bit.ly/3pIb05M
[7] Short explanation of spin
https://bit.ly/2R7UIGV
[8] Short video explaining spin
https://youtu.be/cd2Ua9dKEl8
[9] Pauli exclusion principle
https://bit.ly/3mr4bF5
[10] The failure of supersymmetry
https://bit.ly/3uumFHn
[11] A nice summary of CP-symmetry
https://bit.ly/3t5WmqS
--- Chapters ---
00:00 Intro
00:28 What is particle physics?
01:33 The Fundamental Particles
02:13 Spin
3:52 Conservation Laws
5:01 Fermions and Bosons
7:40 Quarks
11:12 Color Charge
14:13 Leptons
16:39 Neutrinos
19:08 Symmetries in Physics
21:56 Conservation Laws With Forces
23:07 Summary So Far
23:36 Bosons
25:48 Gravity
26:52 Mysteries
28:24 The Future
29:08 Sponsor Message
30:12 End Ramble
https://wn.com/The_Map_Of_Particle_Physics_|_The_Standard_Model_Explained
In this video I explain all the basics of particle physics and the standard model of particle physics. Check out Brilliant here: https://brilliant.org/DOS/
Buy the poster here: https://store.dftba.com/collections/domain-of-science/products/map-of-fundamental-particles
Digital version here: https://www.flickr.com/photos/95869671@N08
The standard model of particle physics is our fundamental description of the stuff in the universe. It doesn’t answer why anything exists, but does describe what exists and how it behaves, and that’s what we’ll be discovering in this video. We will cover the fermions, which contain the quarks and the leptons, as well as the bosons or force carriers. As well as which of the fundamental forces each of these fundamental particles interact with, along with the Higgs field. We’ll also look at the conservation rules of particle physics, symmetries in physics and the various quantum numbers that rule which particle interactions are valid and which are not.
#particlephysics #standardmodel #DomainOfScience
--- Posters ----
DFTBA Store: https://store.dftba.com/collections/domain-of-science
RedBubble Store: https://www.redbubble.com/people/DominicWalliman
I have also made posters available for educational use which you can find here: https://www.flickr.com/photos/95869671@N08/
-- Some Awesome People ---
And many thanks to my $10 supporters on Patreon, you are awesome!
Bob Milano
Alex Polo
Eric Epstein
Kevin Delaney
Mark Pickenheim
noggieB
Raj Duphare
Reggie Fourmyle
Sandy Toye
Sebastian
Terrence Masson
Join the gang and help support me produce free and high quality science content:
https://www.patreon.com/domainofscience
--- Special Thanks ---
Special thanks to Sarah Johnson https://twitter.com/SJDJ and Henry Reich https://www.youtube.com/user/minutephysics for their fact checking help.
--- My Science Books ----
I also write science books for kids called Professor Astro Cat. You can see them all here:
http://profastrocat.com
--- Follow me around the internet ---
http://dominicwalliman.com
https://twitter.com/DominicWalliman
https://www.instagram.com/dominicwalliman
--- Credits ---
Art, animation, presented by Dominic Walliman
References
[1] good summary
https://physics.info/standard/
[2] CPT symmetry
en.wikipedia.org/wiki/CP_violation
[3] Arvin Ash video
https://youtu.be/gkHmXhhAF2Y
[4] Conservation rules video
https://www.youtube.com/watch?v=dkFr3BGO8Dg
[5] More conservation rules
https://www.youtube.com/watch?v=qbf7y7Uv6d4
[6] Particle conservation laws
https://bit.ly/3pIb05M
[7] Short explanation of spin
https://bit.ly/2R7UIGV
[8] Short video explaining spin
https://youtu.be/cd2Ua9dKEl8
[9] Pauli exclusion principle
https://bit.ly/3mr4bF5
[10] The failure of supersymmetry
https://bit.ly/3uumFHn
[11] A nice summary of CP-symmetry
https://bit.ly/3t5WmqS
--- Chapters ---
00:00 Intro
00:28 What is particle physics?
01:33 The Fundamental Particles
02:13 Spin
3:52 Conservation Laws
5:01 Fermions and Bosons
7:40 Quarks
11:12 Color Charge
14:13 Leptons
16:39 Neutrinos
19:08 Symmetries in Physics
21:56 Conservation Laws With Forces
23:07 Summary So Far
23:36 Bosons
25:48 Gravity
26:52 Mysteries
28:24 The Future
29:08 Sponsor Message
30:12 End Ramble
- published: 01 May 2021
- views: 1578467
28:33
All Elementary Particles Explained
- Order: Reorder
- Duration: 28:33
- Uploaded Date: 04 Dec 2024
- views: 26980
----------------------------------------------------------------------------------------------------
In case you'd like to support me:
patreon.com/sub2MAKiT
my...
----------------------------------------------------------------------------------------------------
In case you'd like to support me:
patreon.com/sub2MAKiT
my discord:
https://discord.gg/TSEBQvsWBr
----------------------------------------------------------------------------------------------------
Other MAKiTs:
@MAKiTResearch
@mktcharity
@makitmovies
@makitshitpost
-----------------------------------------------------------------------------------------------------
Sources:
https://archive.org/details/deepdownthingsbr00schu/mode/1up
https://www.hep.phy.cam.ac.uk/~thomson/lectures/partIIIparticles/Handout7_2009.pdf
https://www.osti.gov/biblio/4008239
https://pdglive.lbl.gov/Particle.action?node=Q004&init=0
https://arxiv.org/pdf/2204.07269
https://home.cern/news/news/physics/first-observation-photons-taus-proton-proton-collisions-cms
https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_(OpenStax)/University_Physics_III_-_Optics_and_Modern_Physics_(OpenStax)/11%3A_Particle_Physics_and_Cosmology/11.03%3A_Particle_Conservation_Laws
https://www.reuters.com/article/idUSL07652872/
-----------------------------------------------------------------------------------------------------
00:00 Intro
00:58 Quarks
09:34 Gluons
12:23 Photons
13:22 Electrons
18:00 Leptons
20:49 Bosons
22:17 Neutrinos
24:27 Higgs
27:11 MAKiT having a tad of a breakdown
https://wn.com/All_Elementary_Particles_Explained
----------------------------------------------------------------------------------------------------
In case you'd like to support me:
patreon.com/sub2MAKiT
my discord:
https://discord.gg/TSEBQvsWBr
----------------------------------------------------------------------------------------------------
Other MAKiTs:
@MAKiTResearch
@mktcharity
@makitmovies
@makitshitpost
-----------------------------------------------------------------------------------------------------
Sources:
https://archive.org/details/deepdownthingsbr00schu/mode/1up
https://www.hep.phy.cam.ac.uk/~thomson/lectures/partIIIparticles/Handout7_2009.pdf
https://www.osti.gov/biblio/4008239
https://pdglive.lbl.gov/Particle.action?node=Q004&init=0
https://arxiv.org/pdf/2204.07269
https://home.cern/news/news/physics/first-observation-photons-taus-proton-proton-collisions-cms
https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_(OpenStax)/University_Physics_III_-_Optics_and_Modern_Physics_(OpenStax)/11%3A_Particle_Physics_and_Cosmology/11.03%3A_Particle_Conservation_Laws
https://www.reuters.com/article/idUSL07652872/
-----------------------------------------------------------------------------------------------------
00:00 Intro
00:58 Quarks
09:34 Gluons
12:23 Photons
13:22 Electrons
18:00 Leptons
20:49 Bosons
22:17 Neutrinos
24:27 Higgs
27:11 MAKiT having a tad of a breakdown
- published: 04 Dec 2024
- views: 26980
7:33
The Standard Model of Particle Physics
- Order: Reorder
- Duration: 7:33
- Uploaded Date: 05 Jun 2017
- views: 122149
Once you start learning about modern physics, you start to hear about weird particles like quarks and muons and neutrinos. What are all these things? Why are th...
Once you start learning about modern physics, you start to hear about weird particles like quarks and muons and neutrinos. What are all these things? Why are there so many? How do we know they exist? What do they do? Let's check out the standard model of particle physics.
Watch the whole Modern Physics playlist: http://bit.ly/ProfDavePhysics2
Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1
Mathematics Tutorials: http://bit.ly/ProfDaveMaths
General Chemistry Tutorials: http://bit.ly/ProfDaveGenChem
Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem
Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem
Biology Tutorials: http://bit.ly/ProfDaveBio
EMAIL► [email protected]
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/The_Standard_Model_Of_Particle_Physics
Once you start learning about modern physics, you start to hear about weird particles like quarks and muons and neutrinos. What are all these things? Why are there so many? How do we know they exist? What do they do? Let's check out the standard model of particle physics.
Watch the whole Modern Physics playlist: http://bit.ly/ProfDavePhysics2
Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1
Mathematics Tutorials: http://bit.ly/ProfDaveMaths
General Chemistry Tutorials: http://bit.ly/ProfDaveGenChem
Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem
Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem
Biology Tutorials: http://bit.ly/ProfDaveBio
EMAIL► [email protected]
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 Jun 2017
- views: 122149
12:16
Classification of Elementary Particles | Jeya P | Department of Physics
- Order: Reorder
- Duration: 12:16
- Uploaded Date: 12 Jan 2021
- views: 85940
Nuclear Particle and Astro Physics
#NuclearPhysics #ParticlePhysics #AstroPhysics
Nuclear Particle and Astro Physics
#NuclearPhysics #ParticlePhysics #AstroPhysics
https://wn.com/Classification_Of_Elementary_Particles_|_Jeya_P_|_Department_Of_Physics
Nuclear Particle and Astro Physics
#NuclearPhysics #ParticlePhysics #AstroPhysics
- published: 12 Jan 2021
- views: 85940
18:43
Particle Physics Explained Visually in 20 min | Feynman diagrams
- Order: Reorder
- Duration: 18:43
- Uploaded Date: 20 Dec 2020
- views: 379556
Get MagellanTV here: https://try.magellantv.com/arvinash and get an exclusive offer for our viewers: an extended, month-long trial, FREE. MagellanTV has the la...
Get MagellanTV here: https://try.magellantv.com/arvinash and get an exclusive offer for our viewers: an extended, month-long trial, FREE. MagellanTV has the largest and best collection of Science content anywhere, including Space, Physics, Technology, Nature, Mind and Body, and a growing collection of 4K. This new streaming service has 3000 great documentaries. Check out our personal recommendation and MagellanTV’s exclusive playlists: https://www.magellantv.com/genres/science-and-tech
If you didn't understand this video, these may help:
https://youtu.be/xZqID1zSm0k -- Mechanism of the fundamental forces
https://youtu.be/jlEovwE1oHI -- What are quantum fields?
0:00 - Intro & Fields
2:22 - Special offer
3:09 - Particles, charges, forces
6:32 - Recap
7:13 - Electromagnetism
10:04 - Weak force
12:19 - Strong force
16:53 - Higgs
If we generalize the concept of bosons interacting with particles, we can get all fundamental particle physics. Complex math, but physicist Richard Feynman came up with a simple way to view these interactions - Feynman diagrams.
The 12 fermions are depicted as straight lines with arrows in the diagrams. The arrows represent the “flow” of fermions. No two arrows point towards each other. If time is in the x direction, then fermion arrows going forwards are matter particles, and those going backwards, antimatter particles.
All 6 quarks have color charges. All particles with color charges interact with the strong nuclear force. Quarks also have an electric charge, so they also feel the electromagnetic force.
Leptons can be divided into the electron and its heavier cousins, the muon and tau particles. These all have electric charges but no color charges. Neutrinos do not have a color charge or an electric charge, so they are not affected by the strong and electromagnetic forces.
All fermions carry something called weak isospin. This can be thought of as the “charge” of the weak force. It can be +1/2 or -1/2. All fermions interact with the weak force. But weak isospin can also be -1, 0, and +1 – the W- boson has a weak isospin of -1, W+ has +1, Higgs has -1/2, and Z boson and photons have a weak isospin of 0. Note that this zero is not the same has having no isospin. Everything in the standard model has a weak isospin except gluons.
The weak force has the power to turn one particle into another particle. It is the only force that can do that.
To recap, quarks interact with all forces, electron like particles interact with electromagnetism and the weak force, but do not interact with the strong force. Neutrinos only interact with the weak force and nothing else. Only quarks and gluons carry the strong force. Higgs bosons do not interact with photons or gluons. They confer mass to fundamental particles, so all fundamental particles with mass interact with Higgs.
The simplest force is electromagnetic which interacts with quarks and leptons. Repulsion is depicted in Møller scattering. Attraction is shown in Bhabha scattering. When electrons and positrons are near each other, they can annihilate or attract each other.'
Weak force is felt by all of the standard model particles, except gluons. W-boson can do something very special. They can change the identity or flavor of the particle - a neutron to a proton. We probably would not exist without it.
Z-boson has no electric charge and can mediate interactions with electrically neutral particles like the neutrino and the Higgs.
The strong force is the most complicated mathematically, but since it only relates to quarks and gluons. A pair of quarks can change color. This happens all the time inside protons and neutrons, and is the glue that binds the quarks together.
Because gluons themselves contain color charges, they also interact with each other via complicated diagrams. This is what flux tubes are made of. These tubes are formed when you try to pull quarks apart.
Mesons are formed when a quark tries to leave a nucleon. These mesons are a combination of a quark, anti-quark pairs which mediate the strong force between protons and neutrons.
Pi mesons exchanges colors and quarks between protons and neutron. This is what keeps them glued together. Color charges must be conserved. Either red, blue, and green must combine, or color anti-color must combine to form a neutral color charge.
The most prominent process used at the Large hadron collider to make a Higgs boson is called the gluon fusion process. During high energy proton-proton collisions, two high energy gluons can be produced. Strong force interaction can turn these into top quarks which fuse together via a loop of top quark, anti-top quark creation and annihilation. The energy of this can create a Higgs boson.
#particlephysics
#fundamentalforces
When particles decay, they tend to decay into the next highest mass particle.
Become a patron: https://www.patreon.com/bePatron?u=17543985
Further reading: http://t.ly/fKKD
https://wn.com/Particle_Physics_Explained_Visually_In_20_Min_|_Feynman_Diagrams
Get MagellanTV here: https://try.magellantv.com/arvinash and get an exclusive offer for our viewers: an extended, month-long trial, FREE. MagellanTV has the largest and best collection of Science content anywhere, including Space, Physics, Technology, Nature, Mind and Body, and a growing collection of 4K. This new streaming service has 3000 great documentaries. Check out our personal recommendation and MagellanTV’s exclusive playlists: https://www.magellantv.com/genres/science-and-tech
If you didn't understand this video, these may help:
https://youtu.be/xZqID1zSm0k -- Mechanism of the fundamental forces
https://youtu.be/jlEovwE1oHI -- What are quantum fields?
0:00 - Intro & Fields
2:22 - Special offer
3:09 - Particles, charges, forces
6:32 - Recap
7:13 - Electromagnetism
10:04 - Weak force
12:19 - Strong force
16:53 - Higgs
If we generalize the concept of bosons interacting with particles, we can get all fundamental particle physics. Complex math, but physicist Richard Feynman came up with a simple way to view these interactions - Feynman diagrams.
The 12 fermions are depicted as straight lines with arrows in the diagrams. The arrows represent the “flow” of fermions. No two arrows point towards each other. If time is in the x direction, then fermion arrows going forwards are matter particles, and those going backwards, antimatter particles.
All 6 quarks have color charges. All particles with color charges interact with the strong nuclear force. Quarks also have an electric charge, so they also feel the electromagnetic force.
Leptons can be divided into the electron and its heavier cousins, the muon and tau particles. These all have electric charges but no color charges. Neutrinos do not have a color charge or an electric charge, so they are not affected by the strong and electromagnetic forces.
All fermions carry something called weak isospin. This can be thought of as the “charge” of the weak force. It can be +1/2 or -1/2. All fermions interact with the weak force. But weak isospin can also be -1, 0, and +1 – the W- boson has a weak isospin of -1, W+ has +1, Higgs has -1/2, and Z boson and photons have a weak isospin of 0. Note that this zero is not the same has having no isospin. Everything in the standard model has a weak isospin except gluons.
The weak force has the power to turn one particle into another particle. It is the only force that can do that.
To recap, quarks interact with all forces, electron like particles interact with electromagnetism and the weak force, but do not interact with the strong force. Neutrinos only interact with the weak force and nothing else. Only quarks and gluons carry the strong force. Higgs bosons do not interact with photons or gluons. They confer mass to fundamental particles, so all fundamental particles with mass interact with Higgs.
The simplest force is electromagnetic which interacts with quarks and leptons. Repulsion is depicted in Møller scattering. Attraction is shown in Bhabha scattering. When electrons and positrons are near each other, they can annihilate or attract each other.'
Weak force is felt by all of the standard model particles, except gluons. W-boson can do something very special. They can change the identity or flavor of the particle - a neutron to a proton. We probably would not exist without it.
Z-boson has no electric charge and can mediate interactions with electrically neutral particles like the neutrino and the Higgs.
The strong force is the most complicated mathematically, but since it only relates to quarks and gluons. A pair of quarks can change color. This happens all the time inside protons and neutrons, and is the glue that binds the quarks together.
Because gluons themselves contain color charges, they also interact with each other via complicated diagrams. This is what flux tubes are made of. These tubes are formed when you try to pull quarks apart.
Mesons are formed when a quark tries to leave a nucleon. These mesons are a combination of a quark, anti-quark pairs which mediate the strong force between protons and neutrons.
Pi mesons exchanges colors and quarks between protons and neutron. This is what keeps them glued together. Color charges must be conserved. Either red, blue, and green must combine, or color anti-color must combine to form a neutral color charge.
The most prominent process used at the Large hadron collider to make a Higgs boson is called the gluon fusion process. During high energy proton-proton collisions, two high energy gluons can be produced. Strong force interaction can turn these into top quarks which fuse together via a loop of top quark, anti-top quark creation and annihilation. The energy of this can create a Higgs boson.
#particlephysics
#fundamentalforces
When particles decay, they tend to decay into the next highest mass particle.
Become a patron: https://www.patreon.com/bePatron?u=17543985
Further reading: http://t.ly/fKKD
- published: 20 Dec 2020
- views: 379556
16:25
The Standard Model of Particle Physics: A Triumph of Science
- Order: Reorder
- Duration: 16:25
- Uploaded Date: 16 Jul 2021
- views: 3252336
The Standard Model of particle physics is the most successful scientific theory of all time. It describes how everything in the universe is made of 12 different...
The Standard Model of particle physics is the most successful scientific theory of all time. It describes how everything in the universe is made of 12 different types of matter particles, interacting with three forces, all bound together by a rather special particle called the Higgs boson. It’s the pinnacle of 400 years of science and gives the correct answer to hundreds of thousands of experiments. In this explainer, Cambridge University physicist David Tong recreates the model, piece by piece, to provide some intuition for how the fundamental building blocks of our universe fit together. At the end of the video, he also points out what’s missing from the model and what work is left to do in order to complete the Theory of Everything.
**Correction: At 13'50", the photon should be included with the three fundamental forces. The animation here is incorrect, while the narration is correct.
00:00 The long search for a Theory of Everything
00:33 The Standard Model
01:43 Gravity: the mysterious force
02:29 Quantum Field Theory and wave-particle duality
03:05 Fermions and Bosons
04:00 Electrons and quarks, protons and neutrons
04:45 Neutrinos
05:22 Muons and Taus
05:59 Strange and Bottom Quarks, Charm and Top Quarks
06:13 Electron Neutrinos, Muon Neutrinos, and Tao Neutrinos
06:26 How do we detect the elusive particles?
06:49 Why do particles come in sets of four?
07:17 The Dirac Equation describes all of the particles
07:49 The three fundamental forces
08:13 Bosons
08:32 Electromagnetism and photons
09:17 The Strong Force, gluons and flux tubes
10:38 The Weak Force, Radioactive Beta Decay, W and Z bosons
12:04 The Higgs boson and the Higgs field
13:20 Beyond the Standard Model: a Grand Unified Theory
14:12 How does gravity fit in the picture?
14:41 Where is the missing dark matter and dark energy?
15:03 Unsolved mysteries of the Standard Model
- VISIT or Website: https://www.quantamagazine.org
- LIKE us on Facebook: https://www.facebook.com/QuantaNews
- FOLLOW us Twitter: https://twitter.com/QuantaMagazine
Quanta Magazine is an editorially independent publication supported by the Simons Foundation https://www.simonsfoundation.org/.
https://wn.com/The_Standard_Model_Of_Particle_Physics_A_Triumph_Of_Science
The Standard Model of particle physics is the most successful scientific theory of all time. It describes how everything in the universe is made of 12 different types of matter particles, interacting with three forces, all bound together by a rather special particle called the Higgs boson. It’s the pinnacle of 400 years of science and gives the correct answer to hundreds of thousands of experiments. In this explainer, Cambridge University physicist David Tong recreates the model, piece by piece, to provide some intuition for how the fundamental building blocks of our universe fit together. At the end of the video, he also points out what’s missing from the model and what work is left to do in order to complete the Theory of Everything.
**Correction: At 13'50", the photon should be included with the three fundamental forces. The animation here is incorrect, while the narration is correct.
00:00 The long search for a Theory of Everything
00:33 The Standard Model
01:43 Gravity: the mysterious force
02:29 Quantum Field Theory and wave-particle duality
03:05 Fermions and Bosons
04:00 Electrons and quarks, protons and neutrons
04:45 Neutrinos
05:22 Muons and Taus
05:59 Strange and Bottom Quarks, Charm and Top Quarks
06:13 Electron Neutrinos, Muon Neutrinos, and Tao Neutrinos
06:26 How do we detect the elusive particles?
06:49 Why do particles come in sets of four?
07:17 The Dirac Equation describes all of the particles
07:49 The three fundamental forces
08:13 Bosons
08:32 Electromagnetism and photons
09:17 The Strong Force, gluons and flux tubes
10:38 The Weak Force, Radioactive Beta Decay, W and Z bosons
12:04 The Higgs boson and the Higgs field
13:20 Beyond the Standard Model: a Grand Unified Theory
14:12 How does gravity fit in the picture?
14:41 Where is the missing dark matter and dark energy?
15:03 Unsolved mysteries of the Standard Model
- VISIT or Website: https://www.quantamagazine.org
- LIKE us on Facebook: https://www.facebook.com/QuantaNews
- FOLLOW us Twitter: https://twitter.com/QuantaMagazine
Quanta Magazine is an editorially independent publication supported by the Simons Foundation https://www.simonsfoundation.org/.
- published: 16 Jul 2021
- views: 3252336
1:39:55
LIVE! PSW 2506 The Science Driving Particle Physics and Big Accelerators
- Order: Reorder
- Duration: 1:39:55
- Uploaded Date: 07 Dec 2024
- views: 375
Join PSW Science® on December 6th at 8 PM as we welcome speaker JoAnne Hewett, Director of Brookhaven National Laboratory. This presentation will describe the d...
Join PSW Science® on December 6th at 8 PM as we welcome speaker JoAnne Hewett, Director of Brookhaven National Laboratory. This presentation will describe the decadal vision laid out in the recent national strategic plan for particle physics, how it dovetails with global endeavors, and how it places the nation on the threshold of a new era of insight and discovery. During the question and answer period, in-person attendees and live stream viewers may ask the speaker questions, and in-person attendees may also engage with the speaker during the post-lecture reception. Refreshments are served. For more information on this meeting, please visit: https://pswscience.org/meeting/2506/
The meeting will be held in the John Wesley Powell Auditorium, adjacent to the Cosmos Club. The Powell Auditorium is located at 2170 Florida Avenue, NW Washington, DC 20008. Use of the Cosmos Club is restricted to the Powell Auditorium, the entryway to the auditorium, and the restrooms immediately outside the auditorium. Please note there is no onsite parking available.
PSW Science, founded in 1871, is one of the oldest scientific societies in Washington D.C. Now, over 150 years later, we celebrate the Society's rich history and contributions to scientific discovery and cross-disciplinary collaboration. For information on how to become a member of PSW Science and membership benefits, please visit https://pswscience.org/join/
https://wn.com/Live_Psw_2506_The_Science_Driving_Particle_Physics_And_Big_Accelerators
Join PSW Science® on December 6th at 8 PM as we welcome speaker JoAnne Hewett, Director of Brookhaven National Laboratory. This presentation will describe the decadal vision laid out in the recent national strategic plan for particle physics, how it dovetails with global endeavors, and how it places the nation on the threshold of a new era of insight and discovery. During the question and answer period, in-person attendees and live stream viewers may ask the speaker questions, and in-person attendees may also engage with the speaker during the post-lecture reception. Refreshments are served. For more information on this meeting, please visit: https://pswscience.org/meeting/2506/
The meeting will be held in the John Wesley Powell Auditorium, adjacent to the Cosmos Club. The Powell Auditorium is located at 2170 Florida Avenue, NW Washington, DC 20008. Use of the Cosmos Club is restricted to the Powell Auditorium, the entryway to the auditorium, and the restrooms immediately outside the auditorium. Please note there is no onsite parking available.
PSW Science, founded in 1871, is one of the oldest scientific societies in Washington D.C. Now, over 150 years later, we celebrate the Society's rich history and contributions to scientific discovery and cross-disciplinary collaboration. For information on how to become a member of PSW Science and membership benefits, please visit https://pswscience.org/join/
- published: 07 Dec 2024
- views: 375
1:42
Classification of Particles - A Level Physics
- Order: Reorder
- Duration: 1:42
- Uploaded Date: 27 Mar 2020
- views: 36762
From the standard model, we can classify particles into two categories, hadrons and leptons. Examples of hadrons are protons and neutrons. Electrons are leptons...
From the standard model, we can classify particles into two categories, hadrons and leptons. Examples of hadrons are protons and neutrons. Electrons are leptons because they are fundamental particles.
Music credit:
Song: Dipcrusher - Islands (Vlog No Copyright Music)
Music provided by Vlog No Copyright Music.
Video Link: https://youtu.be/CpFneq3zIt4
Music credit
https://wn.com/Classification_Of_Particles_A_Level_Physics
From the standard model, we can classify particles into two categories, hadrons and leptons. Examples of hadrons are protons and neutrons. Electrons are leptons because they are fundamental particles.
Music credit:
Song: Dipcrusher - Islands (Vlog No Copyright Music)
Music provided by Vlog No Copyright Music.
Video Link: https://youtu.be/CpFneq3zIt4
Music credit
- published: 27 Mar 2020
- views: 36762
19:13
All Fundamental Forces and Particles Explained Simply | Elementary particles
The standard model of particle physics (In this video I explained all the four fundamental...
published: 10 Oct 2023
All Fundamental Forces and Particles Explained Simply | Elementary particles
All Fundamental Forces and Particles Explained Simply | Elementary particles
- Report rights infringement
- published: 10 Oct 2023
- views: 239373
The standard model of particle physics (In this video I explained all the four fundamental forces and elementary particles)
To know more about Elementary particles, I recommend to read this book (Facts and Mysteries in Elementary Particle) : https://amzn.to/46RFcSu
To support on patreon (video script with high-res art works) : https://patreon.com/Klonusk975
Contact : [email protected]
#standardmodel #force
5:21
What’s the smallest thing in the universe? - Jonathan Butterworth
Check out our Patreon page: https://www.patreon.com/teded
View full lesson: https://ed.te...
published: 15 Nov 2018
What’s the smallest thing in the universe? - Jonathan Butterworth
What’s the smallest thing in the universe? - Jonathan Butterworth
- Report rights infringement
- published: 15 Nov 2018
- views: 1272541
Check out our Patreon page: https://www.patreon.com/teded
View full lesson: https://ed.ted.com/lessons/the-standard-model-of-particle-physics-jonathan-butterworth
If you were to take a coffee cup, and break it in half, then in half again, and keep carrying on, where would you end up? Could you keep on going forever? Or would you eventually find a set of indivisible building blocks out of which everything is made? Jonathan Butterworth explains the Standard Model theory and how it helps us understand the world we live in.
Lesson by Jon Butterworth, directed by Nick Hilditch.
Thank you so much to our patrons for your support! Without you this video would not be possible! Jennifer Kurkoski, phkphk12321, Arlene Weston, Mehmet Yusuf Ertekin, Ten Cha, Les Howard, Kevin O'Leary, Francisco Leos, Robert Patrick, Jorge, Marcus Appelbaum, Alan Wilder, Amin Talaei, Mohamed Elsayed, Angel Pantoja, Eimann P. Evarola, Claire Ousey, Carlos H. Costa, Tariq Keblaoui, Bela Namyslik, Nick Johnson, Won Jang, Johnnie Graham, Junjie Huang, Harshita Jagdish Sahijwani, Amber Alexander, Yelena Baykova, Laurence McMillan, John C. Vesey, Karmi Nguyen, Chung Wah Gnapp, Andrew Sprott, Jane White, Ayan Doss, BRENDAN NEALE, Lawrence Teh Swee Kiang, Alex Pierce, Nick Cozby, Jeffrey Segrest, Anthony Arcis, Ugur Doga Sezgin, Kathryn Vacha, Allyson Martin, Srinivasa C Pasumarthi, 张晓雨, Ann Marie Reus, Nishant Suneja, Javier Lara Rosado, Jerry Yang and Shubham Arora.
31:48
The Map of Particle Physics | The Standard Model Explained
In this video I explain all the basics of particle physics and the standard model of parti...
published: 01 May 2021
The Map of Particle Physics | The Standard Model Explained
The Map of Particle Physics | The Standard Model Explained
- Report rights infringement
- published: 01 May 2021
- views: 1578467
In this video I explain all the basics of particle physics and the standard model of particle physics. Check out Brilliant here: https://brilliant.org/DOS/
Buy the poster here: https://store.dftba.com/collections/domain-of-science/products/map-of-fundamental-particles
Digital version here: https://www.flickr.com/photos/95869671@N08
The standard model of particle physics is our fundamental description of the stuff in the universe. It doesn’t answer why anything exists, but does describe what exists and how it behaves, and that’s what we’ll be discovering in this video. We will cover the fermions, which contain the quarks and the leptons, as well as the bosons or force carriers. As well as which of the fundamental forces each of these fundamental particles interact with, along with the Higgs field. We’ll also look at the conservation rules of particle physics, symmetries in physics and the various quantum numbers that rule which particle interactions are valid and which are not.
#particlephysics #standardmodel #DomainOfScience
--- Posters ----
DFTBA Store: https://store.dftba.com/collections/domain-of-science
RedBubble Store: https://www.redbubble.com/people/DominicWalliman
I have also made posters available for educational use which you can find here: https://www.flickr.com/photos/95869671@N08/
-- Some Awesome People ---
And many thanks to my $10 supporters on Patreon, you are awesome!
Bob Milano
Alex Polo
Eric Epstein
Kevin Delaney
Mark Pickenheim
noggieB
Raj Duphare
Reggie Fourmyle
Sandy Toye
Sebastian
Terrence Masson
Join the gang and help support me produce free and high quality science content:
https://www.patreon.com/domainofscience
--- Special Thanks ---
Special thanks to Sarah Johnson https://twitter.com/SJDJ and Henry Reich https://www.youtube.com/user/minutephysics for their fact checking help.
--- My Science Books ----
I also write science books for kids called Professor Astro Cat. You can see them all here:
http://profastrocat.com
--- Follow me around the internet ---
http://dominicwalliman.com
https://twitter.com/DominicWalliman
https://www.instagram.com/dominicwalliman
--- Credits ---
Art, animation, presented by Dominic Walliman
References
[1] good summary
https://physics.info/standard/
[2] CPT symmetry
en.wikipedia.org/wiki/CP_violation
[3] Arvin Ash video
https://youtu.be/gkHmXhhAF2Y
[4] Conservation rules video
https://www.youtube.com/watch?v=dkFr3BGO8Dg
[5] More conservation rules
https://www.youtube.com/watch?v=qbf7y7Uv6d4
[6] Particle conservation laws
https://bit.ly/3pIb05M
[7] Short explanation of spin
https://bit.ly/2R7UIGV
[8] Short video explaining spin
https://youtu.be/cd2Ua9dKEl8
[9] Pauli exclusion principle
https://bit.ly/3mr4bF5
[10] The failure of supersymmetry
https://bit.ly/3uumFHn
[11] A nice summary of CP-symmetry
https://bit.ly/3t5WmqS
--- Chapters ---
00:00 Intro
00:28 What is particle physics?
01:33 The Fundamental Particles
02:13 Spin
3:52 Conservation Laws
5:01 Fermions and Bosons
7:40 Quarks
11:12 Color Charge
14:13 Leptons
16:39 Neutrinos
19:08 Symmetries in Physics
21:56 Conservation Laws With Forces
23:07 Summary So Far
23:36 Bosons
25:48 Gravity
26:52 Mysteries
28:24 The Future
29:08 Sponsor Message
30:12 End Ramble
28:33
All Elementary Particles Explained
------------------------------------------------------------------------------------------...
published: 04 Dec 2024
All Elementary Particles Explained
All Elementary Particles Explained
- Report rights infringement
- published: 04 Dec 2024
- views: 26980
----------------------------------------------------------------------------------------------------
In case you'd like to support me:
patreon.com/sub2MAKiT
my discord:
https://discord.gg/TSEBQvsWBr
----------------------------------------------------------------------------------------------------
Other MAKiTs:
@MAKiTResearch
@mktcharity
@makitmovies
@makitshitpost
-----------------------------------------------------------------------------------------------------
Sources:
https://archive.org/details/deepdownthingsbr00schu/mode/1up
https://www.hep.phy.cam.ac.uk/~thomson/lectures/partIIIparticles/Handout7_2009.pdf
https://www.osti.gov/biblio/4008239
https://pdglive.lbl.gov/Particle.action?node=Q004&init=0
https://arxiv.org/pdf/2204.07269
https://home.cern/news/news/physics/first-observation-photons-taus-proton-proton-collisions-cms
https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_(OpenStax)/University_Physics_III_-_Optics_and_Modern_Physics_(OpenStax)/11%3A_Particle_Physics_and_Cosmology/11.03%3A_Particle_Conservation_Laws
https://www.reuters.com/article/idUSL07652872/
-----------------------------------------------------------------------------------------------------
00:00 Intro
00:58 Quarks
09:34 Gluons
12:23 Photons
13:22 Electrons
18:00 Leptons
20:49 Bosons
22:17 Neutrinos
24:27 Higgs
27:11 MAKiT having a tad of a breakdown
7:33
The Standard Model of Particle Physics
Once you start learning about modern physics, you start to hear about weird particles like...
published: 05 Jun 2017
The Standard Model of Particle Physics
The Standard Model of Particle Physics
- Report rights infringement
- published: 05 Jun 2017
- views: 122149
Once you start learning about modern physics, you start to hear about weird particles like quarks and muons and neutrinos. What are all these things? Why are there so many? How do we know they exist? What do they do? Let's check out the standard model of particle physics.
Watch the whole Modern Physics playlist: http://bit.ly/ProfDavePhysics2
Classical Physics Tutorials: http://bit.ly/ProfDavePhysics1
Mathematics Tutorials: http://bit.ly/ProfDaveMaths
General Chemistry Tutorials: http://bit.ly/ProfDaveGenChem
Organic Chemistry Tutorials: http://bit.ly/ProfDaveOrgChem
Biochemistry Tutorials: http://bit.ly/ProfDaveBiochem
Biology Tutorials: http://bit.ly/ProfDaveBio
EMAIL► [email protected]
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
12:16
Classification of Elementary Particles | Jeya P | Department of Physics
Nuclear Particle and Astro Physics
#NuclearPhysics #ParticlePhysics #AstroPhysics
published: 12 Jan 2021
Classification of Elementary Particles | Jeya P | Department of Physics
Classification of Elementary Particles | Jeya P | Department of Physics
- Report rights infringement
- published: 12 Jan 2021
- views: 85940
Nuclear Particle and Astro Physics
#NuclearPhysics #ParticlePhysics #AstroPhysics
18:43
Particle Physics Explained Visually in 20 min | Feynman diagrams
Get MagellanTV here: https://try.magellantv.com/arvinash and get an exclusive offer for ou...
published: 20 Dec 2020
Particle Physics Explained Visually in 20 min | Feynman diagrams
Particle Physics Explained Visually in 20 min | Feynman diagrams
- Report rights infringement
- published: 20 Dec 2020
- views: 379556
Get MagellanTV here: https://try.magellantv.com/arvinash and get an exclusive offer for our viewers: an extended, month-long trial, FREE. MagellanTV has the largest and best collection of Science content anywhere, including Space, Physics, Technology, Nature, Mind and Body, and a growing collection of 4K. This new streaming service has 3000 great documentaries. Check out our personal recommendation and MagellanTV’s exclusive playlists: https://www.magellantv.com/genres/science-and-tech
If you didn't understand this video, these may help:
https://youtu.be/xZqID1zSm0k -- Mechanism of the fundamental forces
https://youtu.be/jlEovwE1oHI -- What are quantum fields?
0:00 - Intro & Fields
2:22 - Special offer
3:09 - Particles, charges, forces
6:32 - Recap
7:13 - Electromagnetism
10:04 - Weak force
12:19 - Strong force
16:53 - Higgs
If we generalize the concept of bosons interacting with particles, we can get all fundamental particle physics. Complex math, but physicist Richard Feynman came up with a simple way to view these interactions - Feynman diagrams.
The 12 fermions are depicted as straight lines with arrows in the diagrams. The arrows represent the “flow” of fermions. No two arrows point towards each other. If time is in the x direction, then fermion arrows going forwards are matter particles, and those going backwards, antimatter particles.
All 6 quarks have color charges. All particles with color charges interact with the strong nuclear force. Quarks also have an electric charge, so they also feel the electromagnetic force.
Leptons can be divided into the electron and its heavier cousins, the muon and tau particles. These all have electric charges but no color charges. Neutrinos do not have a color charge or an electric charge, so they are not affected by the strong and electromagnetic forces.
All fermions carry something called weak isospin. This can be thought of as the “charge” of the weak force. It can be +1/2 or -1/2. All fermions interact with the weak force. But weak isospin can also be -1, 0, and +1 – the W- boson has a weak isospin of -1, W+ has +1, Higgs has -1/2, and Z boson and photons have a weak isospin of 0. Note that this zero is not the same has having no isospin. Everything in the standard model has a weak isospin except gluons.
The weak force has the power to turn one particle into another particle. It is the only force that can do that.
To recap, quarks interact with all forces, electron like particles interact with electromagnetism and the weak force, but do not interact with the strong force. Neutrinos only interact with the weak force and nothing else. Only quarks and gluons carry the strong force. Higgs bosons do not interact with photons or gluons. They confer mass to fundamental particles, so all fundamental particles with mass interact with Higgs.
The simplest force is electromagnetic which interacts with quarks and leptons. Repulsion is depicted in Møller scattering. Attraction is shown in Bhabha scattering. When electrons and positrons are near each other, they can annihilate or attract each other.'
Weak force is felt by all of the standard model particles, except gluons. W-boson can do something very special. They can change the identity or flavor of the particle - a neutron to a proton. We probably would not exist without it.
Z-boson has no electric charge and can mediate interactions with electrically neutral particles like the neutrino and the Higgs.
The strong force is the most complicated mathematically, but since it only relates to quarks and gluons. A pair of quarks can change color. This happens all the time inside protons and neutrons, and is the glue that binds the quarks together.
Because gluons themselves contain color charges, they also interact with each other via complicated diagrams. This is what flux tubes are made of. These tubes are formed when you try to pull quarks apart.
Mesons are formed when a quark tries to leave a nucleon. These mesons are a combination of a quark, anti-quark pairs which mediate the strong force between protons and neutrons.
Pi mesons exchanges colors and quarks between protons and neutron. This is what keeps them glued together. Color charges must be conserved. Either red, blue, and green must combine, or color anti-color must combine to form a neutral color charge.
The most prominent process used at the Large hadron collider to make a Higgs boson is called the gluon fusion process. During high energy proton-proton collisions, two high energy gluons can be produced. Strong force interaction can turn these into top quarks which fuse together via a loop of top quark, anti-top quark creation and annihilation. The energy of this can create a Higgs boson.
#particlephysics
#fundamentalforces
When particles decay, they tend to decay into the next highest mass particle.
Become a patron: https://www.patreon.com/bePatron?u=17543985
Further reading: http://t.ly/fKKD
16:25
The Standard Model of Particle Physics: A Triumph of Science
The Standard Model of particle physics is the most successful scientific theory of all tim...
published: 16 Jul 2021
The Standard Model of Particle Physics: A Triumph of Science
The Standard Model of Particle Physics: A Triumph of Science
- Report rights infringement
- published: 16 Jul 2021
- views: 3252336
The Standard Model of particle physics is the most successful scientific theory of all time. It describes how everything in the universe is made of 12 different types of matter particles, interacting with three forces, all bound together by a rather special particle called the Higgs boson. It’s the pinnacle of 400 years of science and gives the correct answer to hundreds of thousands of experiments. In this explainer, Cambridge University physicist David Tong recreates the model, piece by piece, to provide some intuition for how the fundamental building blocks of our universe fit together. At the end of the video, he also points out what’s missing from the model and what work is left to do in order to complete the Theory of Everything.
**Correction: At 13'50", the photon should be included with the three fundamental forces. The animation here is incorrect, while the narration is correct.
00:00 The long search for a Theory of Everything
00:33 The Standard Model
01:43 Gravity: the mysterious force
02:29 Quantum Field Theory and wave-particle duality
03:05 Fermions and Bosons
04:00 Electrons and quarks, protons and neutrons
04:45 Neutrinos
05:22 Muons and Taus
05:59 Strange and Bottom Quarks, Charm and Top Quarks
06:13 Electron Neutrinos, Muon Neutrinos, and Tao Neutrinos
06:26 How do we detect the elusive particles?
06:49 Why do particles come in sets of four?
07:17 The Dirac Equation describes all of the particles
07:49 The three fundamental forces
08:13 Bosons
08:32 Electromagnetism and photons
09:17 The Strong Force, gluons and flux tubes
10:38 The Weak Force, Radioactive Beta Decay, W and Z bosons
12:04 The Higgs boson and the Higgs field
13:20 Beyond the Standard Model: a Grand Unified Theory
14:12 How does gravity fit in the picture?
14:41 Where is the missing dark matter and dark energy?
15:03 Unsolved mysteries of the Standard Model
- VISIT or Website: https://www.quantamagazine.org
- LIKE us on Facebook: https://www.facebook.com/QuantaNews
- FOLLOW us Twitter: https://twitter.com/QuantaMagazine
Quanta Magazine is an editorially independent publication supported by the Simons Foundation https://www.simonsfoundation.org/.
1:39:55
LIVE! PSW 2506 The Science Driving Particle Physics and Big Accelerators
Join PSW Science® on December 6th at 8 PM as we welcome speaker JoAnne Hewett, Director of...
published: 07 Dec 2024
LIVE! PSW 2506 The Science Driving Particle Physics and Big Accelerators
LIVE! PSW 2506 The Science Driving Particle Physics and Big Accelerators
- Report rights infringement
- published: 07 Dec 2024
- views: 375
Join PSW Science® on December 6th at 8 PM as we welcome speaker JoAnne Hewett, Director of Brookhaven National Laboratory. This presentation will describe the decadal vision laid out in the recent national strategic plan for particle physics, how it dovetails with global endeavors, and how it places the nation on the threshold of a new era of insight and discovery. During the question and answer period, in-person attendees and live stream viewers may ask the speaker questions, and in-person attendees may also engage with the speaker during the post-lecture reception. Refreshments are served. For more information on this meeting, please visit: https://pswscience.org/meeting/2506/
The meeting will be held in the John Wesley Powell Auditorium, adjacent to the Cosmos Club. The Powell Auditorium is located at 2170 Florida Avenue, NW Washington, DC 20008. Use of the Cosmos Club is restricted to the Powell Auditorium, the entryway to the auditorium, and the restrooms immediately outside the auditorium. Please note there is no onsite parking available.
PSW Science, founded in 1871, is one of the oldest scientific societies in Washington D.C. Now, over 150 years later, we celebrate the Society's rich history and contributions to scientific discovery and cross-disciplinary collaboration. For information on how to become a member of PSW Science and membership benefits, please visit https://pswscience.org/join/
1:42
Classification of Particles - A Level Physics
From the standard model, we can classify particles into two categories, hadrons and lepton...
published: 27 Mar 2020
Classification of Particles - A Level Physics
Classification of Particles - A Level Physics
- Report rights infringement
- published: 27 Mar 2020
- views: 36762
From the standard model, we can classify particles into two categories, hadrons and leptons. Examples of hadrons are protons and neutrons. Electrons are leptons because they are fundamental particles.
Music credit:
Song: Dipcrusher - Islands (Vlog No Copyright Music)
Music provided by Vlog No Copyright Music.
Video Link: https://youtu.be/CpFneq3zIt4
Music credit
Elementary particle
In particle physics, an elementary particle or fundamental particle is a particle whose substructure is unknown, thus it is unknown whether it is composed of other particles. Known elementary particles include the fundamental fermions (quarks, leptons, antiquarks, and antileptons), which generally are "matter particles" and "antimatter particles", as well as the fundamental bosons (gauge bosons and the Higgs boson), which generally are "force particles" that mediate interactions among fermions. A particle containing two or more elementary particles is a composite particle.
Everyday matter is composed of atoms, once presumed to be matter's elementary particles—atom meaning "indivisible" in Greek—although the atom's existence remained controversial until about 1910, as some leading physicists regarded molecules as mathematical illusions, and matter as ultimately composed of energy. Soon, subatomic constituents of the atom were identified. As the 1930s opened, the electron and the proton had been observed, along with the photon, the particle of electromagnetic radiation. At that time, the recent advent of quantum mechanics was radically altering the conception of particles, as a single particle could seemingly span a field as would a wave, a paradox still eluding satisfactory explanation.
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Elementary_particle
All Fundamental Forces and Particles Explained Sim...
What’s the smallest thing in the universe? - Jonat...
The Map of Particle Physics | The Standard Model E...
All Elementary Particles Explained...
The Standard Model of Particle Physics...
Classification of Elementary Particles | Jeya P |...
Particle Physics Explained Visually in 20 min | Fe...
The Standard Model of Particle Physics: A Triumph ...
LIVE! PSW 2506 The Science Driving Particle Physic...