:

DE sign:
(Deconstructing in-order to find new meanings)

A blogging space about my personal interests; was made during training in Stockholm #Young Leaders Visitors Program #Ylvp08 it developed into a social bookmarking blog.

I studied #Architecture; interested in #Design #Art #Education #Urban Design #Digital-media #social-media #Inhabited-Environments #Contemporary-Cultures #experimentation #networking #sustainability & more =)


Please Enjoy, feedback recommended.

p.s. sharing is usually out of interest not Blind praise.
This is neither sacred nor political.

Friday, December 13

Home



Text WARM to 70111 to donate £3 to UNICEF UK's Syria Winter Appeal.
Thousand Thank You
 
Donate by credit card at http://www.unicef.org.uk/syria (including viewers from outside the UK).

In this short film Ewan McGregor, Michael Sheen, Tom Hiddleston, Emma Bunton, Rita Ora and Tinie Tempah join UNICEF UK in support of our Syria Winter Appeal for the children of Syria.

Thank you - your help really makes a difference to children's lives in Syria.

Tuesday, December 10

Design resilient educational environments

A great opportunity for Architects & Designers and all interested civilians to learn about building/rebuilding schools
Kindly use the following link so that you'd join my endorsement group https://iversity.org/c/54?r=24b8e

Thank You in Advance

Wednesday, November 27

moon*4

A new interactive project that can change online collaboration, enjoy =)
Moon by Ai Weiwei & Olafur Eliasson from Studio Olafur Eliasson on Vimeo.
moonmoonmoonmoon.com

melting into the green..

"I tried to create something melting into the green"- Sou Fujimoto from Dezeen on Vimeo.
See more architecture and design movies on dezeen.com/movies

In this movie by film studio Stephenson/Bishop, Japanese architect Sou Fujimoto explains how he tried to combine nature and architecture when designing this year's Serpentine Gallery Pavilion, which is open for three more weeks in London's Kensington Gardens.

Built on the lawn outside the Serpentine Gallery, Sou Fujimoto's cloud-like pavilion comprises a grid of white poles that ascend upwards to form layered terraces with circles of transparent polycarbonate inserted to shelter from rain and reflect sunlight.

"From the beginning I didn't think 'I'd like to make a cloud'," says Fujimoto, explaining how he tried to design a structure that would fit in with its surroundings. "I was impressed by the beautiful surroundings of Kensington Garden, the beautiful green, so I tried to create something that was melting into the green."

"Of course the structure should be artificial so I tried to create something between architecture and nature; that kind of concept has been a big interest in my career so it is really natural to push forward with that concept for the future," he adds.

Monday, November 18

#Ylvp 14

YOUNG LEADERS VISITORS PROGRAMME 2014


Application for this year's Young Leaders program has started.

Kindly review the Link for more details on whether you are eligible to apply & how to...

http://eng.si.se/areas-of-operation/leadership-programmes-and-cultural-exchange/young-leaders-visitors-programme/application-procedure-for-ylvp/

" The Swedish Institute’s Young Leaders Visitors Programme (YLVP) is an annual intercultural leadership programme that aims to lay a foundation for dialogue, mutual understanding and knowledge sharing among young leaders from the Middle East, North Africa and Sweden."


more on the programme http://eng.si.se/areas-of-operation/leadership-programmes-and-cultural-exchange/young-leaders-visitors-programme/

Best Luck ;)

Sunday, November 3

re/building Creative Confidence

 (: Creative Confidence :)

David Kelley: How to build your creative confidence

 

I wanted to talk to you today about creative confidence. I'm going to start way back in the third grade at Oakdale School in Barberton, Ohio.
I remember one day my best friend Brian was working on a project. He was making a horse out of the clay that our teacher kept under the sink. And at one point, one of the girls who was sitting at his table, seeing what he was doing, leaned over and said to him, "That's terrible. That doesn't look anything like a horse." And Brian's shoulders sank. And he wadded up the clay horse and he threw it back in the bin. I never saw Brian do a project like that ever again.
And I wonder how often that happens. It seems like when I tell that story of Brian to my class, a lot of them want to come up after class and tell me about their similar experience, how a teacher shut them down or how a student was particularly cruel to them. And some opt out thinking of themselves as creative at that point. And I see that opting out that happens in childhood, and it moves in and becomes more ingrained, even by the time you get to adult life.
So we see a lot of this. When we have a workshop or when we have clients in to work with us side-by-side, eventually we get to the point in the process that's fuzzy or unconventional. And eventually these bigshot executives whip out their Blackberries and they say they have to make really important phone calls, and they head for the exits. And they're just so uncomfortable. When we track them down and ask them what's going on, they say something like, "I'm just not the creative type." But we know that's not true. If they stick with the process, if they stick with it, they end up doing amazing things and they surprise themselves just how innovative they and their teams really are.
So I've been looking at this fear of judgment that we have. That you don't do things, you're afraid you're going to be judged. If you don't say the right creative thing, you're going to be judged. And I had a major breakthrough when I met the psychologist Albert Bandura.
I don't know if you know Albert Bandura. But if you go to Wikipedia, it says that he's the fourth most important psychologist in history -- like Freud, Skinner, somebody and Bandura. Bandura's 86 and he still works at Stanford. And he's just a lovely guy.
And so I went to see him because he has just worked on phobias for a long time, which I'm very interested in. He had developed this way, this kind of methodology, that ended up curing people in a very short amount of time. In four hours he had a huge cure rate of people who had phobias. And we talked about snakes. I don't know why we talked about snakes. We talked about snakes and fear of snakes as a phobia.
And it was really enjoyable, really interesting. He told me that he'd invite the test subject in, and he'd say, "You know, there's a snake in the next room and we're going to go in there." To which, he reported, most of them replied, "Hell no, I'm not going in there, certainly if there's a snake in there."
But Bandura has a step-by-step process that was super successful. So he'd take people to this two-way mirror looking into the room where the snake was, and he'd get them comfortable with that. And then through a series of steps, he'd move them and they'd be standing in the doorway with the door open and they'd be looking in there. And he'd get them comfortable with that. And then many more steps later, baby steps, they'd be in the room, they'd have a leather glove like a welder's glove on, and they'd eventually touch the snake. And when they touched the snake everything was fine. They were cured. In fact, everything was better than fine. These people who had life-long fears of snakes were saying things like, "Look how beautiful that snake is." And they were holding it in their laps.
Bandura calls this process "guided mastery." I love that term: guided mastery. And something else happened, these people who went through the process and touched the snake ended up having less anxiety about other things in their lives. They tried harder, they persevered longer, and they were more resilient in the face of failure. They just gained a new confidence. And Bandura calls that confidence self-efficacy -- the sense that you can change the world and that you can attain what you set out to do.
Well meeting Bandura was really cathartic for me because I realized that this famous scientist had documented and scientifically validated something that we've seen happen for the last 30 years. That we could take people who had the fear that they weren't creative, and we could take them through a series of steps, kind of like a series of small successes, and they turn fear into familiarity, and they surprise themselves. That transformation is amazing.
We see it at the d.school all the time. People from all different kinds of disciplines, they think of themselves as only analytical. And they come in and they go through the process, our process, they build confidence and now they think of themselves differently. And they're totally emotionally excited about the fact that they walk around thinking of themselves as a creative person.
So I thought one of the things I'd do today is take you through and show you what this journey looks like. To me, that journey looks like Doug Dietz. Doug Dietz is a technical person. He designs medical imaging equipment, large medical imaging equipment. He's worked for GE, and he's had a fantastic career. But at one point he had a moment of crisis.
He was in the hospital looking at one of his MRI machines in use when he saw a young family. There was a little girl, and that little girl was crying and was terrified. And Doug was really disappointed to learn that nearly 80 percent of the pediatric patients in this hospital had to be sedated in order to deal with his MRI machine. And this was really disappointing to Doug, because before this time he was proud of what he did. He was saving lives with this machine. But it really hurt him to see the fear that this machine caused in kids.
About that time he was at the d.school at Stanford taking classes. He was learning about our process about design thinking, about empathy, about iterative prototyping. And he would take this new knowledge and do something quite extraordinary. He would redesign the entire experience of being scanned. And this is what he came up with.
He turned it into an adventure for the kids. He painted the walls and he painted the machine, and he got the operators retrained by people who know kids, like children's museum people. And now when the kid comes, it's an experience. And they talk to them about the noise and the movement of the ship. And when they come, they say, "Okay, you're going to go into the pirate ship, but be very still because we don't want the pirates to find you."
And the results were super dramatic. So from something like 80 percent of the kids needing to be sedated, to something like 10 percent of the kids needing to be sedated. And the hospital and GE were happy too. Because you didn't have to call the anesthesiologist all the time, they could put more kids through the machine in a day. So the quantitative results were great. But Doug's results that he cared about were much more qualitative. He was with one of the mothers waiting for her child to come out of the scan. And when the little girl came out of her scan, she ran up to her mother and said, "Mommy, can we come back tomorrow?" (Laughter)
And so I've heard Doug tell the story many times, of his personal transformation and the breakthrough design that happened from it, but I've never really seen him tell the story of the little girl without a tear in his eye.
Doug's story takes place in a hospital. I know a thing or two about hospitals. A few years ago I felt a lump on the side of my neck, and it was my turn in the MRI machine. It was cancer. It was the bad kind. I was told I had a 40 percent chance of survival.
So while you're sitting around with the other patients in your pajamas and everybody's pale and thin and you're waiting for your turn to get the gamma rays, you think of a lot of things. Mostly you think about, Am I going to survive? And I thought a lot about, What was my daughter's life going to be like without me? But you think about other things. I thought a lot about, What was I put on Earth to do? What was my calling? What should I do? And I was lucky because I had lots of options. We'd been working in health and wellness, and K through 12, and the Developing World. And so there were lots of projects that I could work on. But I decided and I committed to at this point to the thing I most wanted to do -- was to help as many people as possible regain the creative confidence they lost along their way. And if I was going to survive, that's what I wanted to do. I survived, just so you know.
(Laughter)
(Applause)
I really believe that when people gain this confidence -- and we see it all the time at the d.school and at IDEO -- they actually start working on the things that are really important in their lives. We see people quit what they're doing and go in new directions. We see them come up with more interesting, and just more, ideas so they can choose from better ideas. And they just make better decisions.
So I know at TED you're supposed to have a change-the-world kind of thing. Everybody has a change-the-world thing. If there is one for me, this is it. To help this happen. So I hope you'll join me on my quest -- you as thought leaders. It would be really great if you didn't let people divide the world into the creatives and the non-creatives, like it's some God-given thing, and to have people realize that they're naturally creative. And those natural people should let their ideas fly. That they should achieve what Bandura calls self-efficacy, that you can do what you set out to do, and that you can reach a place of creative confidence and touch the snake.
Thank you.
(Applause)

 
http://www.ted.com/talks/david_kelley_how_to_build_your_creative_confidence.html

Tuesday, October 22

Are You Happy now?


Published on Oct 20, 2013
The science of happiness is a growing and intriguing field. Research about what truly makes people happy is not only surprising, but applicable no matter how much money we make or where we live.

Join moderator Katie Couric and a panel of experts in psychology, business, neuroscience and design for a Roundtable discussion about the happiness and sense of wellbeing that elude so many, but are sought by all.


Published on Oct 20, 2013
The science of happiness is a growing and intriguing field. Research about what truly makes people happy is not only surprising, but applicable no matter how much money we make or where we live.

Join moderator Katie Couric and a panel of experts in psychology, business, neuroscience and design for a Roundtable discussion about the happiness and sense of wellbeing that elude so many, but are sought by all.

Monday, October 21

iversty | Courses

MOOCs at iversty



Design 101 (Design Basics) :: Abadir - Accademia di Belle Arti, Catania
https://iversity.org/c/2?r=24b8e


Contemporary Architecture :: iversity
https://iversity.org/c/20?r=24b8e 

Monte Carlo methods in Finance :: Universidad Autónoma de Madrid
https://iversity.org/c/3?r=24b8e


The fascination of crystals and symmetry :: Universität Hamburg
https://iversity.org/c/4?r=24b8e


Mathe-MOOC: Mathematisch denken :: Pädagogische Hochschule Heidelberg
https://iversity.org/c/5?r=24b8e


The future of Storytelling :: Fachhochschule Potsdam
https://iversity.org/c/6?r=24b8e


The European Union in Global Governance :: KU Leuven
https://iversity.org/c/7?r=24b8e

Modelling and Simulation using MATLAB :: Hochschule RheinMain - University of Applied Sciences

https://iversity.org/c/13?r=24b8e


Sectio Chirurgica - 'Anatomie interakiv' :: Universität Tübingen
https://iversity.org/c/8?r=24b8e


Changemaker MOOC - social Entrepreneurship :: Universität Kiel
https://iversity.org/c/9?r=24b8e


DNA from structure to Therapy :: Jacobs University Bremen
https://iversity.org/c/10?r=24b8e


Internationales Agrarmanagement :: Hochschule Weihenstephan-Triesdorf
https://iversity.org/c/11?r=24b8e


Web Engineering I :: Technische Hochschule Mittelhessen
https://iversity.org/c/18?r=24b8e


Web Engineering II :: Technische Hochschule Mittelhessen
https://iversity.org/c/19?r=24b8e


Grundlahen des Marketing :: Fachhochschule Lübeck
https://iversity.org/c/21?r=24b8e


Algorithmen und Datenstrukturen :: Universität Osnabrück
https://iversity.org/c/23?r=24b8e


Political Philosophy :: Universitá degli Studi di Firenze
https://iversity.org/c/24?r=24b8e


Dark Matter in Galaxies : the last Mystery :: SISSA di Trieste
https://iversity.org/c/25?r=24b8e


Einfuhrung in die Betriebswirtschaftslehre :: RWTH Aachen
https://iversity.org/c/26?r=24b8e


The DO School start-up Lab
https://iversity.org/c/27?r=24b8e

Public Privacy :: Universiteit Utrecht
https://iversity.org/c/28?r=24b8e


Vehicle Dynamic I :: Helmut-Schmidt-Universität - Universität der Bundeswehr Hamburg
https://iversity.org/c/30?r=24b8e


Vehicle Dynamic II :: Helmut-Schmidt-Universität - Universität der Bundeswehr Hamburg

https://iversity.org/c/31?r=24b8e


Vehicle Dynamic III :: Helmut-Schmidt-Universität - Universität der Bundeswehr Hamburg
https://iversity.org/c/32?r=24b8e


Einfuhrung in die Wahrscheinlichkeitsrechnung :: Johannes Gutenberg-Universität Mainz
https://iversity.org/c/33?r=24b8e

Saturday, October 19

Talks on the Higgs

This year the Nobel prize in Physics went to
François Englert & Peter W. Higgs For their Discovery and i quote Nobel Prize website
"for the theoretical discovery of a mechanism that contributes to our understanding of the origin of mass of subatomic particles, and which recently was confirmed through the discovery of the predicted fundamental particle, by the ATLAS and CMS experiments at CERN's Large Hadron Collider"
http://www.nobelprize.org/nobel_prizes/physics/laureates/2013/
http://www.nobelprize.org/nobel_prizes/physics/laureates/

Following some videos and Lectures on the concept of the Higgs Boson



http://ed.ted.com/lessons/the-basics-of-boson-dave-barney-and-steve-goldfarb

http://blog.ted.com/2013/05/03/physicists-from-cern-team-up-with-ted-ed-to-create-five-lessons-that-make-particle-physics-childs-play/











CrashCourse on HB
http://article.wn.com/view/2013/10/08/Crash_Course_in_the_Higgs/#/related_news
http://article.wn.com/view/2013/10/08/Crash_Course_in_the_Higgs/#/video

The Higgs Boson Explained at UCBerkeley


Published on Jul 16, 2012
On Friday July 13 at noon, faculty and other members of the Physics Department helped the campus community understand the significance of discovering the Higgs Boson, the particle that was predicted by Peter Higgs almost 50 years ago. Mark Richards, Executive Dean of the College of Letters & Sciences, will host this discussion for the Berkeley community.
Professors Beate Heinemann, an experimental physicist and a member of the ATLAS experiment at the LHC in CERN, Switzerland, and Lawrence Hall, a theoretical physicist and former Director of the Berkeley Center for Theoretical Physics, explained what the Higgs is, why it was predicted and how it was proven to exist. They were joined by panel members Professor Marjorie Shapiro, also a member of the Atlas experiment, Miller Fellow Josh Ruderman and PhD student and ATLAS member Louise Skinnari


Critical Mass: How the Higgs Boson Discovery Swept the World



Published on Feb 14, 2013
Last summer, scientists at the Large Hadron Collider in Geneva, Switzerland, announced the discovery of a new particle that could explain why elementary particles have mass. On February 7, 2013, a panel of experts from the University of Chicago, Argonne National Laboratory, and Fermilab discussed why this discovery marks the beginning of a new era in particle physics research.

 

The Hunt For Higgs


Published on Mar 3, 2012
Anticipation is building in the run-up to presentations of the best-yet evidence for - or against - the existence of the Higgs boson.
The famed particle is a missing link in current theories of physics, used to explain how things gains their mass.
Rumours have been swirling about the findings for weeks, ahead of the announcement on Tuesday afternoon.
It is likely to yield only tantalising hints, as the teams do not have enough data to claim a formal discovery.
However, most physicists concede that not finding the Higgs boson is as exciting a prospect as finding it in the place where existing theory predicts it should be.
"If we wouldn't find it it would be even - in a way - more exciting, but you know, both ways, it's a win-win situation," said Prof Stefan Soldner-Rembold, a particle physicist from the University of Manchester.
"[If] we find it, we know this theory's complete, but there's still more things to look for. If we don't find it, we know there must be something else which we haven't understood yet."
Field day
Finding the Higgs was a key goal for the $10bn (£6bn) Large Hadron Collider (LHC) - a 27km (17-mile) circumference accelerator ring of superconducting magnets, designed to re-create the conditions just after the Big Bang in an attempt to answer fundamental questions of science and the Universe itself.
The collider hosts two experiments - Atlas and CMS - that are searching for the particle independentlyThere is intense excitement among physicists working at Cern, the Geneva-based organisation which operates the collider, over hints that the hunters have cornered their quarry.
"It is a fantastic time at the moment, you can feel people are enthusiastic," Dr Christoph Rembser, a senior scientist on the Atlas experiment, told BBC News. "It is really very lively."
Continue reading the main story
"Start Quote If the Universe really is like that, I find it really quite breathtaking and humbling that we can understand it"
Dr Tara Shears University of Liverpool, UK
Prof Soldner-Rembold called the quality of the LHC's results "exceptional", adding: "Within one year we will probably know whether the Higgs particle exists, but it is likely not going to be a Christmas present."
He told me: "The Higgs particle would, of course, be a great discovery, but it would be an even greater discovery if it didn't exist where theory predicts it to be."
The Higgs boson is a "fundamental" particle; one of the basic building blocks of the Universe. It is also the last missing piece in the leading theory of particle physics - known as the Standard Model - which describes how particles and forces interact.
The Higgs explains why other particles have mass. As the Universe cooled after the Big Bang, an invisible force known as the Higgs field formed together with its associated boson particle.
It is this field (and not the boson) that imparts mass to the fundamental particles that make up atoms. Without it, these particles would zip through the cosmos at the speed of light.


http://www.bbc.co.uk/programmes/b019h7t0 

http://www.imdb.com/title/tt2191711/

The significance of the Higgs Boson discovery - Dr. John Ellis - BOLDtalks 2013 

Published on Mar 31, 2013

Dr. Ellis, Maxwell Professor of theoretical physics at King's College London and Guest Professor at the European Organisation for Nuclear Research (CERN), joins the BOLDtalks 2013 platform to explain the significance of the particle recently discovered at CERN (thought to be the long-sought Higgs Boson) and what its discovery means for the future of science and understanding the fabric of the Universe. Dr. Ellis is a world expert in the fields of particle physics, astrophysics, cosmology and quantum gravity.
In particle physics, there is a theory called the 'Standard Model' that explains that the universe is completely comprised of matter (fermions) and force (bosons).
However, more than 50 years ago Peter Higgs and five other theoretical physicists proposed that an invisible field lying across the Universe gives particles their mass, allowing them to clump together to form stars and planets.
This theory has been unproved, until July 2012, when scientists from the European Organization for Nuclear Research (CERN) have announced a breakthrough discovery of Higgs Boson, using the Large Hydron Collider (LHC) - the world's largest particle accelerator.
Dr. Ellis, Maxwell Professor of theoretical physics at King's College London and Guest Professor at the European Organisation for Nuclear Research (CERN), presents at BOLDtalks 2013 the significance of the particle recently discovered at CERN (thought to be the long-sought Higgs Boson) and what its discovery means for the future of science and understanding the fabric of the Universe. Dr. Ellis is a world expert in the fields of particle physics, astrophysics, cosmology and quantum gravity.

Higgs Boson Discovery announcement by Peter Higgs



Published on Jul 4, 2012

4th of July 2012, this is the day the Higgs Boson was discovered by the human race. 
After 45 years of searching, Peter Higgs can now announce to the world how he has seen the culmination of his life's work finally blossom into a tangible result, a result which has brought an all too human emotion to this triumph.
Francois Englert, Carl Hagen and Gerald Guralnik are also present in this announcement, who created the theory along with the late Robert Brout. For this reason it could also be referred to as the HEB-Boson.
The Higgs field and resulting Higgs boson are a vital part of the Electroweak Interaction and the Standard Model of Particle Physics. In the absence of the Higgs field, when a Local Gauge is applied to the Lagrangian of the Electroweak Interaction we are left with force-carrying bosons that are massive, the W and Z Bosons with masses of ~80GeV and ~90GeV respectively. This would be okay for the Photon as it has no mass, but why are the W and Z Bosons massive?
The Higgs mechanism was the most favoured explanation for solving this problem.
In brief, the Higgs field is introduced to 'break' the symmetry of the Electroweak theory, which allows particles to have mass.
This Higgs mechanism is important as it not only explains how the heavy bosons become massive but also provides an explanation as to how the fermions come to have mass.
The Mechanism of the interaction is simple to understand. Where the Electroweak Interaction couples to electric and weak (or flavour) charges and the Strong Interaction couples to colour charge, the Higgs interaction couples to mass. The process by which the Higgs gives fermions mass is via the Yukawa potential. This potential gives the coupling strength of the Higgs to all types of fermions, the stronger the coupling, the more mass the particle will have. Hence the Higgs Boson couples more strongly to more massive particles, hence the energies of the LHC were necessary to create the most massive particles for the Higgs to couple with.
Why we needed this boson is a bit more complicated, which corresponds to Peter Higgs, Yoichiro Nambu and Jeffrey Goldstone's theoretical research.
In the Electroweak interaction you can examine the Lagrangian in a similar way to those for Quantum Electrodynamics (QED) and also Quantum Chromodynamics (QCD). Starting with the Dirac Lagrangian, when a Local Gauge is applied the resulting Lagrangrian is not invariant under the transformation. The local gauge transformation applied to the Langrangian is dependent on the symmetry, for example for the weak force we use SU(2) symmetry as we want physics invariant under swapping up-like and down-like fermions.
When a Local Gauge Symmetry is applied to the Electroweak Lagrangian it does not remain invariant under the gauge transformation. This can be rectified by the introduction of appropriate fields, which have associated mass-less bosons W1, W2, W3 and B. The SU(2)xU(1) symmetry of the electroweak theory is non-abelian which means that the bosons interact with each other as well as with fermions.
The Electroweak theory needs to end up with three massive bosons (2 charged and 1 neutral) and also a mass-less boson. The Goldstone Theorem provides a mechanism by which the 4 mass-less bosons from the original symmetry can become the four Electroweak bosons described above. The Goldstone theorem states "that for any continuous symmetry broken, there exists a mass-less particle, the Goldstone boson." The result is that for each broken generator, there is a resulting mass-less scalar boson.
The Higgs mechanism is the process applied to Electroweak theory. A complex doublet Higgs field can be included in the theory and this Higgs field breaks the symmetry of the problem while retaining local gauge invariance. This Higgs field (two complex scalar fields which transform under the SU(2) symmetry) will, via the Goldstone Theorem, result in a scalar Higgs boson and 3 Goldstone bosons which will provide mass. The three Goldstone bosons interact with the original fields to provide mass for the W+, W- and Z bosons while leaving the fourth boson mass-less. This can be seen mathematically by looking at the changed form of the Electroweak Lagrangian due to the introduction of the Higgs fields.
There is a reason to believe that the Higgs Boson discovered is not the garden-variety Higgs that physicists were expecting. It's relatively low mass may place it in the Supersymmetric regime, and may be humanity's first probe into Supersymmetry. If the Boson was discovered to be a singlet it would also be the first fundamental singlet ever discovered, sparking new interest in finding the last piece of the singlet, vector, tensor boson puzzle: The Graviton, the force carrier for the gravitational force and the key ingredient in the Theory of Everything, "The Promised Land" of Physics that will explain how General Relativity works with Quantum Theory in a Grand Unified Force.


Higgs Boson Channel on YouTube https://www.youtube.com/channel/HCHTf0TBvHqkQ HB