Looking for a Course in Loop Quantum Gravity

In summary, the most recent book that could be a LQG textbook at some appropriate level is Thiemann's which came out this fall. It is discussed in this thread https://www.physicsforums.com/showthread.php?t=196209 and is not a book for college sophomores. AngryPhysicist, geoffc, Perturbation, and staf9 all own or have looked at the book and have something to say about it. Schutz' "A FIrst Course in GR" is a good book that covers material up to chapter 8. Chapter 9 killed me, but that tells you something. The town library has one of its three copies still checked in. I
  • #1
Jimmy Snyder
1,127
20
I am reading Barton Zwiebach's 'A First Course in String Theory'. I expect I will finish up in about a month. Not that I understand it that well. I will put it aside and perhaps read it again in a couple of years. I took a peek at the book 'String Theory in a Nutshell' by Elias Kiritsis and realized how little I absorbed on my first reading, even chapter 1 of that book is beyond me. Professor Zwiebach's book was written for Sophomores at MIT and that's why I was able to read it at all. I wonder if there is a book on Loop Quantum Gravity that is aimed toward beginners like me.
 
Physics news on Phys.org
  • #2
Nope. There's certainly nothing comparable to the low level at which Zwiebach's book treats string theory.
 
  • #3
I wonder if there is a book on Loop Quantum Gravity that is aimed toward beginners like me.
I would guess shoehorn's right there isn't, at least up to a point.
I don't know how far you want to stretch "comparable".

The most recent book that could be a LQG textbook at some appropriate level is Thiemann's
which came ouit this fall and is discussed in this thread
https://www.physicsforums.com/showthread.php?t=196209
It's not a book for college sophomores though.

Three PF member posting in that thread own the book, and one of them has written a review of it and posted it on his website. A fourth PF person says he has looked it over but not bought it.

The PF posters who own the book or have looked at it and have something to say about in in that thread are
AngryPhysicist
geoffc
Perturbation
staf9

the book tries to be mathematically selfcontained---that is it has a separate section of 200 pages which covers all the various math tools that it uses in developing LQG
====================

there is an online video series with about 20 lectures by Lee Smolin (and 3 guest lecturers) called Introduction to Loop Quantum Gravity

Google PIRSA (Perimeter Institute Recorded Seminar Archive). Some undergraduates at University of Waterloo were taking the course and the lectures were recorded. It is interesting but not consistently at undergraduate level. There were graduate students and postdocs sitting in.
====================

A popular account of LQG can be found in Smolin's book Three Roads to Quantum Gravity. I was surprised by how much understanding it delivers, but it is not mathematical at all.
====================

Obviously there is nothing I can think of that precisely matches Zwiebach!
 
Last edited:
  • #4
jimmysnyder said:
I am reading Barton Zwiebach's 'A First Course in String Theory'. I expect I will finish up in about a month. Not that I understand it that well. I will put it aside and perhaps read it again in a couple of years.

jimmy, if you can manage to find it, Srivastava's Supersymmetry, Superfields and Supergravity is a nice graduate text that'll get you up to speed on some of the string theory prerequisites such as: N-extended Super Yang-Mills theory, Grassmann variables and supermultiplets.
 
  • #5
marcus said:
The most recent book that could be a LQG textbook at some appropriate level is Thiemann's
which came ouit this fall and is discussed in this thread
https://www.physicsforums.com/showthread.php?t=196209
It's not a book for college sophomores though.

And how! I bought it this morning at the CUP bookstore. First impressions: it's heavy, very heavy, and ludicrously expensive even for a CUP first printing. Apart from that, it touches most of the bases that Thiemann covered in his ArXiv review of the same topic, and then some.

It's certainly not something that could profitably be read by an undergraduate. (And I brook no argument on this point. Undergrads may have been exposed to, say, GR but they won't have been exposed to it at anywhere near the level required to have a solid understanding of, for example, the ADM decomposition.)
 
  • #6
shoehorn said:
It's certainly not something that could profitably be read by an undergraduate. (And I brook no argument on this point. Undergrads may have been exposed to, say, GR but they won't have been exposed to it at anywhere near the level required to have a solid understanding of, for example, the ADM decomposition.)
I read Schutz' "A FIrst Course in GR" and I feel confident on the material through chapter 8. Chapter 9 killed me. What does that tell you? I will take a look at Thiemann but I can't decide if it is right for me until I do. I see the town library has one of it's three copies still checked in. I think I better start with Smolin as I started with Brian Greene for ST. The library's copies are all checked in. After that Srivastava sounds like something I would enjoy even if just for the math. The library has this one, but it is in the depository and requires 24 hours notice before being checked out. Thanks everyone for your input so far.
 
Last edited:
  • #7
Jimmy you don't sound ready for Thiemann. Take a look at John Baez's book Gauge Fields, knots, and Gravity it was written as prerequisite for loop quantum gravity. I think this book is you r best bet, and it is such a great book for people with a decent knowledge of math who are not yet professionals.
 
  • #8
jimmysnyder said:
I read Schutz' "A FIrst Course in GR" and I feel confident on the material through chapter 8. Chapter 9 killed me. What does that tell you? I will take a look at Thiemann but I can't decide if it is right for me until I do. I see the town library has one of it's three copies still checked in. I think I better start with Smolin as I started with Brian Greene for ST. The library's copies are all checked in. After that Srivastava sounds like something I would enjoy even if just for the math. The library has this one, but it is in the depository and requires 24 hours notice before being checked out. Thanks everyone for your input so far.

My impression is that one would need to be familiar with, at a bare minimum, the following topics in order to really get something out of Thiemann's book:

0) Lie groups, Lie algebras, and canonical quantization at a formal level.
1) Symplectic and Poisson manifolds.
2) Van Howe and Groenewald's arguments for the incompleteness of geometric quantization.
3) The ADM formulation of GR.
4) Ashtekar's variables (definitely with his approach to complexified general relativity, possibly with the real approach also).

Some may disagree with this, but that's what I'd deem necessary. If you're unsure whether you're able to understand the book, have a look at Thiemann's gr-qc/0110034. There's a not insignificant overlap between that paper and the contents of the book.

By the way, someone else suggested John Baez's book earlier in this thread. I'd forgotten about it but it's actually a very good, very easy read; I like his style of writing a lot. If I were you I'd get a hold of that, read it while at the same time learning as much differential geometry as you can, and by the time you're done with it you'll not only be much better prepared for Thiemann, but Thiemann's book should also be out in paperback by that stage.
 
Last edited:
  • #9
Christine Dantas compiled a good list of resources on her old blog, http://christinedantas.blogspot.com/ - you have to scroll down to the heading "A basic curriculum for Quantum Gravity".

In particular I recommend:
- Carlo Rovelli's book "Quantum Gravity". This is probably more accessible than Thiemann's.
- Lee Smolin's online lectures. These were targetted at upper year undergraduate physics students. The links are available from Christine's blog.
- John Baez's course notes from his Quantum Gravity seminar. http://math.ucr.edu/home/baez/QG.html. This is more abstract and mathematical, but should be accessible to undergraduate math students.
 
  • #10
william donnelly said:
Christine Dantas compiled a good list of resources on her old blog, http://christinedantas.blogspot.com/ - you have to scroll down to the heading "A basic curriculum for Quantum Gravity".

In particular I recommend:
- Carlo Rovelli's book "Quantum Gravity". This is probably more accessible than Thiemann's.

It's definitely more accessible than Thiemann's book and contains several interesting discussions from a conceptual standpoint, but I remain doubtful that it's accessible enough for an undergraduate. For instance, in chapter two Rovelli introduces various actions for general relativity but doesn't go into any detail regarding how the field equations can be derived from these actions. Since these actions are all vielbein-based, I'd expect a reader to have a knowledge of differential forms and their use in variational principles before being able to appreciate these points. Again, I'm not convinced that this is something a typical undergraduate would have come across.

Nevertheless, it is a nice book.
 
  • #11
jimmysnyder said:
I wonder if there is a book on Loop Quantum Gravity that is aimed toward beginners like me.
You can also check the references, bibliography & external links in Wikipedia's loop quantum gravity page. All the cross references have been checked & the whole page has been examined from a layman's point of view, but there is a need for LQG experts to review this page & bring it up to date with developments in the LQG field.
 
Last edited:
  • #12
Jim Kata said:
Jimmy you don't sound ready for Thiemann. Take a look at John Baez's book Gauge Fields, knots, and Gravity it was written as prerequisite for loop quantum gravity. I think this book is you r best bet, and it is such a great book for people with a decent knowledge of math who are not yet professionals.

shoehorn said:
My impression is that one would need to be familiar with, at a bare minimum, the following topics in order to really get something out of Thiemann's book:

0) Lie groups, Lie algebras, and canonical quantization at a formal level.
1) Symplectic and Poisson manifolds.
2) Van Howe and Groenewald's arguments for the incompleteness of geometric quantization.
3) The ADM formulation of GR.
4) Ashtekar's variables (definitely with his approach to complexified general relativity, possibly with the real approach also).

Some may disagree with this, but that's what I'd deem necessary. If you're unsure whether you're able to understand the book, have a look at Thiemann's gr-qc/0110034. There's a not insignificant overlap between that paper and the contents of the book.

By the way, someone else suggested John Baez's book earlier in this thread. I'd forgotten about it but it's actually a very good, very easy read; I like his style of writing a lot. If I were you I'd get a hold of that, read it while at the same time learning as much differential geometry as you can, and by the time you're done with it you'll not only be much better prepared for Thiemann, but Thiemann's book should also be out in paperback by that stage.
Sounds like consensus. I can't even spell ADM, so I took out a copy of Professor Baez's "Gauge Fields, Knots, and Gravity". Here's what it says: "The main prerequisites are some familiarity with electromagnetism, special relativity, linear algebra, and vector calculus, together with some of the indefinable commodity known as mathematical sophistication". That defines me. I also took out a copy of Smolin's 'Three Roads'. Thank everyone for all your help. I expect I will be asking questions on the homework help forum pretty soon.
 
  • #13
I think there is no way to seriously start learning quantum gravity without a proper background: first, you need to have followed an undergraduate program in physics or mathematics.

Then the next step would be to study the very nice book by Baez, already mentioned here. Next (or along with Baez's book) go to Frankel's book (https://www.amazon.com/dp/0521539277/?tag=pfamazon01-20.

Meanwhile when you start to feel that you are ready, go for some tutorials, they are available at the arxiv (you can find some links from my old blog, as already mentioned here as well). If you find some difficulty, go back to the books above and get back to the papers, etc. Learning all that material is a nonlinear process.

The PI lectures by Lee Smolin are advanced and have some prerequisites (as mentioned in the abstract of the course): you'll need them apart from those mentioned above. You can http://www.perimeterinstitute.ca/in...&task=view&id=113&Itemid=167&p=presentations" (pictures of the blackboard in pdf).

(BTW, I'm in a long and lonely journey LaTeXing those Smolin's lectures. I don't have a projection of when I'll finish them (it's a very slow process for several reasons and I might simply give up on them if my energy runs out for something else). So if there is someone else doing this, please let me know! (I asked Smolin but he does not know of anyone else LaTeXing his lectures).)

Finally, follow the arxiv new papers everyday. PF is a nice place to keep up to date about the headings in current research. There is a lot going on and it is easy to get lost. That is a reason why it is more important to know the fundamentals than the details of things that change so rapidly and can be simply dead-ends. When you have solid understanding and maturity you can follow whatever path or idea that interests you, that is much more important than having an encyclopedic knowledge but no wisdom or truthful understanding of the underlying physics.


Thanks,
Christine
 
Last edited by a moderator:
  • #14
ccdantas said:
I think there is no way to seriously start learning quantum gravity without a proper background: first, you need to have followed an undergraduate program in physics or mathematics.

...

When you have solid understanding and maturity you can follow whatever path or idea that interests you, that is much more important than having an encyclopedic knowledge but no wisdom or truthful understanding of the underlying physics.
Thanks Christine. I have a master's in math, so that's not an issue. Solid understanding still eludes me though, my maturity and wisdom are up for dispute, I certainly don't have encyclopedic knowledge and to say I had a truthful understanding of the underlying physics would be a lie. Heck, I don't even understand the superficial physics.
 
  • #15
jimmysnyder said:
Thanks Christine. I have a master's in math, so that's not an issue. Solid understanding still eludes me though, my maturity and wisdom are up for dispute, I certainly don't have encyclopedic knowledge and to say I had a truthful understanding of the underlying physics would be a lie. Heck, I don't even understand the superficial physics.

So we are in pretty the same boat. I have a PhD in Astrophysics and I am struggling will all those issues as well!

Good luck.
Christine
 
  • #16
ccdantas said:
So we are in pretty the same boat. I have a PhD in Astrophysics and I am struggling will all those issues as well!

Good luck.
Christine
The Baez book might be too elementary for me. Here is Exercise 53, page 449:
Baez and Muniain said:
Construct a theory of physics reconciling gravity and quantum theory. (Hint: you may have to develop new mathematical tools.) Design and conduct experiments to test the theory
I have a marvelous solution for the exercise which this post is too small to contain.
 
  • #17
This book has finally released by the end of Oct, 2011.
 
  • #19
I just received my copy of Gambini and Pullin's book. IMHO it's extemely well-written and gives, for an undergraduate audience, a nice meaningful flavour of some of the maths that goes into the LQG programme, without crossing the boundary where an undergrad might struggle. Even if you don't have any "faith" in the LQG approach, the first 2/3 of the book is still gives an excellent "taster" of GR, constraints, QFT, Ashtekar variables. Great for a 3rd year first degree course.
 
  • #20
  • #21
A popular account of LQG can be found in Smolin's book Three Roads to Quantum Gravity. I was surprised by how much understanding it delivers, but it is not mathematical at all.

ditto...very good conceptual introduction and descriptions. no math.
 
  • #22
  • #23
sheaf said:
I just received my copy of Gambini and Pullin's book. IMHO it's extemely well-written and gives, for an undergraduate audience, a nice meaningful flavour of some of the maths that goes into the LQG programme, without crossing the boundary where an undergrad might struggle. Even if you don't have any "faith" in the LQG approach, the first 2/3 of the book is still gives an excellent "taster" of GR, constraints, QFT, Ashtekar variables. Great for a 3rd year first degree course.

I have been reading everything I can in the online sample and I agree with your assessment of its being well-written. It is careful, clear, and always seems to keep at the right level. I think this is partly because Pullin teaches at a US university and has been teaching a course in LQG for undergraduates. He knows what works.

Also it is just plain well-written--they make efficient effective use of good English. So the parts I've looked at have been a pleasure to read. We lucked out on this one!
 
Last edited:
  • #24
I got a draft version sent to me by Pullin, and even in the early stages, it was quite good. One complaint I had is that there were only three or four exercises per chapter. I think undergraduates would be able to get more out of it if they could get their hands dirty more often and calculate a lot of things. But the problems chosen were well written; I imagine they were the problems given in his lectures.

I'd like to see the finished version. The index in the draft was pathetic and referred to wrong pages. I think Baez's book on gauge fields, knots, and gravity is a great supplement and might be accessible to advanced undergraduates.
 

1. What is Loop Quantum Gravity (LQG)?

Loop Quantum Gravity is a theoretical framework that attempts to reconcile the principles of quantum mechanics and general relativity in order to provide a complete understanding of the fundamental nature of space and time. It proposes that space is quantized, meaning that it is made up of discrete units, and that gravity is a manifestation of the geometry of spacetime.

2. How does LQG differ from other theories of quantum gravity?

LQG differs from other theories, such as string theory, in its approach to understanding the fundamental nature of spacetime. While string theory proposes that particles are made up of tiny strings, LQG suggests that space itself is made up of discrete quantum units. LQG also does not require the existence of extra dimensions, which is a key feature of string theory.

3. What are the main challenges in developing LQG?

One of the main challenges in developing LQG is the issue of renormalization, which is the process of removing infinities from calculations in quantum field theory. LQG also faces challenges in incorporating matter and particles, as well as in making predictions that can be tested experimentally.

4. How is LQG related to the search for a theory of everything?

LQG is one of the leading contenders for a theory of everything, which is a theoretical framework that aims to unify all fundamental forces and particles in the universe. While LQG is not yet a complete theory of everything, it provides a promising approach to understanding the fundamental nature of spacetime and the universe.

5. What are the potential implications of LQG?

If LQG is successfully developed and confirmed through experiments, it could have significant implications for our understanding of the universe. It could potentially resolve some of the inconsistencies between quantum mechanics and general relativity, and provide a more complete understanding of the fundamental building blocks of the universe. Additionally, LQG could potentially have practical applications, such as in the development of new technologies.

Similar threads

  • Beyond the Standard Models
Replies
13
Views
1K
  • Beyond the Standard Models
Replies
4
Views
2K
  • Beyond the Standard Models
Replies
7
Views
1K
  • Beyond the Standard Models
Replies
24
Views
3K
  • Beyond the Standard Models
Replies
4
Views
2K
  • Beyond the Standard Models
4
Replies
105
Views
10K
  • Beyond the Standard Models
Replies
6
Views
2K
Replies
2
Views
1K
  • Beyond the Standard Models
Replies
4
Views
3K
Back
Top