added pointer to today’s

- Andrew M. Evans, Alexandra Miller, Aaron Russell,
*A Conformal Field Theory Primer in $D \geq 3$*[arXiv:2309.10107]

added pointer to today’s

- Jürgen Fuchs, Christoph Schweigert, Simon Wood, Yang Yang,
*Algebraic structures in two-dimensional conformal field theory*, Encyclopedia of Mathematical Physics [arXiv:2305.02773]

will be adding this also to some related entries (such as *VOA*, *conformal block*, …)

added pointer to today’s

- Satoshi Nawata, Runkai Tao, Daisuke Yokoyama,
*Fudan lectures on 2d conformal field theory*[arXiv2208.05180]

added pointer to today’s

- Marc Gillioz,
*Conformal field theory for particle physicists*[arXiv:2207.09474]

added publication data for:

- Martin Schottenloher,
*A Mathematical Introduction to Conformal Field Theory*, Lecture Notes in Physics**759**, Springer 2008 (doi:10.1007/978-3-540-68628-6, web)

added pointer to:

- Paul Ginsparg,
*Applied Conformal Field Theory*, lectures at: *Fields, strings, critical phenomena, Les Houche Summer School 1988(arXiv:hep-th/9108028)

added pointer to today’s

- Marco Benini, Luca Giorgetti, Alexander Schenkel,
*A skeletal model for 2d conformal AQFTs*(arXiv:2111.01837)

added pointer to today’s

- Joaquin Liniado,
*Two Dimensional Conformal Field Theory and a Primer to Chiral Algebras*(arXiv:2110.15164)

added pointer to:

- Katrin Wendland,
*Snapshots of Conformal Field Theory*, in: Mathematical Aspects of Quantum Field Theories. Mathematical Physics Studies. Springer 2015 (arXiv:1404.3108, doi:10.1007/978-3-319-09949-1_4)

added pointer to the original:

- Alexander Belavin, Alexander Polyakov, Alexander Zamolodchikov,
*Infinite conformal symmetry in two–dimensional quantum field theory*, Nuclear Physics B Volume 241, Issue 2, 23 July 1984, Pages 333-380 (doi:10.1016/0550-3213(84)90052-X)

added pointer to

- James E. Tener,
*Representation theory in chiral conformal field theory: from fields to observables*(arXiv:1810.08168)

(here and in related entries)

]]>I added

- Clay Cordova, Thomas T. Dumitrescu, Kenneth Intriligator,
*Deformations of Superconformal Theories*, (arXiv:1602.01217)

to SCFT. Jacques Distler mentioned it as a source for the claim

]]>a general feature of ((1,0) or (2,0)) SCFTs in 6 dimensions (and $\mathcal{N}=3$ SCFTs in 4 dimensions): they have no relevant or marginal supersymmetry-preserving deformations.

Hey Zoran: it looks like in #28 you are replying to #25. Notice that this dates from over a year back! If you want Tim to see you message, you’d better email him. :-)

]]>Just go to the web page of Oberwolfach http://www.mfo.de and you can find pdfs of the last few years of online reports.

]]>I noticed that the references on the FQFT-perspective on 2dCFT were missing at at conformal field theory. So I added in some, in a new subsection References–Formulation by functors on conformal cobordisms.

]]>The workshop reports are not freely available, are they?

The Oberwolfach workshops reports are usually made freely available online, as far as I am aware.

]]>So they will be at the workshop “Geometry, Quantum Fields, and Strings: Categorial Aspects” next week in Oberwolfach?

The workshop reports are not freely available, are they?

(I hope you get well soon).

]]>Today's arxiv reference form Igor Kříž and collaborators at vertex operator algebra. Probably Urs will hear more from Prof. Kříž at Oberwolfach next week (I was scheduled to go and to my regret do not have physical strength to travel that far without health risk).

]]>Right Tim, this is the canonical kind of statement I learned from (first from Ginsparg’s review when first studying the subject in early 1990s and then from that book when it appeared in 1997 to my delight). And it makes “nevertheless” out of place here.

]]>I am just saying that 2d CFT is better understood than higher dimensional CFT.

Well this is what I agree, however the original statement explictly claimed that the problem/difference is in the problems with **rigour** of defining QFT. In 2d the rigour has been avoided by alternative combinatorial treatment (which is often non-rigourous) of the classification problem of a consistent class (rather than the definition itself), but it works, at least in rational case.

Statements like “more interesting in 2 dim than” or “better understood in 2 dim” or “conformal symmetries are more complicated in 2 dim” etc. have a tendency to be subjective.

The foreword of the Francesco/Mathieu/Sénéchal book does a good job, in my opinion, to dodge this difficulty:

“In d spatial dimensions, there are 1/2(d+1)(d+2) parameters needed to specify a conformal transformation. The consequence of this finiteness is that conformal invariance can say relatively little about the form of correlations, in fact just slightly more than rotation or scale invariance. The exception is in two dimensions, where the above formula gives only the number of parameters specifying conformal transformations that are everywhere well-defined, while there is an infinity variety of local transformations, namely the locally analytic functions. In two dimensions the conformal symmetry is so powerful as to allow…”

(the authors write next “an exact solution of the problem”, which is suboptimal for various reasons, one being that the “problem” isn’t defined yet :-)

]]>Zoran,

maybe there is a misunderstanding here. I am not talking about Feynman integrals etc. I am just saying that 2d CFT is better understood than higher dimensional CFT. I don’t think this is controversial. In fact, I think you make the same point.

]]>It is easy to be an admiral after the battle. If you think you can do the renormalization in 2d etc. hence that the difficulties with **rigour** prevent you to extend than go on. Most of the breakthrough is due to BPZ revolution in 1984 which had nothing to do with rigour in 2d as opposed to “rigour in handling higher dimensional QFT”, but with combinatorial handling of constraints performed in dimension 2 due infinite Virasoro symmetry at physicists’ level of rigour.

Still one can not systematically do the Feynman integral and renormalization etc. in 2d. One **avoids** this by doing bootstrap or something else, instead of defining the analytic Feynman integral one replaces it with comgbinatorial device defined ad hoc with help of highly symmetric situation. Similarly one can do something for TQFTs in higher dimension here and there. But no progress in true general QFT.

Bootstrap or not, very few QFTs in higher dimensions are rigorously understood.

2d CFT has to a large extent been constructed and classified. This is far from true in higher dimensions. Independend of which formalism you use.

]]>