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When I was first learning QFT, I found it very helpful to start in the parts that rest on the most solid mathematical foundations, like topological quantum field theories and 2d conformal field theories. This might be an especially good place to start if you're aiming for the geometric applications of QFT, because I think many of those applications currently revolve around TQFTs and CFTs.

There are lots of places you can learn about TQFTs.

  • My favorite introduction is Joachim Kock's Frobenius algebras and 2D topological quantum field theories, which starts with the definition of a TQFT and builds up to a detailed proof of the first big theorem in the subject: the classification of 2d TQFTs.
  • For a quicker introduction, you might try these seminar talks by John Baez, Julie Bergner, Chris Carlson, and John Huerta. PDF notes are linked from these pages: 1 | 2 | 3 | 4 | 5.
  • For a taste of how TQFTs can be used to do geometry, try using using a topological gauge theory with finite gauge group $G$ to count principal $G$-bundles over a compact surface. Ulrich Pennig has some lovely notes on this. There's also a relevant MO questionrelevant MO question.
  • For a taste of how TQFTs can be used to do representation theory, I recommend Qiaochu Yuan's excellent notes on a field-theoretic proof of Mednykh's formula.
  • When you're ready to leave the 1-categorical nest and start thinking about extended TQFTs, try David Ben-Zvi's Northwestern lectures, as recorded by Orit Davidovich and and Alex Hoffnung. PDF notes are linked from these pages: 1 | 2 | 3.
  • For a really serious application, you can try Turaev's Quantum Invariants of Knots and 3-Manifolds, which discusses the TQFT that Witten discovered for the Jones polynomial. It's tough reading, though.
  • I love John Baez's "Quantum Quandaries" for the physics inspiration it provides, though maybe that's not your thing.

Here are a handful of references for CFTs that I like.

Finally, I should make it clear that there's lots of cool geometry related to QFTs more complicated and mysterious than TQFTs and CFTs.

There's also lots of cool math related to QFTs more like the one's you'd encounter in an introductory physics course, although much of it is more analytic than geometric. Some references:

Good luck!

When I was first learning QFT, I found it very helpful to start in the parts that rest on the most solid mathematical foundations, like topological quantum field theories and 2d conformal field theories. This might be an especially good place to start if you're aiming for the geometric applications of QFT, because I think many of those applications currently revolve around TQFTs and CFTs.

There are lots of places you can learn about TQFTs.

  • My favorite introduction is Joachim Kock's Frobenius algebras and 2D topological quantum field theories, which starts with the definition of a TQFT and builds up to a detailed proof of the first big theorem in the subject: the classification of 2d TQFTs.
  • For a quicker introduction, you might try these seminar talks by John Baez, Julie Bergner, Chris Carlson, and John Huerta. PDF notes are linked from these pages: 1 | 2 | 3 | 4 | 5.
  • For a taste of how TQFTs can be used to do geometry, try using using a topological gauge theory with finite gauge group $G$ to count principal $G$-bundles over a compact surface. Ulrich Pennig has some lovely notes on this. There's also a relevant MO question.
  • For a taste of how TQFTs can be used to do representation theory, I recommend Qiaochu Yuan's excellent notes on a field-theoretic proof of Mednykh's formula.
  • When you're ready to leave the 1-categorical nest and start thinking about extended TQFTs, try David Ben-Zvi's Northwestern lectures, as recorded by Orit Davidovich and and Alex Hoffnung. PDF notes are linked from these pages: 1 | 2 | 3.
  • For a really serious application, you can try Turaev's Quantum Invariants of Knots and 3-Manifolds, which discusses the TQFT that Witten discovered for the Jones polynomial. It's tough reading, though.
  • I love John Baez's "Quantum Quandaries" for the physics inspiration it provides, though maybe that's not your thing.

Here are a handful of references for CFTs that I like.

Finally, I should make it clear that there's lots of cool geometry related to QFTs more complicated and mysterious than TQFTs and CFTs.

There's also lots of cool math related to QFTs more like the one's you'd encounter in an introductory physics course, although much of it is more analytic than geometric. Some references:

Good luck!

When I was first learning QFT, I found it very helpful to start in the parts that rest on the most solid mathematical foundations, like topological quantum field theories and 2d conformal field theories. This might be an especially good place to start if you're aiming for the geometric applications of QFT, because I think many of those applications currently revolve around TQFTs and CFTs.

There are lots of places you can learn about TQFTs.

  • My favorite introduction is Joachim Kock's Frobenius algebras and 2D topological quantum field theories, which starts with the definition of a TQFT and builds up to a detailed proof of the first big theorem in the subject: the classification of 2d TQFTs.
  • For a quicker introduction, you might try these seminar talks by John Baez, Julie Bergner, Chris Carlson, and John Huerta. PDF notes are linked from these pages: 1 | 2 | 3 | 4 | 5.
  • For a taste of how TQFTs can be used to do geometry, try using using a topological gauge theory with finite gauge group $G$ to count principal $G$-bundles over a compact surface. Ulrich Pennig has some lovely notes on this. There's also a relevant MO question.
  • For a taste of how TQFTs can be used to do representation theory, I recommend Qiaochu Yuan's excellent notes on a field-theoretic proof of Mednykh's formula.
  • When you're ready to leave the 1-categorical nest and start thinking about extended TQFTs, try David Ben-Zvi's Northwestern lectures, as recorded by Orit Davidovich and and Alex Hoffnung. PDF notes are linked from these pages: 1 | 2 | 3.
  • For a really serious application, you can try Turaev's Quantum Invariants of Knots and 3-Manifolds, which discusses the TQFT that Witten discovered for the Jones polynomial. It's tough reading, though.
  • I love John Baez's "Quantum Quandaries" for the physics inspiration it provides, though maybe that's not your thing.

Here are a handful of references for CFTs that I like.

Finally, I should make it clear that there's lots of cool geometry related to QFTs more complicated and mysterious than TQFTs and CFTs.

There's also lots of cool math related to QFTs more like the one's you'd encounter in an introductory physics course, although much of it is more analytic than geometric. Some references:

Good luck!

Corrected attribution of Mednykh's formula proof
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Vectornaut
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When I was first learning QFT, I found it very helpful to start in the parts that rest on the most solid mathematical foundations, like topological quantum field theories and 2d conformal field theories. This might be an especially good place to start if you're aiming for the geometric applications of QFT, because I think many of those applications currently revolve around TQFTs and CFTs.

There are lots of places you can learn about TQFTs.

  • My favorite introduction is Joachim Kock's Frobenius algebras and 2D topological quantum field theories, which starts with the definition of a TQFT and builds up to a detailed proof of the first big theorem in the subject: the classification of 2d TQFTs.
  • For a quicker introduction, you might try these seminar talks by John Baez, Julie Bergner, Chris Carlson, and John Huerta. PDF notes are linked from these pages: 1 | 2 | 3 | 4 | 5.
  • For a taste of how TQFTs can be used to do geometry, try using using a topological gauge theory with finite gauge group $G$ to count principal $G$-bundles over a compact surface. Ulrich Pennig has some lovely notes on this. There's also a relevant MO question.
  • For a taste of how TQFTs can be used to do representation theory, I recommend Qiaochu Yuan's excellent notes on a field-theoretic proof of Mednykh's formula.
  • When you're ready to leave the 1-categorical nest and start thinking about extended TQFTs, try David Ben-Zvi's Northwestern lectures, as recorded by Orit Davidovich and and Alex Hoffnung. PDF notes are linked from these pages: 1 | 2 | 3.
  • For a really serious application, you can try Turaev's Quantum Invariants of Knots and 3-Manifolds, which discusses the TQFT that Witten discovered for the Jones polynomial. It's tough reading, though.
  • I love John Baez's "Quantum Quandaries" for the physics inspiration it provides, though maybe that's not your thing.

Here are a handful of references for CFTs that I like.

Finally, I should make it clear that there's lots of cool geometry related to QFTs more complicated and mysterious than TQFTs and CFTs.

There's also lots of cool math related to QFTs more like the one's you'd encounter in an introductory physics course, although much of it is more analytic than geometric. Some references:

Good luck!

When I was first learning QFT, I found it very helpful to start in the parts that rest on the most solid mathematical foundations, like topological quantum field theories and 2d conformal field theories. This might be an especially good place to start if you're aiming for the geometric applications of QFT, because I think many of those applications currently revolve around TQFTs and CFTs.

There are lots of places you can learn about TQFTs.

  • My favorite introduction is Joachim Kock's Frobenius algebras and 2D topological quantum field theories, which starts with the definition of a TQFT and builds up to a detailed proof of the first big theorem in the subject: the classification of 2d TQFTs.
  • For a quicker introduction, you might try these seminar talks by John Baez, Julie Bergner, Chris Carlson, and John Huerta. PDF notes are linked from these pages: 1 | 2 | 3 | 4 | 5.
  • For a taste of how TQFTs can be used to do geometry, try using using a topological gauge theory with finite gauge group $G$ to count principal $G$-bundles over a compact surface. Ulrich Pennig has some lovely notes on this. There's also a relevant MO question.
  • For a taste of how TQFTs can be used to do representation theory, I recommend Qiaochu Yuan's excellent field-theoretic proof of Mednykh's formula.
  • When you're ready to leave the 1-categorical nest and start thinking about extended TQFTs, try David Ben-Zvi's Northwestern lectures, as recorded by Orit Davidovich and and Alex Hoffnung. PDF notes are linked from these pages: 1 | 2 | 3.
  • For a really serious application, you can try Turaev's Quantum Invariants of Knots and 3-Manifolds, which discusses the TQFT that Witten discovered for the Jones polynomial. It's tough reading, though.
  • I love John Baez's "Quantum Quandaries" for the physics inspiration it provides, though maybe that's not your thing.

Here are a handful of references for CFTs that I like.

Finally, I should make it clear that there's lots of cool geometry related to QFTs more complicated and mysterious than TQFTs and CFTs.

There's also lots of cool math related to QFTs more like the one's you'd encounter in an introductory physics course, although much of it is more analytic than geometric. Some references:

Good luck!

When I was first learning QFT, I found it very helpful to start in the parts that rest on the most solid mathematical foundations, like topological quantum field theories and 2d conformal field theories. This might be an especially good place to start if you're aiming for the geometric applications of QFT, because I think many of those applications currently revolve around TQFTs and CFTs.

There are lots of places you can learn about TQFTs.

  • My favorite introduction is Joachim Kock's Frobenius algebras and 2D topological quantum field theories, which starts with the definition of a TQFT and builds up to a detailed proof of the first big theorem in the subject: the classification of 2d TQFTs.
  • For a quicker introduction, you might try these seminar talks by John Baez, Julie Bergner, Chris Carlson, and John Huerta. PDF notes are linked from these pages: 1 | 2 | 3 | 4 | 5.
  • For a taste of how TQFTs can be used to do geometry, try using using a topological gauge theory with finite gauge group $G$ to count principal $G$-bundles over a compact surface. Ulrich Pennig has some lovely notes on this. There's also a relevant MO question.
  • For a taste of how TQFTs can be used to do representation theory, I recommend Qiaochu Yuan's excellent notes on a field-theoretic proof of Mednykh's formula.
  • When you're ready to leave the 1-categorical nest and start thinking about extended TQFTs, try David Ben-Zvi's Northwestern lectures, as recorded by Orit Davidovich and and Alex Hoffnung. PDF notes are linked from these pages: 1 | 2 | 3.
  • For a really serious application, you can try Turaev's Quantum Invariants of Knots and 3-Manifolds, which discusses the TQFT that Witten discovered for the Jones polynomial. It's tough reading, though.
  • I love John Baez's "Quantum Quandaries" for the physics inspiration it provides, though maybe that's not your thing.

Here are a handful of references for CFTs that I like.

Finally, I should make it clear that there's lots of cool geometry related to QFTs more complicated and mysterious than TQFTs and CFTs.

There's also lots of cool math related to QFTs more like the one's you'd encounter in an introductory physics course, although much of it is more analytic than geometric. Some references:

Good luck!

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Vectornaut
  • 2.3k
  • 2
  • 26
  • 24

When I was first learning QFT, I found it very helpful to start in the parts that rest on the most solid mathematical foundations, like topological quantum field theories and 2d conformal field theories. This might be an especially good place to start if you're aiming for the geometric applications of QFT, because I think many of those applications currently revolve around TQFTs and CFTs.

There are lots of places you can learn about TQFTs.

  • My favorite introduction is Joachim Kock's Frobenius algebras and 2D topological quantum field theories, which starts with the definition of a TQFT and builds up to a detailed proof of the first big theorem in the subject: the classification of 2d TQFTs.
  • For a quicker introduction, you might try these seminar talks by John Baez, Julie Bergner, Chris Carlson, and John Huerta. PDF notes are linked from these pages: 1 | 2 | 3 | 4 | 5.
  • For a taste of how TQFTs can be used to do geometry, try using using a topological gauge theory with finite gauge group $G$ to count principal $G$-bundles over a compact surface. Ulrich Pennig has some lovely notes on this. There's also a relevant MO question.
  • For a taste of how TQFTs can be used to do representation theory, I recommend Qiaochu Yuan's excellent field-theoretic proof of Mednykh's formula.
  • When you're ready to leave the 1-categorical nest and start thinking about extended TQFTs, try David Ben-Zvi's Northwestern lectures, as recorded by Orit Davidovich and and Alex Hoffnung. PDF notes are linked from these pages: 1 | 2 | 3.
  • For a really serious application, you can try Turaev's Quantum Invariants of Knots and 3-Manifolds, which discusses the TQFT that Witten discovered for the Jones polynomial. It's tough reading, though.
  • I love John Baez's "Quantum Quandaries" for the physics inspiration it provides, though maybe that's not your thing.

Here are a handful of references for CFTs that I like.

Finally, I should make it clear that there's lots of cool geometry related to QFTs more complicated and mysterious than TQFTs and CFTs.

There's also lots of cool math related to QFTs more like the one's you'd encounter in an introductory physics course, although much of it is more analytic than geometric. Some references:

Good luck!