World Scientific
  • Search
    Quick Search in Journals
    Access type:
    Quick Search anywhere
    Access type:
    Advanced Search
  • My Cart
  •   
Skip main navigation
Close Drawer MenuOpen Drawer Menu

Cookies Notification

We use cookies on this site to enhance your user experience. By continuing to browse the site, you consent to the use of our cookies. Learn More
×

Our site uses Javascript to enchance its usability.You can disable your ad blocker or whitelist our website www.worldscientific.com to view the full content.

Select your blocker:

Adblock Plus Instructions

  1. Click the AdBlock Plus icon in the extension bar
  2. Click the blue power button
  3. Click refresh
Our website is made possible by displaying certain online content using javascript.
In order to view the full content, please disable your ad blocker or whitelist our website www.worldscientific.com.

System Upgrade on Tue, Oct 25th, 2022 at 2am (EDT)

Existing users will be able to log into the site and access content. However, E-commerce and registration of new users may not be available for up to 12 hours.
For online purchase, please visit us again. Contact us at [email protected] for any enquiries.
Research ArticleFree Access

Braided Frobenius algebras from certain Hopf algebras

    https://doi.org/10.1142/S0219498823500123Cited by:1 (Source: Crossref)
    Next

    Abstract

    A braided Frobenius algebra is a Frobenius algebra with a Yang–Baxter operator that commutes with the operations, that are related to diagrams of compact surfaces with boundary expressed as ribbon graphs. A heap is a ternary operation exemplified by a group with the operation (x,y,z)xy1z, that is ternary self-distributive. Hopf algebras can be endowed with the algebra version of the heap operation. Using this, we construct braided Frobenius algebras from a class of certain Hopf algebras that admit integrals and cointegrals. For these Hopf algebras we show that the heap operation induces a Yang–Baxter operator on the tensor product, which satisfies the required compatibility conditions. Diagrammatic methods are employed for proving commutativity between Yang–Baxter operators and Frobenius operations.

    Communicated by J. Gómez-Torrecillas

    AMSC: 17B38, 16T05, 16T25, 57K12

    References

    • 1. J. Carter, A. S. Crans, M. Elhamdadi and M. Saito, Cohomology of categorical self-distributivity, J. Homotopy Relat. Struct. 3(1) (2008) 12–63. Web of ScienceGoogle Scholar
    • 2. S. Carter, A. Ishii, M. Saito and K. Tanaka, Homology for quandles with partial group operations, Pacific J. Math. 287(1) (2017) 19–48. Crossref, Web of ScienceGoogle Scholar
    • 3. J. Collins and R. Duncan, Hopf-Frobenius algebras and a simpler Drinfeld double, in Proc. 16th Int. Conf. Quantum Physics and Logic 2019 (QPL), EPTCS 318, eds. B. CoeckeM. Leifer (2020), pp. 150–180, https://doi.org/10.4204/EPTCS.318.10. CrossrefGoogle Scholar
    • 4. M. Comeau, Braided Frobenius algebras, dissertation, University of Ottawa (2006), https://ruor.uottawa.ca/handle/10393/27343. Google Scholar
    • 5. M. Elhamdadi, M. Saito and E. Zappala, Heap and ternary self-distributive cohomology, preprint (2019), arXiv:1910.02877. Google Scholar
    • 6. M. Elhamdadi, M. Saito and E. Zappala, Higher arity self-distributive operations in Cascades and their cohomology, J. Algebra Appl. 20(7) (2021) 2150116, https://doi.org/10.1142/S0219498821501164. Link, Web of ScienceGoogle Scholar
    • 7. R. Fenn and C. Rourke, Racks and links in codimension two, J. Knot Theory Ramifications 1(4) (1992) 343–406. LinkGoogle Scholar
    • 8. C. Heunen and J. Vicary, Categories for Quantum Theory: An Introduction (Oxford University Press, USA, 2019). CrossrefGoogle Scholar
    • 9. A. Ishii, Moves and invariants for knotted handlebodies, Algebr. Geom. Topol. 8(3) (2008) 1403–1418. Crossref, Web of ScienceGoogle Scholar
    • 10. A. Ishii, S. Matsuzaki and T. Murao, A multiple group rack and oriented spatial surfaces, J. Knot Theory Ramifications 29(7) (2020) 2050046. Link, Web of ScienceGoogle Scholar
    • 11. V. F. R. Jones, Hecke algebra representations of braid groups and link polynomials, Ann. Math. (2) 126(2) (1987) 335–388. Crossref, Web of ScienceGoogle Scholar
    • 12. A. Joyal and R. Street, Braided tensor categories, Adv. Math. 102(1) (1993) 20–78. Crossref, Web of ScienceGoogle Scholar
    • 13. C. Kassel, Quantum Groups, Vol. 155 (Springer Science & Business Media, 2012). Google Scholar
    • 14. M. Khovanov, A categorification of the Jones polynomial, Duke Math. J. 101(3) (2000) 359–426. Crossref, Web of ScienceGoogle Scholar
    • 15. J. Kock, Frobenius Algebras and 2-D Topological Quantum Field Theories, Vol. 59 (Cambridge University Press, 2004). Google Scholar
    • 16. R. G. Larson and M. E. Sweedler, An associative orthogonal bilinear form for Hopf algebras, Amer. J. Math. 91(1) (1969) 75–94. Crossref, Web of ScienceGoogle Scholar
    • 17. V. Lebed, Qualgebras and knotted 3-valent graphs, Fund. Math. 230(2) (2015) 167–204. Crossref, Web of ScienceGoogle Scholar
    • 18. S. Matsuzaki, A diagrammatic presentation and its characterization of non-split compact surfaces in the 3-sphere, preprint (2019), arXiv:1905.03159. Google Scholar
    • 19. B. Pareigis, When Hopf algebras are Frobenius algebras, J. Algebra 18(4) (1971) 588–596. Crossref, Web of ScienceGoogle Scholar
    • 20. N. Yu. Reshetikhin and V. G. Turaev, Ribbon graphs and their invariants derived from quantum groups, Commun. Math. Phys. 127(1) (1990) 1–26. Crossref, Web of ScienceGoogle Scholar
    • 21. M. Saito and E. Zappala, Fundamental heap for framed links and ribbon cocycle invariants, preprint (2020), arXiv:2011.03684. Google Scholar
    • 22. E. Zappala, Non-associative algebraic structures in knot theory, Ph.D. dissertation, University of South Florida (2020). Google Scholar