Quantum motions are encoded by a particular family of recursive Hochschild equations in the renormalization Hopf algebra which represent Dyson–Schwinger equations, combinatorially. Feynman graphons, which topologically complete the space of Feynman diagrams of a gauge field theory, are considered to formulate some random graph representations for solutions of quantum motions. This framework leads us to explain the structures of Tutte and Kirchhoff–Symanzik polynomials associated with solutions of Dyson–Schwinger equations. These new graph polynomials are applied to formulate a new parametric representation for large Feynman diagrams and their corresponding Feynman rules.

@article{MM3_2023_27_2_a5,
     author = {Ali Shojaei-Fard},
     title = {Graph polynomials associated with {Dyson{\textendash}Schwinger} equations},
     journal = {Mathematica Moravica},
     pages = {91 - 114},
     publisher = {mathdoc},
     volume = {27},
     number = {2},
     year = {2023},
     url = {https://geodesic-test.mathdoc.fr/item/MM3_2023_27_2_a5/}
}

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Ali Shojaei-Fard. Graph polynomials associated with Dyson–Schwinger equations. Mathematica Moravica, Tome 27 (2023) no. 2. https://geodesic-test.mathdoc.fr/item/MM3_2023_27_2_a5/