Publikationen

Publikationen von Prof. Dr. Matthias Kriesell


66.	Maximal ambiguously k-colorable graphs, Journal of Combinatorial Theory (B) 140 (2020), 248-262. DOI.
65.	Rooted complete minors in line graphs with a Kempe coloring, with S. Mohr, Graphs and Combinatorics 35 (2019), 551-557. DOI.
64.	Nonseparating K₄-subdivisions in graphs of minimum degree at least 4, Journal of Graph Theory 89 (2018), 194-213. DOI.
63.	More on foxes, with J. M. Schmidt, Journal of Graph Theory 89 (2018), 101-114. DOI.
62.	Degree Sequences and Edge Connectivity, Abh. Math. Sem. Univ. Hamburg 87 (2017), 343-355. DOI.
61.	Unique colorability and clique minors, Journal of Graph Theory 85 (2017), 207-216. DOI.
60.	Antistrong digraphs, with J. Bang-Jensen, S. Bessy, and B. Jackson, Journal of Combinatorial Theory (B) 122 (2017), 68-90. DOI.
59.	Arc-Disjoint Directed and Undirected Cycles in Digraphs, with J. Bang-Jensen, A. Maddaloni, and S. Simonsen, Journal of Graph Theory 83 (2016), 406-420. DOI.
58.	On graphs double-critical with respect to the colouring number, with A. S. Pedersen, Discrete Mathematics & Theoretical Computer Science 17 (2015), 49-62.
57.	Vertex-disjoint directed and undirected cycles in general digraphs, with J. Bang-Jensen, A. Maddaloni, and S. Simonsen, Journal of Combinatorial Theory (B) 106 (2014), 1-14.
56.	The average degree of minimally contraction-critically 5-connected graphs, with K. Ando and Y. Egawa, Journal of Graph Theory 75 (2014), 331-354. DOI.
55.	Axioms for infinite matroids, with H. Bruhn, R. Diestel, R. Pendavingh, and P. Wollan, Advances in Mathematics 239 (2013), 18-46.
54.	Minimal Connectivity, in Topics in Structural Graph Theory, edited by L. Beineke and R. Wilson, Cambridge University Press (2013), 71-99.
53.	On the problem of finding disjoint cycles and dicycles in a digraph, with J. Bang-Jensen, Combinatorica 31 (2011), 639-668.
52.	What is on his mind?, with J. Barát, Discrete Mathematics 310 (2010), 2573-2583. DOI.
51.	On Seymour's strengthening of Hadwiger's Conjecture for graphs with certain forbidden subgraphs, Discrete Mathematics 310 (2010), 2714-2724. DOI.
50.	Balancing two spanning trees, Networks 57 (2011), 351-353. DOI.
49.	Packing Steiner trees on four terminals, Journal of Combinatorial Theory (B) 100 (2010), 546-553. DOI.
48.	Semantic Enhancement of Social Tagging Systems, with F. Abel, N. Henze, and D. Krause, Annals of Information Systems 6 (2009), 25-54. DOI.
47.	Disjoint directed and undirected paths and cycles in digraphs, with J. Bang-Jensen, Theoretical Computer Science 46-49 (2009), 5138-5144. DOI.
46.	Edge disjoint Steiner trees in graphs without large bridges, Journal of Graph Theory 62 (2009), 188-198. DOI.
45.	Disjoint sub(di)graphs in digraphs, with J. Bang-Jensen, European Conference on Combinatorics, Graph Theory and Applications (2009), Electronic Notes in Discrete Mathematics 34 (2009), 179-183. DOI.
44.	On the number of 4-contractible edges in 4-connected graphs, with K. Ando, Y. Egawa, and K. Kawarabayashi, Journal of Combinatorial Theory (B) 99 (2009), 97-109. DOI.
43.	On the Effect of Group Structures on Ranking Strategies in Folksonomies, with F. Abel, N. Henze, and D. Krause, in: Weaving Services and People on the World Wide Web, Part 2, Springer Berlin Heidelberg (2009), 275-300. DOI.
42.	An elementary proof of Frank's characterization of the graphs having k edge disjoint spanning trees, SUT Journal of Mathematics 44 (2008), 101-107.
41.	On the number of contractible triples in 3-connected graphs, Journal of Combinatorial Theory (B) 98 (2008), 136-145. DOI.
40.	Vertex suppression in 3-connected graphs, Journal of Graph Theory 57 (2008), 41-54. DOI.
39.	On small contractible subgraphs in 3-connected graphs of small average degree, Graphs and Combinatorics 23 (2007), 545-557. DOI.
38.	A constructive characterization of the 3-connected triangle free graphs, Journal of Combinatorial Theory (B) 97 (2007), 358-370. DOI.
37.	How to contract an essentially 6-connected graph to a 5-connected graph, Discrete Mathematics 307 (2007), 494-510. DOI.
36.	A generating theorem for 5-regular simple planar graphs. I., with J. Kanno, Congressus Numerantium 185 (2007), 127-143.
35.	There exist highly critically connected graphs of diameter 3, Graphs and Combinatorics 22 (2006), 481-485. DOI.
34.	Contractions, Cycle Double Covers, and Cyclic Colorings in Locally Connected Graphs, Journal of Combinatorial Theory (B) 96 (2006), 881-900. DOI.
33.	Mader's conjecture on extremely critical graphs, Combinatorica 26 (2006), 277-314. DOI.
32.	On the Pancyclicity of Lexicographic Products, with T. Kaiser, Graphs and Combinatorics 22 (2006), 51-58. DOI.
31.	Average Degree and Contractibility, Journal of Graph Theory 51 (2006), 205-224. DOI.
30.	Global connectivity and expansion: long cycles and factors in f-connected graphs, with S. Brandt, H. Broersma, and R. Diestel, Combinatorica 26 (2006), 17-36. DOI.
29.	Closed Separator Sets, Combinatorica 25 (2005), 575-598. DOI.
28.	A Pictured Memorandum on Synthesis Phenomena Occurring in the Homicidal Chauffeur Game, with M. H. Breitner and A. Meyer, Proceedings of the Fifth International ISDG Workshop, International Society of Dynamic Games, Segovia (2005), 17-32.
27.	The Personal Publication Reader, with F. Abel, R. Baumgartner, A. Brooks, C. Enzi, G. Gottlob, N. Henze, M. Herzog, W. Nejdl, K. Tomaschewski, Semantic Web Challenge, 4th International Semantic Web Conference, Galway (2005).
26.	Disjoint A-paths in Digraphs, Journal of Combinatorial Theory (B) 95 (2005), 168-172. DOI.
25.	Semantic Web enabled Information Systems: Personalized Views on Web Data, with R. Baumgartner, C. Enzi, N. Henze, M. Herrlich, M. Herzog, K. Tomaschewski, International Ubiquitous Web Systems and Intelligence Workshop, Singapore (UWSI 2005). DOI.
24.	Cayley DHTs - A Group-Theoretic Framework for Analyzing DHTs, with W. Nejdl and C. Qu, 2nd International Symposium on Parallel and Distributed Processing, Hongkong (ISPA 2004). Also contained as a chapter in Semantic Web and Peer-to-Peer, S. Staab und H. Stuckenschmidt (eds.), Springer Heidelberg (2005). DOI.
23.	Triangle Density and Contractibility, Combinatorics, Probability and Computing 14 (2005), 133-146. DOI.
22.	Personalization Functionality for the Semantic Web: Architectural Outline and First Sample Implementations, with N. Henze, 1st International Workshop on Engineering the Adaptive Web (EAW 2004).
21.	On decomposing a hypergraph into k connected sub-hypergraphs, with A. Frank and T. Király, Discrete Applied Mathematics 131 (2003), 373-383. DOI.
20.	Edge disjoint trees containing some given vertices in a graph, Journal of Combinatorial Theory (B) 88 (2003), 53-65. DOI.
19.	A contribution to a conjecture of A. Saito, Graphs and Combinatorics 18 (2002), 565-571. DOI.
18.	A survey on contractible edges in graphs of a given vertex connectivity, Graphs and Combinatorics 18 (2002), 1-30. DOI.
17.	Upper bounds to the number of vertices in a k-critically n-connected graph, Graphs and Combinatorics 18 (2002), 133-146. DOI.
16.	Almost all 3-connected graphs contain a contractible set of k vertices, Journal of Combinatorial Theory (B) 83 (2001), 305-319. DOI.
15.	All 4-connected line graphs of claw free graphs are Hamiltonian connected, Journal of Combinatorial Theory (B) 82 (2001), 306-315. DOI.
14.	On factors of 4-connected claw free graphs, with H. Broersma and Zd. Ryjácek, Journal of Graph Theory 37 (2001), 125-136. DOI.
13.	A degree sum condition for the existence of a contractible edge in a k-connected graph, Journal of Combinatorial Theory (B) 82 (2001), 81-101. DOI.
12.	Induced paths in 5-connected graphs, Journal of Graph Theory 36 (2001), 52-58. DOI.
11.	The symmetric (2k,k)-graphs, Journal of Graph Theory 36 (2001), 35-51. DOI.
10.	Contractible subgraphs in 3-connected graphs, Journal of Combinatorial Theory (B) 80 (2000), 32-48. DOI.
9.	The k-critically 2k-connected graphs for k=3 and k=4, Journal of Combinatorial Theory (B) 78 (2000), 69-80. DOI.
8.	Contractible non-edges in triangle free graphs, Graphs and Combinatorics 15 (1999), 429-439.
7.	On a conjecture of Thomassen and Toft, Journal of Graph Theory 32 (1999), 118-122.
6.	Local spanning trees in graphs and hypergraph decomposition with respect to edge connectivity, 6th Twente Workshop on Graphs and Combinatorial Optimization (Enschede 1999), Electron. Notes Discrete Math., 3, Elsevier, Amsterdam (1999). DOI.
5.	Edge-dominating trails in AT-free graphs, with E. Köhler, 6th Twente Workshop on Graphs and Combinatorial Optimization (Enschede 1999), Electron. Notes Discrete Math., 3, Elsevier, Amsterdam (1999). DOI.
4.	Contractible non-edges in 3-connected graphs, Journal of Combinatorial Theory (B) 74 (1998), 192-201. DOI.
3.	On k-critically connected line graphs, Journal of Combinatorial Theory (B) 74 (1998), 1-7. DOI.
2.	Criticity Results Concerning the Connectivity of Graphs, PhD Thesis, TU Berlin (1997).
1.	A note on Hamiltonian Cycles in Lexicographical Products, Journal of Automata, Languages, and Combinatorics 2 (1997), 135-138.

Editorial Activities:

3. The Electronic Journal of Combinatorics

2. Discrete Mathematics & Theoretical Computer Science

1. AKCE International Journal of Graphs and Combinatorics

Publikationen im Fachgebiet

Bang-Jensen, Jørgen; Bessy, Stéphane; Huang, Jing; Kriesell, Matthias
Good orientations of unions of edge-disjoint spanning trees. - In: Journal of graph theory, ISSN 1097-0118, Bd. 96 (2021), 4, S. 594-618

In this paper, we exhibit connections between the following subjects: Tree packing in graphs and digraphs (both behave completely different), the rigidity matroid of a graph, Henneberg moves on trees, the conjectures of Thomassen and Matthews and Sumner, and (s,t)-orderings of digraphs. We do this by studying graphs which admit acyclic orientations that contain an out-branching and in-branching which are arc-disjoint (such an orientation is called good). A 2T-graph is a graph whose edge set can be decomposed into two edge-disjoint spanning trees. It is a well-known result due to Tutte and Nash-Williams, respectively, that every 4-edge-connected graph contains a spanning 2T-graph. Vertex-minimal 2T-graphs with at least two vertices which are known as generic circuits play an important role in rigidity theory for graphs. We prove that every generic circuit has a good orientation. Using this result we prove that if G is 2T-graph whose vertex set has a partition V1,V2, ,Vk so that each Vi induces a generic circuit Gi of G and the set of edges between different Gi's form a matching in G, then G has a good orientation. We also obtain a characterization for the case when the set of edges between different Gi's form a double tree, that is, if we contract each Gi to one vertex, and delete parallel edges we obtain a tree. All our proofs are constructive and imply polynomial algorithms for finding the desired good orderings and the pairs of arc-disjoint branchings which certify that the orderings are good. We identify a structure which can be used to certify that a given 2T-graph does not have a good orientation.

https://doi.org/10.1002/jgt.22633

Mohr, Samuel;
Rooted structures in graphs : a project on Hadwiger's conjecture, rooted minors, and Tutte cycles. - Ilmenau : Universitätsbibliothek, 2020. - 1 Online-Ressource (viii, 131 Blätter)
Technische Universität Ilmenau, Dissertation 2020

Hadwigers Vermutung ist eine der anspruchsvollsten Vermutungen für Graphentheoretiker und bietet eine weitreichende Verallgemeinerung des Vierfarbensatzes. Ausgehend von dieser offenen Frage der strukturellen Graphentheorie werden gewurzelte Strukturen in Graphen diskutiert. Eine Transversale einer Partition ist definiert als eine Menge, welche genau ein Element aus jeder Menge der Partition enthält und sonst nichts. Für einen Graphen G und eine Teilmenge T seiner Knotenmenge ist ein gewurzelter Minor von G ein Minor, der T als Transversale seiner Taschen enthält. Sei T eine Transversale einer Färbung eines Graphen, sodass es ein System von kanten-disjunkten Wegen zwischen allen Knoten aus T gibt; dann stellt sich die Frage, ob es möglich ist, die Existenz eines vollständigen, in T gewurzelten Minors zu gewährleisten. Diese Frage ist eng mit Hadwigers Vermutung verwoben: Eine positive Antwort würde Hadwigers Vermutung für eindeutig färbbare Graphen bestätigen. In dieser Arbeit wird ebendiese Fragestellung untersucht sowie weitere Konzepte vorgestellt, welche bekannte Ideen der strukturellen Graphentheorie um eine Verwurzelung erweitern. Beispielsweise wird diskutiert, inwiefern hoch zusammenhängende Teilmengen der Knotenmenge einen hoch zusammenhängenden, gewurzelten Minor erzwingen. Zudem werden verschiedene Ideen von Hamiltonizität in planaren und nicht-planaren Graphen behandelt.

https://nbn-resolving.org/urn:nbn:de:gbv:ilm1-2020000294

Kriesell, Matthias;
Maximal ambiguously k-colorable graphs. - In: Journal of combinatorial theory, Bd. 140 (2020), S. 248-262

https://doi.org/10.1016/j.jctb.2019.05.007

Kriesell, Matthias; Mohr, Samuel
Rooted complete minors in line graphs with a Kempe coloring. - In: Graphs and combinatorics, ISSN 1435-5914, Bd. 35 (2019), 2, S. 551-557

https://doi.org/10.1007/s00373-019-02012-7

Kriesell, Matthias;
Nonseparating K4-subdivisions in graphs of minimum degree at least 4. - In: Journal of graph theory, ISSN 1097-0118, Bd. 89 (2018), 2, S. 194-213
Im Titel ist "4" tiefgestellt

https://doi.org/10.1002/jgt.22247

Kriesell, Matthias; Schmidt, Jens M.
More on foxes. - In: Journal of graph theory, ISSN 1097-0118, Bd. 89 (2018), 2, S. 101-114

https://doi.org/10.1002/jgt.22243

Brause, Christoph; Kemnitz, Arnfried; Marangio, Massimiliano; Pruchnewski, Anja; Voigt, Margit
Sum choice number of generalized [theta]-graphs. - In: Discrete mathematics, Bd. 340 (2017), 11, S. 2633-2640

https://doi.org/10.1016/j.disc.2016.11.028

Kriesell, Matthias;
Degree sequences and edge connectivity. - In: Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg, ISSN 1865-8784, Bd. 87 (2017), 2, S. 343-355

https://doi.org/10.1007/s12188-016-0171-0

Kriesell, Matthias;
Unique colorability and clique minors. - In: Journal of graph theory, ISSN 1097-0118, Bd. 85 (2017), 1, S. 207-216

https://doi.org/10.1002/jgt.22056

Bang-Jensen, Jørgen; Bessy, Stéphane; Jackson, Bill; Kriesell, Matthias
Antistrong digraphs. - In: Journal of combinatorial theory. . - Orlando, Fla. : Academic Press, 1971- , ZDB-ID: 1469158-9, Bd. 122 (2017), S. 68-90

http://dx.doi.org/10.1016/j.jctb.2016.05.004

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