Parabolic semi-orthogonal decompositions and Kummer flat invariants of log schemes

Scherotzke, Sarah; Sibilla, Nicolo; Talpo, Mattia

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Parabolic semi-orthogonal decompositions and Kummer flat invariants of log schemes

Scherotzke, Sarah; Sibilla, Nicolo; Talpo, Mattia

2020 • In Documenta Mathematica

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Disciplines :

Mathematics

Author, co-author :

Scherotzke, Sarah ; University of Luxembourg > Faculty of Science, Technology and Medicine (FSTM) > Department of Mathematics (DMATH)

Sibilla, Nicolo

Talpo, Mattia

External co-authors :

yes

Language :

English

Title :

Parabolic semi-orthogonal decompositions and Kummer flat invariants of log schemes

Publication date :

2020

Journal title :

Documenta Mathematica

ISSN :

1431-0643

Publisher :

Deutsche Mathematiker-Vereinigung, Bielefeld, Germany

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBilu :

since 19 January 2021

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Bibliography

[1] Dan Abramovich and Qile Chen. Stable logarithmic maps to Deligne-Faltings pairs, II. Asian J. Math., 18(3):465488, 2014.
[2] David Ben-Zvi, John Francis, and David Nadler. Integral transforms and Drinfeld centers in derived algebraic geometry. J. Amer. Math. Soc., 23(4):909966, 2010.
[3] Daniel Bergh, Valery A. Lunts, and Olaf M. Schnürer. Geometricity for derived categories of algebraic stacks. Selecta Math., 22(4):25352568, 2016.
[4] A. Blumberg, D. Gepner, and G. Tabuada. A universal characterization of higher algebraic K-theory. Geom. Topol., 17(2):733838, 2013.
[5] Alexei I. Bondal and Mikhail M. Kapranov. Representable functors, Serre functors, and mutations. Izvestiya: Mathematics, 35(3):519541, 1990.
[6] Niels Borne and Angelo Vistoli. Parabolic sheaves on logarithmic schemes. Adv. Math., 231(3-4):13271363.
[7] Charles Cadman. Using stacks to impose tangency conditions on curves. Amer. J. Math., 129(2):405427, 2007.
[8] Andrei Căldăraru. The Mukai pairing, II: the HochschildKostant Rosenberg isomorphism. Adv. Math., 194(1):3466, 2005.
[9] David Carchedi, Sarah Scherotzke, Nicoló Sibilla, and Mattia Talpo. Kato-Nakayama spaces, infinite root stacks, and the profinite homotopy type of log schemes. Geom. Topol., 21(5):30933158, 2017.
[10] Qile Chen. Stable logarithmic maps to DeligneFaltings pairs, I. Ann. of Math., 180(2):455521, 2014.
[11] Denis-Charles Cisinski and Gon¸calo Tabuada. Non-connective K-theory via universal invariants. Compos. Math., 147(4):12811320, 2011.
[12] John Collins, Alexander Polishchuk, et al. Gluing stability conditions. Adv. Theor. Math. Phys., 14(2):563608, 2010.
[13] Brian Conrad. From normal crossings to strict normal crossings. http://math.stanford.edu/conrad/249BW17Page/handouts/…
[14] Ajneet Dhillon and Ivan Kobyzev. G-theory of root stacks and equivariant K-theory. Ann. K-Theory, 4(2):151-183, 2019.
[15] Barbara Fantechi, Etienne Mann, and Fabio Nironi. Smooth toric Deligne-Mumford stacks. J. Reine Angew. Math., 2010(648):201244, 2010.
[16] Dennis Gaitsgory. Ind-coherent sheaves. Mosc. Math. J., 13(3):399528, 2013.
[17] Dennis Gaitsgory and Nick Rozenblyum. A study in derived algebraic geometry, volume 1. American Mathematical Soc., 2017.
[18] Mark Gross and Bernd Siebert. Logarithmic Gromov-Witten invariants. J. Amer. Math. Soc., 26(2):451510, 2013.
[19] Mark Gross, Bernd Siebert, et al. Mirror symmetry via logarithmic degeneration data, I. J. Differential Geom., 72(2):169338, 2006.
[20] Kei Hagihara. Structure theorem of Kummer étale K-group. K-Theory, 29(2):7599, 2003.
[21] Kei Hagihara. Structure theorem of Kummer étale K-group II. Doc. Math., 21:13451396, 2016.
[22] Lars Hesselholt and Ib Madsen. On the K-theory of local fields. Ann. of Math. (2), 158(1):1113, 2003.
[23] Nicholas I. Howell. Motives of log schemes. 2017. https://scholarsbank.uoregon.edu/xmlui/bitstream/handle/
[24] Marc Hoyois, Sarah Scherotzke, and Nicoló Sibilla. Higher traces, noncommutative motives, and the categorified Chern character. Adv. Math., 309:97154, 2017.
[25] Akira Ishii, Kazushi Ueda, et al. The special McKay correspondence and exceptional collections. Tohoku Math. J. (2), 67(4):585609, 2015.
[26] Tetsushi Ito, Kazuya Kato, Chikara Nakayama, and Sampei Usui. On log motives. Tunis. J. Math., 2(4):733-789, 2020.
[27] Jaya N.N. Iyer and Carlos T. Simpson. A relation between the parabolic Chern characters of the de Rham bundles. Math. Ann., 338(2):347383, 2007.
[28] Kazuya Kato. Logarithmic structures of Fontaine-Illusie. In Algebraic analysis, geometry, and number theory (Baltimore, MD, 1988), pages 191224. Johns Hopkins Univ. Press, Baltimore, MD, 1989.
[29] Henning Krause. Localization theory for triangulated categories. In In Triangulated categories, volume 375 of London Math. Soc. Lecture Note Ser., 2010.
[30] Amalendu Krishna and Bhamidi Sreedhar. Atiyah-Segal theorem for Deligne-Mumford stacks and applications. J. Algebr. Geom. 29(3):403-470, 2020.
[31] Alexander Kuznetsov. Derived categories view on rationality problems. In Pardini R., Pirola G. (eds.): Rationality Problems in Algebraic Geometry 67-104. Lecture Notes in Mathematics, vol. 2172. Springer, Cham, 2016.
[32] Malte Leip. Thh of log rings. In L. Hesselholt and P. Scholze (eds.), Arbeitsgemeinschaft: Topological Cyclic Homology. Mathematisches Forschungsinstitut Oberwolfach, 2018.
[33] Joseph Lipman and Amnon Neeman. Quasi-perfect scheme-maps and boundedness of the twisted inverse image functor. Illinois J. Math., 51(1):209236, 2007.
[34] Jacob Lurie. Higher Topos Theory (AM-170). Princeton University Press, 2009.
[35] Jacob Lurie. Higher Algebra. 2016. http://www.math.harvard.edu/lurie/papers/HA.
[36] Wieslawa Niziol. K-theory oflog-schemes. I. Doc. Math., 13:505551, 2008.
[37] Arthur Ogus. Lectures on logarithmic algebraic geometry, vol. 178 of Cambridge Studies in Advanced Mathematics. Cambridge University Press, 2018.
[38] Martin Olsson. Hochschild and cyclic homology of log schemes. Talk available at Error! Hyperlink reference not valid.
[39] Martin Olsson. Logarithmic geometry and algebraic stacks. Ann. Sci. Ecole Norm. Sup. (4), 36(5):747791, 2003.
[40] Martin Olsson. The logarithmic cotangent complex. Math. Ann., 333(4):859931, 2005.
[41] Marco Robalo. K-theory and the bridge from motives to noncommutative motives. Adv. Math., 269:399550, 2015.
[42] John Rognes, Steffen Sagave, and Christian Schlichtkrull. Localization sequences for logarithmic topological hochschild homology. Math. Ann., 363(3-4):13491398, 2015.
[43] Nick Rozenblyum. Filtered colimits of oo-categories. Preprint, http://www.math. harvard.edu/ gaitsgde/GL/colimits.pdf, 2012.
[44] Francesco Sala and Olivier Schiffmann. The circle quantum group and the infinite root stack of a curve (with an appendix by Tatsuki Kuwagaki). Sel. Math., New Ser., 25(5):86 p., paper no. 77, 2019.
[45] Matthew Satriano. Canonical artin stacks over log smooth schemes. Math. Z., 274(3-4):779804, 2013.
[46] Sarah Scherotzke, Nicol`o Sibilla, and Mattia Talpo. On a logarithmic version of the derived McKay correspondence. Compos. Math. 154(12):2534-2585, 2018.
[47] The Stacks Project Authors. Stacks project. 2018. http://stacks.math.columbia.edu.
[48] Goncalo Tabuada. Higher K-theory via universal invariants. Duke Math. J., 145(1):121206, 10 2008.
[49] Mattia Talpo. Moduli of parabolic sheaves on a polarized logarithmic scheme. Trans. Amer. Math. Soc., 369(5):34833545, 2017.
[50] Mattia Talpo. Parabolic sheaves with real weights as sheaves on the KatoNakayama space. Adv. Math., 336:97148, 2018.
[51] Mattia Talpo and Angelo Vistoli. Infinite root stacks and quasi-coheren sheaves on logarithmic schemes. Proc. Lond. Math. Soc., 117(5):11871243, 2018.
[52] Mattia Talpo and Angelo Vistoli. The KatoNakayama space as a transcendental root stack. Int. Math. Res. Not., 2018(19):61456176, 2018.