nLab model structure for parameterized spectra

The first statements are made explicit in HSS, Prop. 4.5 & Prop. 5.11. To see that also the unit axiom is satisfied it is sufficient to see that $\mathbb{S}$ is a cofibrant object. For that use the definition of $\mathbb{S}$ as $\mathbb{S}_t^{\mathcal{I}}[\ast]$ (hidden on p. 38) and the fact that $\mathbb{S}_t^{\mathcal{I}}$ is a left Quillen functor, by HSS, Lem. 5.12.

Proposition

The inclusion of $\mathcal{I}$ -spaces via their zero-spectrum bundles is a bireflective subcategory (according to this Def.) which is also a Quillen adjoint triple:

(2)

Proof

This may be recognized from HSS, Lem. 3.19 & Cor. 5.13.

Definition

In the following we will leave the inclusions

\mathcal{S} \overset{const}{\hookrightarrow} \mathcal{S}^{\mathcal{I}} \overset{0}{\hookrightarrow} \mathrm{Sp}^\Sigma_\mathcal{R}

notationally implicit. For example, for $B$ a simplicial set we write $\big(\mathrm{Sp}^\Sigma_\mathcal{R}\big)_{/B}$ for the slice model structure of (1) over the zero-spectrum bundle over $B$ .

The model category (1) is not quite right proper (cf. pp. 40) but, in its version based on simplicial sets, we have:

Proposition

Left base change $f^\ast$ along Kan fibrations $f \,\colon\, B_1 \to B_2$ of (zero-spectrum bundles (2) over) Kan complexes is a left Quillen functor between the slice model structures of the absolute local model structure. Since, generally, $f^\ast$ is also a right Quillen functor, we have base change Quillen adjoint triples of this form:

Proof

The left Quillen property of $f^\ast$ is HSS20, Lem. 7.22](#HebestreitSagaveSchlichtkrull20). The right Quillen property is mentioned inside the proof of Lem. 8.10 there.

Similarly, but now also for the positive local model structure, we have:

Proposition

With respect absolute or positive local model structure:

Proof

HSS, Lem. 5.17 & Lem. 7.25

(…)

Related concepts

References

Tools

Tools for creating model structures on spectra relative to suitable ambient model categories:

Stefan Schwede, Section 3 of: Spectra in model categories and applications to the algebraic cotangent complex, Journal of Pure and Applied Algebra 120 (1997) 104 [pdf]

and also for model structures on symmetric spectra:

Mark Hovey, Spectra and symmetric spectra in general model categories, Journal of Pure and Applied Algebra 165 1 (2001) 63-127 [arXiv:0004051, doi:10.1016/S0022-4049(00)00172-9]

Over a fixed base

Model structure for genuine equivariant spectra parameterized over a fixed base:

Peter May, Johann Sigurdsson, Chapter 12 of: Parametrized Homotopy Theory, Mathematical Surveys and Monographs 132, AMS (2006) [arXiv:math/0411656]

Over varying bases

Model structures of parameterized spectra over varying bases:

Vincent Braunack-Mayer, Combinatorial parametrised spectra, Algebr. Geom. Topol. 21 (2021) 801-891 [arXiv:1907.08496, doi:10.2140/agt.2021.21.801]

(based on the PhD thesis, 2018)
Fabian Hebestreit, Steffen Sagave, Christian Schlichtkrull, Multiplicative parametrized homotopy theory via symmetric spectra in retractive spaces, Forum of Mathematics, Sigma 8 (2020) e16 [arXiv:1904.01824, doi:10.1017/fms.2020.11]

Last revised on April 20, 2023 at 08:54:10. See the history of this page for a list of all contributions to it.

nLab model structure for parameterized spectra

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Model category theory

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Classes of bundles

Universal bundles

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Proposition

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Definition

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Proposition

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Related concepts

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Over a fixed base

Over varying bases