Is there a fibration sequence of spectra $K\mathbb{F}_q\to KU\to KU$?

Question

Quillen famously constructed a fibration sequence $BGL(\mathbb{F}_q)^+ \to BU \to BU$ to compute the algebraic K-groups of finite fields, where the second map is $\psi^\ell-1$ for $\ell$ a generator of $\mathbb{Z}_q^\times$. Does this lift to the level of the K-theory spectra?

I don't know much about delooping, but I would guess that if we had a fibration sequence $BGL(\mathbb{F}_q)^+ \to BU\times \mathbb{Z} \to BU\times \mathbb{Z}$ of $E_\infty$-spaces, this would then deloop to a fibration sequence of the associated connective $\Omega$-spectra. However, this seems out of reach, since Quillen's method proceeds via the Atiyah-Segal completion theorem and only produces a homotopy class of map.

Answer 1

The infinite loop space/spectrum level statements were written down in

May, Quinn, Ray, Tornehave: "$E_\infty$ Ring Spaces and $E_\infty$ Ring Spectra" (1977) http://www.math.uchicago.edu/~may/BOOKS/e_infty.pdf ,

see Theorem VIII.3.2 and its proof on pages 224-225. For a prime $p$ and a prime power $r=q$ generating the $p$-adic units (take $r=3$ for $p=2$), May writes $j^\delta_p$ for $K(\mathbb{F}_r)$ completed at $p$, viewed as a discrete model for the connective complex image-of-$J$ spectrum, and argues that this spectrum is equivalent to the homotopy fiber $F\psi^r$ of $\psi^r-1 \colon kU \to bu$, after $p$-completion. Here $kU = ku$ is the connective complex $K$-theory spectrum and $bu$ is its $1$-connected cover. See also Section 19 of the survey paper

May: "Infinite Loop Space Theory" (1977) http://www.math.uchicago.edu/~may/PAPERS/18.pdf ,

which may be easier to read.