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\newcommand{\widevec}{\overrightarrow} \newcommand{\darr}{\downarrow} \newcommand{\nearr}{\nearrow} \newcommand{\nwarr}{\nwarrow} \newcommand{\searr}{\searrow} \newcommand{\swarr}{\swarrow} \newcommand{\curvearrowbotright}{\curvearrowright} \newcommand{\uparr}{\uparrow} \newcommand{\downuparrow}{\updownarrow} \newcommand{\duparr}{\updownarrow} \newcommand{\updarr}{\updownarrow} \newcommand{\gt}{>} \newcommand{\lt}{<} \newcommand{\map}{\mapsto} \newcommand{\embedsin}{\hookrightarrow} \newcommand{\Alpha}{A} \newcommand{\Beta}{B} \newcommand{\Zeta}{Z} \newcommand{\Eta}{H} \newcommand{\Iota}{I} \newcommand{\Kappa}{K} \newcommand{\Mu}{M} \newcommand{\Nu}{N} \newcommand{\Rho}{P} \newcommand{\Tau}{T} \newcommand{\Upsi}{\Upsilon} \newcommand{\omicron}{o} \newcommand{\lang}{\langle} \newcommand{\rang}{\rangle} \newcommand{\Union}{\bigcup} \newcommand{\Intersection}{\bigcap} \newcommand{\Oplus}{\bigoplus} \newcommand{\Otimes}{\bigotimes} \newcommand{\Wedge}{\bigwedge} \newcommand{\Vee}{\bigvee} \newcommand{\coproduct}{\coprod} \newcommand{\product}{\prod} \newcommand{\closure}{\overline} \newcommand{\integral}{\int} \newcommand{\doubleintegral}{\iint} \newcommand{\tripleintegral}{\iiint} \newcommand{\quadrupleintegral}{\iiiint} \newcommand{\conint}{\oint} \newcommand{\contourintegral}{\oint} \newcommand{\infinity}{\infty} \newcommand{\bottom}{\bot} \newcommand{\minusb}{\boxminus} \newcommand{\plusb}{\boxplus} \newcommand{\timesb}{\boxtimes} \newcommand{\intersection}{\cap} \newcommand{\union}{\cup} \newcommand{\Del}{\nabla} \newcommand{\odash}{\circleddash} \newcommand{\negspace}{\!} \newcommand{\widebar}{\overline} \newcommand{\textsize}{\normalsize} \renewcommand{\scriptsize}{\scriptstyle} \newcommand{\scriptscriptsize}{\scriptscriptstyle} \newcommand{\mathfr}{\mathfrak} \newcommand{\statusline}[2]{#2} \newcommand{\tooltip}[2]{#2} \newcommand{\toggle}[2]{#2} % Theorem Environments \theoremstyle{plain} \newtheorem{theorem}{Theorem} \newtheorem{lemma}{Lemma} \newtheorem{prop}{Proposition} \newtheorem{cor}{Corollary} \newtheorem*{utheorem}{Theorem} \newtheorem*{ulemma}{Lemma} \newtheorem*{uprop}{Proposition} \newtheorem*{ucor}{Corollary} \theoremstyle{definition} \newtheorem{defn}{Definition} \newtheorem{example}{Example} \newtheorem*{udefn}{Definition} \newtheorem*{uexample}{Example} \theoremstyle{remark} \newtheorem{remark}{Remark} \newtheorem{note}{Note} \newtheorem*{uremark}{Remark} \newtheorem*{unote}{Note} %------------------------------------------------------------------- \begin{document} %------------------------------------------------------------------- \section*{special lambda-ring} [[John Baez]]: I believe `special $\lambda$-ring' is an old-fashioned term for what almost everyone now calls a [[lambda-ring]], the `nonspecial' ones having been found to be too general. This, at least, is what Hazewinkel says in his article cited on our page about [[lambda-ring]]s. So I believe this page here should be folded in with [[lambda-ring]]. At the very least, we should give both definitions of $\lambda$-ring --- special and unspecial --- over at [[lambda-ring]]. When I last checked, that page did not include a definition. For any [[commutative ring]] $A$ we can consider the set $\Phi(A)$ of [[power series]] in an indeterminate $t$ with coefficients in $A$ whose constant term is $1$: $f(t) = 1 + a_1t + a_2t^2 + \ldots$ These form an [[abelian group]] under multiplication with the constant power-series $1$ as unit. What may be less familiar is that there is a commutative associative binary operation $\circ$ on this set that distributes over multiplication making $\Phi(A)$ into a commutative ring, for which the function $\epsilon_A: \Phi(A) \rightarrow A$ taking $f(t)$ to $f'(0)$ is a homomorphism. So what is usually called multiplication of power-series becomes \emph{addition} in this ring, with $1$ as zero; very confusing. Of course, $\Phi$ is a functor from rings to rings and $\epsilon$ is a natural transformation. In fact it is the counit of a [[comonad]]. How is $\circ$ defined? We impose the condition $(1 + a t)\circ f(t) = f(a t)$ for $a\in A$ and $f(t)\in \Phi(A)$. It is now clear from distributivity that if $g(t) = \Pi_j(1+a_j t)$ then $g(t)\circ f(t) = \Pi_j f(a_j t)$. But what happens if $g(t)$ is not a product of linear factors? Newton's theorem on [[symmetric polynomial]]s comes to the rescue. For we note that the coefficient of $t^n$ in $\Pi_j f(a_j t)$ is a symmetric function in the $a_j$ and so can be expressed as a polynomial over the integers in the first $n$ coefficients of $g(t)$ and of $f(t)$. In this way we have indicated that a universal formula for multiplication in $\Phi(A)$ exists, though we may not have written it down explicitly. We use the same trick in defining the comultiplication $\mu_A : \Phi(A) \rightarrow \Phi(\Phi(A))$ but now our old-fashioned notation and use of indeterminates starts to cause trouble. A power-series in $\Phi(A)$ is really just a sequence $(a_1, a_2, \ldots)$. We demand that $\mu_A (a,0,0, \ldots) = ((a,0,0, \ldots),(0,0, \ldots), \ldots )$ Again, to define $\mu_A$ on an arbitrary power-series, factorize it formally into linear factors, apply the rule and distributivity, and apply Newton's theorem. A \textbf{special $\lambda$-ring} is a [[coalgebra]] for the comonad $\Phi$ above. If $\xi : A \rightarrow \Phi(A)$ is the costructure map for such a coalgebra, we define unary operations $\lambda^n$ on $A$ by the formula $\xi(a) = 1 + \lambda^1(a)t + \lambda^2(a)t^2 + \ldots$ The counit condition forces $\lambda^1(a) = a$. It is also traditional to denote $\xi(a)$ by $\lambda_t (a)$. Note that $\lambda_t(a_1 + a_2) = \lambda_t(a_1)\lambda_t(a_2)$ and that $\lambda_t(a_1 a_2) = \lambda_t(a_1)\circ\lambda_t(a_2)$. The functor $\Phi$ is representable by a commutative Hopf algebra $\Lambda$, and so has a left adjoint. The underlying ring of $\Lambda$ is $\mathbb{Z}[\lambda^1,\lambda^2, \ldots ]$, the free special $\lambda$-ring on one generator ($\lambda^1$). In the terminology of [[bimodel|bimodels]] $\Phi = \Lambda\Rightarrow?$ and its left adjoint is $\Lambda\otimes?$. So the theory of special $\lambda$-rings is a monadic extension of the theory of rings. [[!redirects SpecialLambdaRing]] [[!redirects special lambda-rings]] [[!redirects special ∞-ring]] [[!redirects special ∞-rings]] \end{document}