Scott's Pi

In mathematics, at the junction of singularity theory and differential topology, Cerf theory is the study of families of smooth real-valued functions

${\displaystyle f:M\to \mathbb{ℝ}}$

on a smooth manifold M, their generic singularities and the topology of the subspaces these singularities define, as subspaces of the function space.

An example

Marston Morse proved that, provided ${\displaystyle M}$ is compact, any smooth function

${\displaystyle f:M\to \mathbb{ℝ}}$

could be approximated by a Morse function. So for many purposes, one can replace arbitrary functions on ${\displaystyle M}$ by Morse functions.

As a next step, one could ask, 'if you have a 1-parameter family of functions which start and end at Morse functions, can you assume the whole family is Morse?' In general the answer is no. Consider, for example, the family:

${\displaystyle f_t(x)=(1/3)x^3-tx,}$

as a 1-parameter family of functions on ${\displaystyle M=\mathbb{ℝ}}$. At time

${\displaystyle t=-1}$

it has no critical points, but at time

${\displaystyle t=1}$

it is a Morse function with two critical points

${\displaystyle x=\pm 1.}$

Jean Cerf^[1] showed that a 1-parameter family of functions between two Morse functions could be approximated by one that is Morse at all but finitely many degenerate times. The degeneracies involve a birth/death transition of critical points, as in the above example when ${\displaystyle t=0}$ an index 0 and index 1 critical point are created (as ${\displaystyle t}$ increases).

A stratification of an infinite-dimensional space

Let's return to the general case that ${\displaystyle M}$ is a compact manifold. Let ${\displaystyle \mathrm{Morse}(M)}$ denote the space of Morse functions

${\displaystyle f:M\to \mathbb{ℝ}}$

and ${\displaystyle \mathrm{Func}(M)}$ the space of smooth functions

${\displaystyle f:M\to \mathbb{ℝ}.}$

Morse proved that

${\displaystyle \mathrm{Morse}(M)\subset \mathrm{Func}(M)}$

is an open and dense subset in the ${\displaystyle C^{\mathrm{\infty }}}$ topology.

For the purposes of intuition, here is an analogy. Think of the Morse functions as the top-dimensional open stratum in a stratification of ${\displaystyle \mathrm{Func}(M)}$ (we make no claim that such a stratification exists, but suppose one does). Notice that in stratified spaces, the co-dimension 0 open stratum is open and dense. For notational purposes, reverse the conventions for indexing the stratifications in a stratified space, and index the open strata not by their dimension, but by their co-dimension. This is convenient since ${\displaystyle \mathrm{Func}(M)}$ is infinite-dimensional if ${\displaystyle M}$ is not a finite set. By assumption, the open co-dimension 0 stratum of ${\displaystyle \mathrm{Func}(M)}$ is ${\displaystyle \mathrm{Morse}(M)}$, ie: ${\displaystyle \mathrm{Func}(M{)}^0=\mathrm{Morse}(M)}$. In a stratified space ${\displaystyle X}$, frequently ${\displaystyle X^0}$ is disconnected. The essential property of the co-dimension 1 stratum ${\displaystyle X^1}$ is that any path in ${\displaystyle X}$ which starts and ends in ${\displaystyle X^0}$ can be approximated by a path that intersects ${\displaystyle X^1}$ transversely in finitely many points, and does not intersect ${\displaystyle X^i}$ for any ${\displaystyle i>1}$.

Thus Cerf theory is the study of the positive co-dimensional strata of ${\displaystyle \mathrm{Func}(M)}$, i.e.: ${\displaystyle \mathrm{Func}(M{)}^i}$ for ${\displaystyle i>0}$. In the case of

${\displaystyle f_t(x)=x^3-tx,}$

only for ${\displaystyle t=0}$ is the function not Morse, and

${\displaystyle f_0(x)=x^3}$

has a cubic degenerate critical point corresponding to the birth/death transition.

A single time parameter, statement of theorem

The Morse Theorem asserts that if ${\displaystyle f:M\to \mathbb{ℝ}}$ is a Morse function, then near a critical point ${\displaystyle p}$ it is conjugate to a function ${\displaystyle g:{\mathbb{ℝ}}^n\to \mathbb{ℝ}}$ of the form

${\displaystyle g(x_1,x_2,\cdots ,x_n)=f(p)+{ϵ}_1{x}_1^2+{ϵ}_2{x}_2^2+\cdots +{ϵ}_n{x}_n^2}$

where ${\displaystyle {ϵ}_i\in \{\pm 1\}}$.

Cerf's 1-parameter theorem asserts the essential property of the co-dimension one stratum.

Precisely, if ${\displaystyle f_t:M\to \mathbb{ℝ}}$ is a 1-parameter family of smooth functions on ${\displaystyle M}$ with ${\displaystyle t\in [0,1]}$, and ${\displaystyle f_0,f_1}$ Morse, then there exists a smooth 1-parameter family ${\displaystyle F_t:M\to \mathbb{ℝ}}$ such that ${\displaystyle F_0=f_0,F_1=f_1}$, ${\displaystyle F}$ is uniformly close to ${\displaystyle f}$ in the ${\displaystyle C^k}$-topology on functions ${\displaystyle M\times [0,1]\to \mathbb{ℝ}}$. Moreover, ${\displaystyle F_t}$ is Morse at all but finitely many times. At a non-Morse time the function has only one degenerate critical point ${\displaystyle p}$, and near that point the family ${\displaystyle F_t}$ is conjugate to the family

${\displaystyle g_t(x_1,x_2,\cdots ,x_n)=f(p)+x_1^3+{ϵ}_{1}t{x}_1+{ϵ}_2{x}_2^2+\cdots +{ϵ}_n{x}_n^2}$

where ${\displaystyle {ϵ}_i\in \{\pm 1\},t\in [-1,1]}$. If ${\displaystyle {ϵ}_1=-1}$ this is a 1-parameter family of functions where two critical points are created (as ${\displaystyle t}$ increases), and for ${\displaystyle {ϵ}_1=1}$ it is a 1-parameter family of functions where two critical points are destroyed.

Origins

The PL-Schoenflies problem for ${\displaystyle S^2\subset {\mathbb{ℝ}}^3}$ was solved by Alexander in 1924. His proof was adapted to the smooth case by Morse and Baiada. The essential property was used by Cerf in order to prove that every orientation-preserving diffeomorphism of ${\displaystyle S^3}$ is isotopic to the identity,^[2] seen as a 1-parameter extension of the Schoenflies theorem for ${\displaystyle S^2\subset {\mathbb{ℝ}}^3}$. The corollary ${\displaystyle {\mathrm{\Gamma }}_4=0}$ at the time had wide implications in differential topology. The essential property was later used by Cerf to prove the pseudo-isotopy theorem^[3] for high-dimensional simply-connected manifolds. The proof is a 1-parameter extension of Smale's proof of the h-cobordism theorem (the rewriting of Smale's proof into the functional framework was done by Morse, also Milnor,^[4] and also by Cerf-Gramain-Morin ^[5] following a suggestion of Thom).

Cerf's proof is built on the work of Thom and Mather.^[6] A useful modern summary of Thom and Mather's work from the period is the book of Golubitsky and Guillemin.^[7]

Applications

Beside the above mentioned applications, Robion Kirby used Cerf Theory as a key step in justifying the Kirby calculus.

Generalization

A stratification of the complement of an infinite co-dimension subspace of the space of smooth maps ${\displaystyle \{f:M\to \mathbb{ℝ}\}}$ was eventually developed by Sergeraert.^[8]

During the seventies, the classification problem for pseudo-isotopies of non-simply connected manifolds was solved by Hatcher and Wagoner,^[9] discovering algebraic ${\displaystyle K_i}$-obstructions on ${\displaystyle {\pi }_{1}M}$ (${\displaystyle i=2}$) and ${\displaystyle {\pi }_{2}M}$ (${\displaystyle i=1}$) and by Igusa, discovering obstructions of a similar nature on ${\displaystyle {\pi }_{1}M}$ (${\displaystyle i=3}$).^[10]

References