Notational convention: In this post only, I will colour a statement red if it depends on the axiom of choice. 
The famous Banach-Tarski paradox asserts that one can take the unit ball in three dimensions, divide it up into finitely many pieces, and then translate and rotate each piece so that their union is now two disjoint unit balls. As a consequence of this paradox, it is not possible to create a finitely additive measure on 
that is both translation and rotation invariant, which can measure every subset of , and which gives the unit ball a non-zero measure. This paradox helps explain why Lebesgue measure (which is countably additive and both translation and rotation invariant, and gives the unit ball a non-zero measure) cannot measure every set, instead being restricted to measuring sets that are Lebesgue measurable.
On the other hand, it is not possible to replicate the Banach-Tarski paradox in one or two dimensions; the unit interval in 
or unit disk in 
cannot be rearranged into two unit intervals or two unit disks using only finitely many pieces, translations, and rotations, and indeed there do exist non-trivial finitely additive measures on these spaces. However, it is possible to obtain a Banach-Tarski type paradox in one or two dimensions using countably many such pieces; this rules out the possibility of extending Lebesgue measure to a countably additive translation invariant measure on all subsets of (or any higher-dimensional space).
In these notes I would like to establish all of the above results, and tie them in with some important concepts and tools in modern group theory, most notably amenability and the ping-pong lemma. This material is not required for the rest of the course, but nevertheless has some independent interest.
– One-dimensional equidecomposability –
Before we study the three-dimensional situation, let us first review the simpler one-dimensional situation. To avoid having to say “X can be cut up into finitely many pieces, which can then be moved around to create Y” all the time, let us make a convenient definition:
Definition 1. (Equidecomposability) Let &bg=ffffff&fg=545454&s=0 "G = (G,\cdot)")
be a group acting on a space X, and let A, B be subsets of X.
- We say that A, B are finitely G-equidecomposable if there exist finite partitions
and 
and group elements 
such that 
for all 
.
- We say that A, B are countably G-equidecomposable if there exist countable partitions
and 
and group elements 
such that for all i.
- We say that A is finitely G-paradoxical if it can be partitioned into two subsets, each of which is finitely G-equidecomposable with A.
- We say that A is countably G-paradoxical if it can be partitioned into two subsets, each of which is countably G-equidecomposable with A.
One can of course make similar definitions when &bg=ffffff&fg=545454&s=0 "G = (G,+)")
is an additive group rather than a multiplicative one.
Clearly, finite G-equidecomposability implies countable G-equidecomposability, but the converse is not true. Observe that any finitely (resp. countably) additive and G-invariant measure on X that measures every single subset of X, must give either a zero measure or an infinite measure to a finitely (resp. countably) G-paradoxical set. Thus, paradoxical sets provide significant obstructions to constructing additive measures that can measure all sets.
Example 1. If acts on itself by translation, then ![{}[0,2]](http://l.wordpress.com/latex.php?latex=%7B%7D%5B0,2%5D&bg=ffffff&fg=545454&s=0 "{}[0,2]")
is finitely -equidecomposable with ![{}[10,11) \cup [21,22]](http://l.wordpress.com/latex.php?latex=%7B%7D%5B10,11)+%5Ccup+%5B21,22%5D&bg=ffffff&fg=545454&s=0 "{}[10,11) \cup [21,22]")
, and 
is finitely -equidecomposable with ![(-\infty,-10] \cup (10,+\infty)](http://l.wordpress.com/latex.php?latex=(-%5Cinfty,-10%5D+%5Ccup+(10,+%5Cinfty)&bg=ffffff&fg=545454&s=0 "(-\infty,-10] \cup (10,+\infty)")
.
Example 2. If G acts transitively on X, then any two finite subsets of X are finitely 
-equidecomposable iff they have the same cardinality, and any two countably infinite sets of X are countably -equidecomposable. In particular, any countably infinite subset of X is countably G-paradoxical.
Exercise 1. Show that finite G-equidecomposability and countable G-equidecomposability are both equivalence relations.
Exercise 2. (Banach-Schroder-Bernstein theorem) Let G act on X, and let A, B be subsets of X.
- If A is finitely G-equidecomposable with a subset of B, and B is finitely G-equidecomposable with a subset of A, show that A and B are finitely G-equidecomposable with each other. (Hint: adapt the proof of the Schroder-Bernstein theorem.)
- If A is finitely G-equidecomposable with a superset of B, and B is finitely G-equidecomposable with a superset of A, show that A and B are finitely G-equidecomposable with each other. (Hint: use part 1.)
- Show that claims 1 and 2 hold when “finitely” is replaced by “countably”.
Exercise 3. Show that if G acts on X, A is a subset of X which is finitely (resp. countably) G-paradoxical, and 
, then the recurrence set 
is also finitely (resp. countably) G-paradoxical (where G acts on itself by translation).
Let us first establish countable equidecomposability paradoxes in the reals.
Proposition 1. Let act on itself by translations. Then ![{}[0,1]](http://l.wordpress.com/latex.php?latex=%7B%7D%5B0,1%5D&bg=ffffff&fg=545454&s=0 "{}[0,1]")
and are countably -equidecomposable.
Proof. By Exercise 2, it will suffice to show that some set contained in is countably -equidecomposable with . Consider the space 
of all cosets 
of the rationals. By the axiom of choice, we can express each such coset as for some ![x \in [0,1/2]](http://l.wordpress.com/latex.php?latex=x+%5Cin+%5B0,1/2%5D&bg=ffffff&fg=545454&s=0 "x \in [0,1/2]")
, thus we can partition 
for some ![E \subset [0,1/2]](http://l.wordpress.com/latex.php?latex=E+%5Csubset+%5B0,1/2%5D&bg=ffffff&fg=545454&s=0 "E \subset [0,1/2]")
. By Example 2, ![{\Bbb Q} \cap [0,1/2]](http://l.wordpress.com/latex.php?latex=%7B%5CBbb+Q%7D+%5Ccap+%5B0,1/2%5D&bg=ffffff&fg=545454&s=0 "{\Bbb Q} \cap [0,1/2]")
is countably 
-equidecomposable with , which implies that ![\bigcup_{x \in E} x + ({\Bbb Q} \cap [0,1/2])](http://l.wordpress.com/latex.php?latex=%5Cbigcup_%7Bx+%5Cin+E%7D+x+++(%7B%5CBbb+Q%7D+%5Ccap+%5B0,1/2%5D)&bg=ffffff&fg=545454&s=0 "\bigcup_{x \in E} x + ({\Bbb Q} \cap [0,1/2])")
is countably -equidecomposable with 
. Since latter set is and the former set is contained in [0,1], the claim follows. 
Of course, the same proposition holds if [0,1] is replaced by any other interval. As a quick consequence of this proposition and Exercise 2, we see that any subset of containing an interval is -equidecomposable with . In particular, we have
Corollary 1. Any subset of containing an interval is countably -paradoxical.
In particular, we see that any countably additive translation-invariant measure that measures every subset of , must assign a zero or infinite measure to any set containing an interval. In particular, it is not possible to extend Lebesgue measure to measure all subsets of .
We now turn from countably paradoxical sets to finitely paradoxical sets. Here, the situation is quite different: we can rule out many sets from being finitely paradoxical. The simplest example is that of a finite set:
Proposition 2. If G acts on X, and A is a non-empty finite subset of X, then A is not finitely (or countably) G-paradoxical.
Proof. One easily sees that any two sets that are finitely or countably G-equidecomposable must have the same cardinality. The claim follows.
Now we consider the integers.
Proposition 3. Let the integers 
act on themselves by translation. Then is not finitely -paradoxical.
Proof. The integers are of course infinite, and so Proposition 2 does not apply directly. However, the key point is that the integers can be efficiently truncated to be finite, and so we will be able to adapt the Proposition 2 argument in our case.
Let’s see how. Suppose for contradiction that we could partition into two sets A and B, which are in turn partitioned into finitely many pieces and 
, such that can be partitioned as 
and 
for some integers 
.
Now let N be a large integer (much larger than 
). We truncate to the interval ![{}[-N,N] := \{-N,\ldots,N\}](http://l.wordpress.com/latex.php?latex=%7B%7D%5B-N,N%5D+:=+%5C%7B-N,%5Cldots,N%5C%7D&bg=ffffff&fg=545454&s=0 "{}[-N,N] := \{-N,\ldots,N\}")
. Clearly
![A \cap [-N,N] = \bigcup_{i=1}^n A_i \cap [-N,N]](http://l.wordpress.com/latex.php?latex=A+%5Ccap+%5B-N,N%5D+=+%5Cbigcup_%7Bi=1%7D%5En+A_i+%5Ccap+%5B-N,N%5D&bg=ffffff&fg=545454&s=0 "A \cap [-N,N] = \bigcup_{i=1}^n A_i \cap [-N,N]")
. (1)
and
![{}[-N,N] = \bigcup_{i=1}^n (A_i + a_i) \cap [-N,N]](http://l.wordpress.com/latex.php?latex=%7B%7D%5B-N,N%5D+=+%5Cbigcup_%7Bi=1%7D%5En+(A_i+++a_i)+%5Ccap+%5B-N,N%5D&bg=ffffff&fg=545454&s=0 "{}[-N,N] = \bigcup_{i=1}^n (A_i + a_i) \cap [-N,N]")
. (2)
From (2) we see that the set ![\bigcup_{i=1}^n (A_i \cap [-N,N]) + a_i](http://l.wordpress.com/latex.php?latex=%5Cbigcup_%7Bi=1%7D%5En+(A_i+%5Ccap+%5B-N,N%5D)+++a_i&bg=ffffff&fg=545454&s=0 "\bigcup_{i=1}^n (A_i \cap [-N,N]) + a_i")
differs from ![{}[-N,N]](http://l.wordpress.com/latex.php?latex=%7B%7D%5B-N,N%5D&bg=ffffff&fg=545454&s=0 "{}[-N,N]")
by only O(1) elements, where the bound in the O(1) expression can depend on 
but does not depend on N. (The point here is that [-N,N] is “almost” translation-invariant in some sense.) Comparing this with (1) we see that
![|[-N,N]| \leq |A \cap [-N,N]| + O(1)](http://l.wordpress.com/latex.php?latex=%7C%5B-N,N%5D%7C+%5Cleq+%7CA+%5Ccap+%5B-N,N%5D%7C+++O(1)&bg=ffffff&fg=545454&s=0 "|[-N,N]| \leq |A \cap [-N,N]| + O(1)")
. (3)
Similarly with A replaced by B. Summing, we obtain
![2 |[-N,N]| \leq |[-N,N]| + O(1)](http://l.wordpress.com/latex.php?latex=2+%7C%5B-N,N%5D%7C+%5Cleq+%7C%5B-N,N%5D%7C+++O(1)&bg=ffffff&fg=545454&s=0 "2 |[-N,N]| \leq |[-N,N]| + O(1)")
, (4)
but this is absurd for N sufficiently large, and the claim follows.
Exercise 4. Use the above argument to show that in fact no infinite subset of is finitely -paradoxical; combining this with Example 2, we see that the only finitely -paradoxical set of integers is the empty set.
The above argument can be generalised to an important class of groups:
Definition 2. (Amenability) Let be a discrete, at most countable, group. A Følner sequence is a sequence 
of finite subsets of G with 
with the property that 
for all 
, where 
denotes symmetric difference. A discrete, at most countable, group G is amenable if it contains at least one Følner sequence. Of course, one can define the same concept for additive groups .
Remark 1. One can define amenability for uncountable groups by replacing the notion of a Følner sequence with a Følner net. Similarly, one can define amenability for locally compact Hausdorff groups equipped with a Haar measure by using that measure in place of cardinality in the above definition. However, we will not need these more general notions of amenability here. The notion of amenability was first introduced (though not by this name, or by this definition) by von Neumann, precisely in order to study these sorts of decomposition paradoxes.
Example 3. The sequence for 
is a Følner sequence for the integers , which are hence an amenable group.
Exercise 5. Show that any abelian discrete group that is at most countable, is amenable.
Exercise 6. Show that any amenable discrete group G that is at most countable is not finitely G-paradoxical, when acting on itself. Combined with Exercise 3, we see that if such a group G acts on a non-empty space X, then X is not finitely G-paradoxical.
Remark 2. Exercise 6 suggests that an amenable group G hould be able to support a non-trivial finitely additive measure which is invariant under left-translations, and can measure all subsets of G. Indeed, one can even create a finitely additive probability measure, for instance by selecting a non-principal ultrafilter 
and a Følner sequence _%7Bn=1%7D%5E%5Cinfty&bg=ffffff&fg=545454&s=0 "(F_n)_{n=1}^\infty")
and defining +:=+%5Clim_%7Bn+%5Cto+p%7D+%7CA+%5Ccap+F_n%7C/%7CF_n%7C&bg=ffffff&fg=545454&s=0 "\mu(A) := \lim_{n \to p} |A \cap F_n|/|F_n|")
for all 
.
The reals &bg=ffffff&fg=545454&s=0 "{\Bbb R} = ({\Bbb R},+)")
(which we will give the discrete topology!) are uncountable, and thus not amenable by the narrow definition of Definition 2. However, observe from Exercise 5 that any finitely generated subgroup of the reals is amenable (or equivalently, that the reals themselves with the discrete topology are amenable, using the Følner net generalisation of Definition 2). Also, we have the following easy observation:
Exercise 7. Let G act on X, and let A be a subset of X which is finitely G-paradoxical. Show that there exists a finitely generated subgroup H of G such that A is finitely H-paradoxical.
From this, we see that is not finitely -paradoxical. But we can in fact say much more:
Proposition 4. Let A be a non-empty subset of . Then A is not finitely -paradoxical.
Proof. Suppose for contradiction that we can partition A into two sets 
which are both finitely -equidecomposable with A. This gives us two maps 
, 
which are piecewise given by a finite number of translations; thus there exists a finite set 
such that +%5Cin+x+++%5C%7Bg_1,%5Cldots,g_d%5C%7D&bg=ffffff&fg=545454&s=0 "f_i(x) \in x + \{g_1,\ldots,g_d\}")
for all 
and 
.
For any integer 
, consider the 
composition maps 
for 
. From the disjointness of 
and an easy induction we see that the ranges of all these maps are disjoint, and so for any the quantities &bg=ffffff&fg=545454&s=0 "f_{i_1} \circ \ldots \circ f_{i_N}(x)")
are distinct. On the other hand, we have
+%5Cin+x+++%5C%7Bg_1,%5Cldots,g_d%5C%7D+++%5Cldots+++%5C%7Bg_1,%5Cldots,g_d%5C%7D&bg=ffffff&fg=545454&s=0 "f_{i_1} \circ \ldots \circ f_{i_N}(x) \in x + \{g_1,\ldots,g_d\} + \ldots + \{g_1,\ldots,g_d\}")
. (5)
Simple combinatorics (relying primarily on the abelian nature of &bg=ffffff&fg=545454&s=0 "({\Bbb R},+)")
shows that the number of values on the RHS of (5) is at most 
. But for sufficiently large N, we have 
, giving the desired contradiction.
Let us call a group G supramenable if every non-empty subset of G is not finitely G-paradoxical; thus is supramenable. From Exercise 3 we see that if a supramenable group acts on any space X, then the only finitely G-paradoxical subset of X is the empty set.
Exercise 8. We say that a group has subexponential growth if for any finite subset S of G, we have 
, where 
is the set of n-fold products of elements of S. Show that every group of subexponential growth is supramenable.
Exercise 9. Show that every abelian group has subexponential growth (and is thus supramenable. More generally, show that every nilpotent group has subexponential growth and is thus also supramenable.
Exercise 10. Show that if two finite unions of intervals in are finitely -equidecomposable, then they must have the same length. (Hint: reduce to the case when both sets consist of a single interval. First show that the lengths of these intervals cannot differ by more than a factor of two, and then amplify this fact by iteration to conclude the result.)
Remark 3. We already saw that amenable groups G admit finitely additive translation-invariant probability measures that measure all subsets of G (Remark 2 can be extended to the uncountable case); in fact, this turns out to be an equivalent definition of amenability. It turns out that supramenable groups G enjoy a stronger property, namely that given any non-empty set A on G, there exists a finitely additive translation-invariant measure on G that assigns the measure 1 to A; this is basically a deep result of Tarski.
– Two-dimensional equidecomposability –
Now we turn to equidecomposability on the plane . The nature of equidecomposability depends on what group G of symmetries we wish to act on the plane.
Suppose first that we only allow ourselves to translate various sets in the planes, but not to rotate them; thus 
. As this group is abelian, it is supramenable by Exercise 9, and so any non-empty subset A of the plane will not be finitely -paradoxical sets; indeed, by Remark 3, there exists a finitely additive translation-invariant measure that gives A the measure 1. On the other hand, it is easy to adapt Corollary 1 to see that any subset of the plane containing a ball will be countably -paradoxical.
Now suppose we allow both translations and rotations, thus G is now the group +%5C;times+%7B%5CBbb+R%7D%5E2&bg=ffffff&fg=545454&s=0 "SO(2) \;times {\Bbb R}^2")
of (orientation-preserving) isometries 
for 
and 
, where 
denotes the anti-clockwise rotation by 
around the origin. This group is no longer abelian, or even nilpotent, so Exercise 9 no longer applies. Indeed, it turns out that G is no longer supramenable. This is a consequence of the following three lemmas:
Lemma 1. Let G be a group which contains a free semigroup on two generators (in other words, there exist group elements 
such that all the words involving g and h (but not 
or 
) are distinct). Then G contains a non-empty finitely G-paradoxical set. In other words, G is not supramenable.
Proof. Let S be the semigroup generated by g and h (i.e. the set of all words formed by g and h, including the empty word (i.e. group identity). Observe that gS and hS are disjoint subsets of S that are clearly G-equidecomposable with S. The claim then follows from Exercise 2.
Lemma 2. (Semigroup ping-pong lemma) Let G act on a space X, let g, h be elements of G, and suppose that there exists a non-empty subset A of X such that gA and hA are disjoint subsets of A. Then g, h generate a free semigroup.
Proof. As in the proof of Proposition 4, we see from induction that for two different words w, w’ generated by g, h, the sets wA and w’A are disjoint, and the claim follows.
Lemma 3. The group +%5Cltimes+%7B%5CBbb+R%7D%5E2&bg=ffffff&fg=545454&s=0 "G = SO(2) \ltimes {\Bbb R}^2")
contains a free semigroup on two generators.
Proof. It is convenient to identify with the complex plane 
. We set g to be the rotation 
for some transcendental phase 
be such that 
is transcendental (such a phase must exist, since the set of algebraic complex numbers is countable), and let 
be the translation 
. Observe that g and h act on the set A of polynomials in 
with non-negative integer coefficients, and that gA and hA are disjoint. The claim now follows from Lemma 2.
Combining Lemma 1 and Lemma 3 to create a countable, finitely paradoxical subset of +%5Cltimes+%7B%5CBbb+R%7D%5E2&bg=ffffff&fg=545454&s=0 "SO(2) \ltimes {\Bbb R}^2")
, and then letting that set act on a generic point in the plane (noting that each group element in has at most one fixed point), we obtain
Corollary 2. (Sierpinski-Mazurkiewicz paradox) There exist non-empty finitely -paradoxical subsets of the plane.
We have seen that the group of rigid motions is not supramenable. Nevertheless, it is still amenable, thanks to the following lemma:
Lemma 4. Suppose one has a short exact sequence 
of discrete, at most countable, groups, and suppose one has a choice function 
that inverts the projection of G to K (the existence of which is automatic, from the axiom of choice, or if G is finitely generated). If H and K are amenable, then so is G.
Proof. Let _%7Bn=1%7D%5E%5Cinfty&bg=ffffff&fg=545454&s=0 "(A_n)_{n=1}^\infty")
and _%7Bn=1%7D%5E%5Cinfty&bg=ffffff&fg=545454&s=0 "(B_n)_{n=1}^\infty")
be Følner sequences for H and K respectively. Let 
be a rapidly growing function, and let be the set +%5Ccdot+A_%7Bf(n)%7D&bg=ffffff&fg=545454&s=0 "F_n := \bigcup_{x \in B_n} \phi(x) \cdot A_{f(n)}")
. One easily verifies that this is a Følner sequence for G if f is sufficiently rapidly growing.
Exercise 11. Show that any finitely generated solvable group is amenable. More generally, show that any discrete, at most countable, solvable group is amenable.
Exercise 12. Show that any finitely generated subgroup of is amenable. (Hint: use the short exact sequence +%5Cltimes+%7B%5CBbb+R%7D%5E2+%5Cto+SO(2)+%5Cto+0&bg=ffffff&fg=545454&s=0 "0 \to {\Bbb R}^2 \to SO(2) \ltimes {\Bbb R}^2 \to SO(2) \to 0")
, which shows that is solvable (in fact it is metabelian)). Conclude that is not finitely -paradoxical.
Finally, we show a result of Banach.
Proposition 5. The unit disk D in is not finitely +%5Ctimes+%7B%5CBbb+R%7D%5E2&bg=ffffff&fg=545454&s=0 "SO(2) \times {\Bbb R}^2")
-paradoxical.
Proof. If the claim failed, then D would be finitely
for n at least 5.&bg=ffffff&fg=000000&s=0 "SL_2(\mathbb{R})")
, and they often give nice invariants of diagrams of elliptic curves. For example, the quotient of the upper half plane by the group +=+%5C%7B+%5Cbinom%7Bab%7D%7Bcd%7D+%7C+ad-bc+=+1,+c+%5Cin+2%5Cmathbb%7BZ%7D+%5C%7D&bg=ffffff&fg=000000&s=0 "\Gamma_0(2) = \{ \binom{ab}{cd} | ad-bc = 1, c \in 2\mathbb{Z} \}")
classifies ordered pairs &bg=ffffff&fg=000000&s=0 "(E_1, E_2)")
of elliptic curves, equipped with a 
-isogeny (aka double cover homomorphism) between them. The function /%5CDelta(2%5Ctau)&bg=ffffff&fg=000000&s=0 "\Delta(\tau)/\Delta(2\tau)")
is invariant under this group of transformations, and therefore gives an invariant for these pairs. The normalizer &bg=ffffff&fg=000000&s=0 "\Gamma_0^+(2)")
in 
, and the resulting quotient space classifies unordered pairs of curves related by dual &bg=ffffff&fg=000000&s=0 "SL_2(\mathbb{Z})")
, and in particular, translation by integers, so it has a Fourier expansion. The easiest way to compute the expansion is to use modular forms of higher weight: +=+E_4(%5Ctau)%5E3/%5CDelta(%5Ctau)&bg=ffffff&fg=000000&s=0 "j(\tau) = E_4(\tau)^3/\Delta(\tau)")
. Writing the Fourier series in terms of 
, we see that the numerator 
has all nonnegative coefficients, since it is the 
of the denominator also has nonnegative coefficients, since it is a shifted generating function for +=+q%5E%7B-1%7D+++744+++196884q+++21493760q%5E2+++864299970q%5E3+++%5Cdots&bg=ffffff&fg=000000&s=0 "j(\tau) = q^{-1} + 744 + 196884q + 21493760q^2 + 864299970q^3 + \dots")
therefore has all nonnegative coefficients, and one might ask if these coefficients count something interesting (other than some combination of buckets and lattices).
that coincides with the unique /%5CDelta(2%5Ctau)+++24&bg=ffffff&fg=000000&s=0 "q^{-1} + 276q - 2048q^2 + \dots = \Delta(\tau)/\Delta(2\tau) + 24")
, which is invariant under &bg=ffffff&fg=000000&s=0 "\Gamma_0(2)")
. After looking at all of the elements, Conway and Norton concluded that the series seemed to have some special properties in common:&bg=ffffff&fg=000000&s=0 "\Gamma_0(N)")
, for N a multiple of |g| such that N divides 12|g|.
. The centralizer of an element in conjugacy class 2A is isomorphic to 2.B, the nontrivial &bg=ffffff&fg=000000&s=0 "Z(g,h,\tau)")
are characters of a representation of some central extension of the centralizer of g in the monster.,+Z(g%5Ea+h%5Ec,g%5Eb+h%5Ed,%5Ctau)+%5Csim+Z(g,h,%5Cfrac%7Ba%5Ctau+b%7D%7Bc%5Ctau+d%7D)&bg=ffffff&fg=000000&s=0 "\binom{ab}{cd} \in SL_2(\mathbb{Z}), Z(g^a h^c,g^b h^d,\tau) \sim Z(g,h,\frac{a\tau+b}{c\tau+d})")
, i.e., they are constant multiples (the ambiguity was later revised to 24th roots of unity).+=+j(%5Ctau)-744&bg=ffffff&fg=000000&s=0 "Z(g,h,\tau) = j(\tau)-744")
if and only if g=h=1.
, but vertex operator algebras have multiplication given by )&bg=ffffff&fg=000000&s=0 "V \otimes V \to V((z))")
, so multiplication takes two sections of the special fiber and produces a section of the generic fiber in a bilinear way. We also demand that this multiplication is almost commutative and associative, in the sense that multiplying three sections of the special fiber in three different ways (namely (AB)C, B(AC), and A(BC)) yields the same section of the generic fiber of the small polydisc D x D (the condition is actually a bit stronger than that). There are other axioms that are harder to motivate, coming from an action of the Virasoro algebra (which produces formal coordinate changes on the generic point).
, and for vertex operator algebras, it is a map )&bg=ffffff&fg=000000&s=0 "V \otimes M \to M((z))")
(and they both need to satisfy some kind of compatibility with multiplication). Twisted module structures can occur here because the generic point (i.e., the punctured disc) is not simply connected. In particular, the connected finite (étale) covers of Spec C((z)) have the form Spec C((t)), where t^N = z. The twisted module structure itself is given by a map )&bg=ffffff&fg=000000&s=0 "V \otimes M \to M((z^{1/N}))")
, and it has to satisfy a compatibility with multiplication in V together with an additional monodromy condition. The form of this monodromy condition is a source of some debate, since g-twisted modules for some authors are the same as 
-twisted modules for others. If we take the Fourier expansion of 
, then the power series vm lies in 
.
%7Cz%7C+=+(-1/2)+%5Cbar%7Bz%7D/%7Cz%7C&bg=ffffff&fg=000000&s=0 "(\partial/\partial z)|z| = (-1/2) \bar{z}/|z|")
. The absolute value function wasn’t analytic, so its derivative with respect to 
wasn’t defined. And what were all these 
+dz&bg=ffffff&fg=000000&s=0 "(\partial \bar{z}/\partial z) dz")
.+=+(x%5E2-y%5E2)+++2xyi&bg=ffffff&fg=000000&s=0 "f(x+iy) = (x^2-y^2) + 2xyi")
. Then we can take its differential and get a differential form 
. When we evaluate 
, and at a point 
changes between 
, for real 
. For example, with +dx+++(-2+y+2xi)+dy&bg=ffffff&fg=000000&s=0 "df = (2x+2yi) dx + (-2 y+2xi) dy")
. Of course, +dx+++b(x,y)+dy&bg=ffffff&fg=000000&s=0 "a(x,y) dx + b(x,y) dy")
. However, some experience shows that it is better express one forms in terms of 
and 
are complex valued functions on 
, so 
. Supposing that I had consisidered 
. Then 
.+dz&bg=ffffff&fg=000000&s=0 "df=(df/dz) dz")
, where 
is the derivative you learned in your first complex analysis course. The function 
is a smooth, but not analytic function, then 
will be of the form 
. Neither 
nor 
will necessarily be analytic.
and 
for the coordinates on 
, the one-form 
isn’t +dx&bg=ffffff&fg=000000&s=0 "(\partial y/\partial x) dx")
.
are called &bg=ffffff&fg=000000&s=0 "(1,0)")
forms, while one-forms of the form 
are called &bg=ffffff&fg=000000&s=0 "(0,1)")
forms. More generally, if we are working with functions of 
complex variables, we will have &bg=ffffff&fg=000000&s=0 "(p,q)")
-forms, for 
. In coordinates, a 
. &bg=ffffff&fg=000000&s=0 "(p+q)")
-form 
such that+=+e%5E%7Bi+(p-q)+%5Ctheta%7D+%5Ceta(v_1,+v_2,+%5Cldots,+v_%7Bp+q%7D)&bg=ffffff&fg=000000&s=0 "\eta(e^{i \theta} v_1, e^{i \theta} v_2, \ldots, e^{i \theta} v_{p+q}) = e^{i (p-q) \theta} \eta(v_1, v_2, \ldots, v_{p+q})")
,
vectors 
, 
, …, 
. &bg=ffffff&fg=000000&s=0 "(p,0)")
-form is a sum of terms of the form a smooth function times 
. A holomorphic 
-form is a sum of terms of the form an analytic function times 
? By definition,+dz+++(%5Cpartial+f/%5Cpartial+%5Cbar%7Bz%7D)+d+%5Cbar%7Bz%7D&bg=ffffff&fg=000000&s=0 "df = (\partial f/\partial z) dz + (\partial f/\partial \bar{z}) d \bar{z}")
.
and 
denote complex-valued functions of +-+f(z))/h&bg=ffffff&fg=000000&s=0 "\partial f/\partial z = \lim_{h \to 0} (f(z+h) - f(z))/h")
. But, when 
