5.2. SOBOLEV AND FINITE ENERGY FUNCTIONS 71by what was proved above and the choice of k. DWe turn now to a proof of the result in Example 5.1.4. Suppose that u has an
extension v in EMO(R^2 ), choose n > 5 so that
1 n-5
llvllBMO(R^2 ) < ~ 2 log n + 1'and let Bj = B(zj, 1) and Bo= B(n, n) where z 1 = 1 and z 2 = 2n - 1. Then
lvB; - VB 0 I ::; ~ (log:~~~~ + 1) llvllBMO(R2)
for j = 1, 2 by Lemma 5.1.5, whence
(5.1.6) luB 1 - uB 2 I = lvB 1 - VB 21 < n - 5.
Next if 'Y is a hyperbolic segment joining z 1 and z2 in D, then
1
length("f)
lu(zi) - u(z2)I = ho(z1, z2) = 'Y po(z) ds 2".
2
2". n-1by inequality (3.2.1) and
JuB 1 - uB 2 J 2". Ju(z1) - u(z2)J - Ju(z1) - UB 1 J - Ju(z2) - UB 2 l 2". n- 5
by (5.1.3), which contradicts (5.1.6).
The domain D in Example 5.1.4 is not a quasidisk by Example 1.4.5. On the
other hand, functions in EMO(D) have extensions to EMO(R^2 ) whenever D is a
disk or half-plane.
THEOREM 5.1.7 (Reimann-Rychener [147]). If Dis a disk or half-plane and if
u E EMO(D), then u has an extension v E EMO(R^2 ) with
llvllBMO(R2) ::; c JluiiBMO(D)where c 2". 1 is an absolute constant.
DEFINITION 5.1.8. A domain D is a EMO-extension domain if there exists a
constant c 2". 1 such that each u E EMO(D) has an extension v E EMO(R^2 ) with
JlvllBMO(R2) ::; c JluliBMO(D)'
This extension property then yields another characterization for the class of
quasi disks.
THEOREM 5.1.9 (Jones [94]). A simply connected domain D C R^2 is a K-
quasidisk if and only if it is a EMO-extension domain with constant c, where K
and c depend only on each other.
5.2. Sobolev and finite energy functions
We assume throughout this section that u is locally integrable and ACL ( abso-
lutely continuous on lines) in a domain D C R^2 ; see Definition 1.1.7. We say that
u has finite Dirichlet energy or is in Li(D) if
Eo(u) = l Jgrad uJ^2 dm < oo.
When do such functions u have an extension v in Li(R^2 )?