Every
hyperkähler manifold is also hypercomplex. The converse is not true. The
Hopf surface :\bigg({\mathbb H}\backslash 0\bigg)/{\mathbb Z} (with {\mathbb Z} acting as a multiplication by a quaternion q, |q|>1) is hypercomplex, but not
Kähler, hence not
hyperkähler either. To see that the Hopf surface is not Kähler, notice that it is
diffeomorphic to a product S^1\times S^3, hence its odd cohomology group is odd-dimensional. By
Hodge decomposition, odd cohomology of a compact
Kähler manifold are always even-dimensional. In fact Hidekiyo Wakakuwa proved that on a compact
hyperkähler manifold \ b_{2p+1}\equiv 0 \ mod \ 4.
Misha Verbitsky has shown that any compact hypercomplex manifold admitting a Kähler structure is also hyperkähler. In 1988, left-invariant hypercomplex structures on some compact
Lie groups were constructed by the physicists Philippe Spindel, Alexander Sevrin, Walter Troost, and Antoine Van Proeyen. In 1992,
Dominic Joyce rediscovered this construction, and gave a complete classification of left-invariant hypercomplex structures on compact Lie groups. Here is the complete list. : T^4, SU(2l+1), T^1 \times SU(2l), T^l \times SO(2l+1), :T^{2l}\times SO(4l), T^l \times Sp(l), T^2 \times E_6, : T^7\times E^7, T^8\times E^8, T^4\times F_4, T^2\times G_2 where T^i denotes an i-dimensional compact torus. It is remarkable that any
compact Lie group becomes hypercomplex after it is multiplied by a sufficiently big torus. == Basic properties ==