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Let $\mathbb{H}$ be the skew-field of quaternions. I'm aware of the

Theorem 1. A function $f:\mathbb{H}\to\mathbb{H}$ which is $\mathbb{H}$-differentiable on the left (i.e. the usual limit $h^{-1}\cdot (f(x+h)-f(x))$, for $h\to 0$, exists for every $x\in \mathbb{H}$) is a quaternionic affine function on the right (i.e. of the form $x\mapsto x\cdot \alpha + v$).

This means that there are no interesting smooth quaternionic funcions, hence no interesting "quaternionic-smooth manifolds" (which is not the same as the quaternionic-Kahler or hyperkahler structures you encounter in differential geometry and complex analytic geometry).

I think I can also recall the

Theorem 2. If a function $f:\mathbb{H}\to\mathbb{H}$ is locally $\mathbb{H}$-analytic (i.e. it can be locally developped in power series, for the suitable noncommutative notion of "power series"), than it corresponds to a real-analytic function $f:\mathbb{R}^4\to \mathbb{R}^4$, and any real-analytic funcion $f:\mathbb{R}^4\to \mathbb{R}^4$ can be obtained in this way.

That says that $\mathbb{H}$-analytic functions are essentially the same as quadruples of real-analytic functions of 4 variables. Hence there is no "quaternionic-analytic geometry" distinguishable from $4n$-dimentional real-analytic geometry. I think the same happens with quaternionic (noncommutative) polynomials: they're just 4-tuples of real polynomials in 4 variables.

But, is it reasonable that the zero locus on $\mathbb{H}^n$ of a "noncommutative polynomial" with $\mathbb{H}$-coefficients doesn't have any further mathematical structure than it's real-algebraic variety structure? It would be nice to be able to see things such as $\mathbb{HP}^1$ as a "quaternionic curve ", and to speak of a point " $\mathrm{Spec}(\mathbb{H})$ " (whatever it means) if it possible...

Is there a theory of "quaternionic algebraic geometry", maybe as a branch or particular case of some noncommutative (algebraic) geometry theory?

Of course, if such a theory has some sense, it cannot be the "obvious analog" of complex algebraic or analytic geometry, as theorems 1. and 2. above show.

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    $\begingroup$ I think that the way around Theorem 1 is what is usually termed "Clifford analysis". $\endgroup$ Commented Jan 13, 2011 at 14:59

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The answer is yes!(at least if quaternionic holomorphic geometry counts) "Quaternionic holomorphic geometry" provides a very elegant description of surfaces in 3- and 4-dimensional space.

The first paper in this field is more or less

Franz Pedit and Ulrich Pinkall, Quaternionic Analysis on Riemann Surfaces and Differential Geometry, in: Proocedings of the international con- gress of mathematicians, Berlin 1998, II Documenta Mathematica, Journal der Deutschen Mathematiker-Vereinigung, Extra Volume ICM 1998, 389-400. Click me

A good introduction to "Quaternionic holomorphic geometry" is given by

Francis E. Burstall, Dirk Ferus, Katrin Leschke, Franz Pedit and Ulrich Pinkall, Conformal geometry of surfaces in S4 and quaternions, Lecture Notes in Mathematics 1772, Springer-Verlag, Berlin, 2002. http://arxiv.org/abs/math/0002075

and

Dirk Ferus, Katrin Leschke, Franz Pedit and Ulrich Pinkall, Quaternionic Holomorphic Geometry: Plucker Formula, Dirac Eigenvalue Esitmates and Energy Estimates of Harmonic 2-Tori, Inventiones Mathematicae 146 (2001),no. 3, 507-593 arxiv.org/abs/math/0012238v1

But just to clarify things: "Of course, if such a theory has some sense, it cannot be the "obvious analog" of complex algebraic or analytic geometry, as theorems 1. and 2. above show."

This isn't really true, because the quaternionic holomorphic geometry developed in the papers above, is a kind of generalization of complex geometry, i.e. if you look how a "quaternionic holomorphic structure" is defined, you see that it is a kind of $\overline{\partial}$-Operator with some extra data (a so called Hopf field).

If you need more references, there are plenty available (just type "quaternionic holomorphic geometry" into google)

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    $\begingroup$ Is there a way, according to this theory, to say that $\mathbb{HP}^1$ is a curve ? $\endgroup$
    – Qfwfq
    Commented Jan 13, 2011 at 23:52
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I actually have no idea how this relates to the "quaternionic geometry" mentioned above, but there is also hyperkähler geometry. A hyperkähler manifold is a real manifold such that every tangent space has an action of the quaternions, and there is a single metric which makes the manifold Kähler in the complex structure induced by $I,J$, or $K$. This sounds a little differential geometric at first, but one can get a purely algebraic object by turning $J$ and $K$ into their respective symplectic forms $\omega_J$ and $\omega_K$. The sum $\omega_J+i\omega_K$ is a holomorphic symplectic form for the complex structure $I$, and many examples of these come from purely algebro-geometric sources. See, for example, the survey of Kaledin.

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  • $\begingroup$ Yea. I knew it should correspond to holomorphic symplectic manifolds (perhaps "irreducible"?) and there is a whole $\mathbb{P}^1$ of such complex structures.. But what I was looking for in my answer was a bit more "à la Grothendieck": i.e. some spaces "over $\mathbb{H}$" in some suitable sense. (holom sympl manif's are definitely "over $\mathbb{C}$") $\endgroup$
    – Qfwfq
    Commented Jan 13, 2011 at 23:18
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    – Qfwfq
    Commented Jan 13, 2011 at 23:21
  • $\begingroup$ Ah, sorry, didn't see "hyperkahler" mentioned in the question. Still, it's worth noting that "hyperkahler" doesn't have to only be a differential geometric notion. It can sneak back into algebraic geometry (even over finite fields!). $\endgroup$
    – Ben Webster
    Commented Jan 14, 2011 at 2:33
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You may perhaps be also interested in the quite recent paper

Gentili, Graziano; Stoppato, Caterina Zeros of regular functions and polynomials of a quaternionic variable. Michigan Math. J. 56 (2008), no. 3, 655–667

(and other papers by the same authors).

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Take a look at Dominic Joyce's paper "A theory of quaternionic algebra, with applications to hypercomplex geometry".

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It's true that two of the successful methods for defining a holomorphic function (the usual limits, and analytic power series) don't lead to very interesting quaternionic cases, as demonstrated by theorems 1 and 2 in the question. The first is too specific and the second too general.

This leaves a third option, which is to generalize the Cauchy-Riemann equations. Recall that a function is holomorphic if $$\frac{\partial f}{\partial x} + i \frac{\partial f}{\partial y} = 0$$ (and that for complex functions, this is equivalent to the other two conditions).

This approach does lead to an interesting extensions to quaternions, developed by Fueter in the 1930's, hence called the Cauchy-Riemann-Fueter equation: $$\frac{\partial f}{\partial q_0} + \frac{\partial f}{\partial q_1} i_1 + \frac{\partial f}{\partial q_2} i_2 + \frac{\partial f}{\partial q_3} i_3 = 0$$

The main starting reference I know of for this work is Quaternionic Analysis, Sudbery, 1979

There is more on this in Dominic Joyce's A theory of quaternionic algebra, with applications to hypercomplex geometry. There's also a simple introduction on page 14 of Quaternion Algebraic Geometry (my DPhil thesis from 2000), and a suggestion of applying to 3-dimensional space and spherical harmonics at the end of Quaternionic Algebra Described by Sp(1) Representations.

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In a more analytic direction there is also a recent theory of "split quaternionic analysis" developed by Igor Frenkel and Matvei Libine, starting here with a survey here, with applications to representation theory and physics.

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