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To give some background, I am mainly an analyst trained in harmonic/functional and do work on geometric pde's and spectral multipliers. Of late, I am trying to learn more about (research level) complex geometry. If I understand correctly, complex geometry means many things to many different people. To some, it is an extension of algebraic geometry, while many others would immediately think of the Newlander-Nirenberg or Yau's proof of Calabi conjecture.

I am looking for some kind of research ``introduction'' to the analytic side of complex geometry. I want to develop a better appreciation of the pde theoretic tools that are relevant in complex geometry, the problems they can solve, and also some of the open problems in the field that are thought to be potentially amenable to analytic methods of attack. In other words, suppose an analyst wants to do research on complex geometry. What does he start by reading? Papers sometime down the line for sure, but initially they might be too specific/concentrated. I guess, if there were a textbook on complex geometry written by Yau, or Hormander, or Tao, amongst other people, that would be a starting point for me.

If my question is too broad/unfit for this site, I apologize. I realize that it is impossible that any single book/monograph/lecture note will cover all the analytic sides of complex geometry. But even a partial answer will be appreciated.

Lastly, just for example: if someone asked me what would be a good answer if someone asked the same question about real differential geometry? I would say I don't have a good answer, as the literature is just too huge. However, I would add that some of my favourites are Schoen/Yau's Lectures on Differential Geometry, Jost's Geometric Analysis, and perhaps Aubin's Nonlinear problems in Riemannian geometry. These books should certainly get one started.

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    $\begingroup$ There is in fact a textbook by Hörmander, called An Introduction to Complex Analysis in Several Variables (North-Holland). It seems to answer pretty well your query. $\endgroup$
    – abx
    Commented Jul 19, 2014 at 4:29
  • $\begingroup$ best wishes from this complex geometry beginner.I think your background will help you lot $\endgroup$
    – Koushik
    Commented Jul 19, 2014 at 15:57

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1) There is a great book From Holomorphic Functions to Complex Manifolds by Fritzsche-Grauert.
It is very geometric and gives you the fundamentals on complex manifolds, including specialized topics, from Stein manifolds to compact Kähler manifolds, which in a sense are the two extremities in the spectrum of holomorphic geometry.
An important bonus is that Grauert was arguably the deepest complex analyst in the twentieth century.
It is very geometric but it will also warm your analyst's heart with sections on plurisubharmonic functions, Sobolev spaces and, Neumann operators,...

2) Another, even more analysis rich introduction, to complex geometry is Krantz's Function Theory of Several Complex Variables
There you will find harmonic analysis, regularity of $\bar \partial $ operator, $H^p$ functions and all sorts of integral representations.

3) Both books contain introductions to the indispensable tool of sheaves and their cohomology, which actually had their first applications in complex analysis, and were foreshadowed in Oka's groundbreaking solution to the Levi problem.
There are other good books, by Fuks, Griffiths, Hörmander (mentioned in abx's comment), Huybrechts, Ohsawa, Range, Wells,... but for me the most comprehensive introductions are 1) and 2).

4) Welcome to that enchanting land of complex geometry (full disclosure: that was where I started doing research!) and good luck!

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  • $\begingroup$ Thanks! Actually I was already aware of Hormander's Several Complex Variables book (there is also one by Rudin) and Folland-Stein's $\bar{\partial}$-Neumann analysis on Heisenberg groups paper. I was inclined to call these ``Complex Analysis/PDE'' rather than Complex Geometry, though I guess this depends on personal interpretation. Similarly, in my opinion, Griffiths-Harris or Huybrechts are on the other side, not exactly on the interface. The Fritzsche-Grauert book looks quite good though. Another resource I found is $\endgroup$
    – MBM
    Commented Jul 19, 2014 at 14:10
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    $\begingroup$ Jean-Pierre Demailly's notes at www-fourier.ujf-grenoble.fr/~demailly/manuscripts/… and the quite lengthy and detailed www-fourier.ujf-grenoble.fr/~demailly/manuscripts/agbook.pdf $\endgroup$
    – MBM
    Commented Jul 19, 2014 at 14:11
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    $\begingroup$ Dear @Koushik, I think you should express yourself a bit more modestly when you criticize a book by a world-renowned specialist like Krantz. You are perfectly entitled not to like the book but you should give valid mathematical arguments, and not rudely dismiss it as "not a good book" and "quite horrible" without the shadow of an explanation. $\endgroup$ Commented Jul 19, 2014 at 19:56

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