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Is it true that two planes may intersect in a point ?

or

If they intersect then, they always make a straight line ?

I have some doubt; please explain.

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In $\Bbb R^3$ two distinct planes either intersect in a line or are parallel, in which case they have empty intersection; they cannot intersect in a single point. In $\Bbb R^n$ for $n>3$, however, two planes can intersect in a point. In $\Bbb R^4$, for instance, let $P_1=\big\{\langle x,y,0,0\rangle:x,y\in\Bbb R\big\}$ and $P_2=\big\{\langle 0,0,x,y\rangle:x,y\in\Bbb R\big\}\;;$ $P_1$ and $P_2$ are $2$-dimensional subspaces of $\Bbb R^4$, so they are planes, and their intersection $P_1\cap P_2=\big\{\langle 0,0,0,0\rangle\big\}$ consists of a single point, the origin in $\Bbb R^4$. Similar examples can easily be constructed in any $\Bbb R^n$ with $n>3$.

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    I might be wrong (have no rigorous proof of what follows), but a curious example that comes to mind would be the (fourth-dimensional) "graph" of the complex identity function **w = f(z) = z**. It seems plausible that the "graph" should be a plane (it has to be a 2D surface immersed in 4D, and I see no reason why it would have any curvature). It is also evident that it should meet the "x axis" (i.e., z-plane, **w = 0**) of this function at **z = 0** only.2015-12-21