Lie group structure on the complex projective space
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There is a famous theorem about when $S^n$ has the structure of a Lie group. What about the complex projective space $mathbb CP^n$? For example, why $mathbb CP^2$ is not a Lie group (without using classification for low dimension compact Lie groups)?
algebraic-topology lie-groups projective-space
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There is a famous theorem about when $S^n$ has the structure of a Lie group. What about the complex projective space $mathbb CP^n$? For example, why $mathbb CP^2$ is not a Lie group (without using classification for low dimension compact Lie groups)?
algebraic-topology lie-groups projective-space
It is an amusing observation that a polynomial $f$ over $Bbb C$ that does not split into linear factors gives a non-trivial finite field extension $F/Bbb C$, and $Bbb P(F) = Bbb CP^{dim F - 1}$ is then a commutative positive-dimensional Lie group, and so the proofs below give as a corollary the fundamental theorem of algebra.
– Mike Miller
14 mins ago
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There is a famous theorem about when $S^n$ has the structure of a Lie group. What about the complex projective space $mathbb CP^n$? For example, why $mathbb CP^2$ is not a Lie group (without using classification for low dimension compact Lie groups)?
algebraic-topology lie-groups projective-space
There is a famous theorem about when $S^n$ has the structure of a Lie group. What about the complex projective space $mathbb CP^n$? For example, why $mathbb CP^2$ is not a Lie group (without using classification for low dimension compact Lie groups)?
algebraic-topology lie-groups projective-space
algebraic-topology lie-groups projective-space
edited 13 mins ago
Eric Wofsey
177k12202328
177k12202328
asked 40 mins ago
zzy
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It is an amusing observation that a polynomial $f$ over $Bbb C$ that does not split into linear factors gives a non-trivial finite field extension $F/Bbb C$, and $Bbb P(F) = Bbb CP^{dim F - 1}$ is then a commutative positive-dimensional Lie group, and so the proofs below give as a corollary the fundamental theorem of algebra.
– Mike Miller
14 mins ago
add a comment |
It is an amusing observation that a polynomial $f$ over $Bbb C$ that does not split into linear factors gives a non-trivial finite field extension $F/Bbb C$, and $Bbb P(F) = Bbb CP^{dim F - 1}$ is then a commutative positive-dimensional Lie group, and so the proofs below give as a corollary the fundamental theorem of algebra.
– Mike Miller
14 mins ago
It is an amusing observation that a polynomial $f$ over $Bbb C$ that does not split into linear factors gives a non-trivial finite field extension $F/Bbb C$, and $Bbb P(F) = Bbb CP^{dim F - 1}$ is then a commutative positive-dimensional Lie group, and so the proofs below give as a corollary the fundamental theorem of algebra.
– Mike Miller
14 mins ago
It is an amusing observation that a polynomial $f$ over $Bbb C$ that does not split into linear factors gives a non-trivial finite field extension $F/Bbb C$, and $Bbb P(F) = Bbb CP^{dim F - 1}$ is then a commutative positive-dimensional Lie group, and so the proofs below give as a corollary the fundamental theorem of algebra.
– Mike Miller
14 mins ago
add a comment |
3 Answers
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$mathbb{CP}^n$ has Euler characteristic $n+1$, but a compact (positive-dimensional) Lie group has Euler characteristic $0$, for example by the Lefschetz fixed point theorem.
Alternatively, you can show in various ways that the rational cohomology ring of a compact Lie group must be an exterior algebra on a finite number of odd generators. But $H^{bullet}(mathbb{CP}^n, mathbb{Q})$ is concentrated in even degrees, so doesn't admit odd generators.
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1
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$pi_2(mathbb{C}P^n)$ is $mathbb{Z}$ and $pi_2(G)$ is trivial where $G$ is a connected Lie group.
https://en.wikipedia.org/wiki/Complex_projective_space#Homotopy_groups
https://mathoverflow.net/questions/8957/homotopy-groups-of-lie-groups
add a comment |
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0
down vote
A complex projective space (of positive dimension) never admits a Lie group structure. There are lots of ways to prove this. For instance, the rational cohomology ring of any Lie group is a graded Hopf algebra (the comultiplication coming from the group operation) but the cohomology ring $mathbb{Q}[x]/(x^n)$ of $mathbb{CP}^n$ does not admit a Hopf algebra structure. Indeed, for reasons of degree, $Delta(x)$ would have to be $xotimes 1+1otimes x$ but then $Delta(x^n)=Delta(x)^n=sum_{k=0}^n binom{n}{k} x^kotimes x^{n-k}$ would be nonzero (all the terms except $k=0$ and $k=n$ are nonzero), which is a contradiction.
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3 Answers
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active
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votes
3 Answers
3
active
oldest
votes
active
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active
oldest
votes
up vote
2
down vote
$mathbb{CP}^n$ has Euler characteristic $n+1$, but a compact (positive-dimensional) Lie group has Euler characteristic $0$, for example by the Lefschetz fixed point theorem.
Alternatively, you can show in various ways that the rational cohomology ring of a compact Lie group must be an exterior algebra on a finite number of odd generators. But $H^{bullet}(mathbb{CP}^n, mathbb{Q})$ is concentrated in even degrees, so doesn't admit odd generators.
add a comment |
up vote
2
down vote
$mathbb{CP}^n$ has Euler characteristic $n+1$, but a compact (positive-dimensional) Lie group has Euler characteristic $0$, for example by the Lefschetz fixed point theorem.
Alternatively, you can show in various ways that the rational cohomology ring of a compact Lie group must be an exterior algebra on a finite number of odd generators. But $H^{bullet}(mathbb{CP}^n, mathbb{Q})$ is concentrated in even degrees, so doesn't admit odd generators.
add a comment |
up vote
2
down vote
up vote
2
down vote
$mathbb{CP}^n$ has Euler characteristic $n+1$, but a compact (positive-dimensional) Lie group has Euler characteristic $0$, for example by the Lefschetz fixed point theorem.
Alternatively, you can show in various ways that the rational cohomology ring of a compact Lie group must be an exterior algebra on a finite number of odd generators. But $H^{bullet}(mathbb{CP}^n, mathbb{Q})$ is concentrated in even degrees, so doesn't admit odd generators.
$mathbb{CP}^n$ has Euler characteristic $n+1$, but a compact (positive-dimensional) Lie group has Euler characteristic $0$, for example by the Lefschetz fixed point theorem.
Alternatively, you can show in various ways that the rational cohomology ring of a compact Lie group must be an exterior algebra on a finite number of odd generators. But $H^{bullet}(mathbb{CP}^n, mathbb{Q})$ is concentrated in even degrees, so doesn't admit odd generators.
answered 19 mins ago
Qiaochu Yuan
276k32579917
276k32579917
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add a comment |
up vote
1
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$pi_2(mathbb{C}P^n)$ is $mathbb{Z}$ and $pi_2(G)$ is trivial where $G$ is a connected Lie group.
https://en.wikipedia.org/wiki/Complex_projective_space#Homotopy_groups
https://mathoverflow.net/questions/8957/homotopy-groups-of-lie-groups
add a comment |
up vote
1
down vote
$pi_2(mathbb{C}P^n)$ is $mathbb{Z}$ and $pi_2(G)$ is trivial where $G$ is a connected Lie group.
https://en.wikipedia.org/wiki/Complex_projective_space#Homotopy_groups
https://mathoverflow.net/questions/8957/homotopy-groups-of-lie-groups
add a comment |
up vote
1
down vote
up vote
1
down vote
$pi_2(mathbb{C}P^n)$ is $mathbb{Z}$ and $pi_2(G)$ is trivial where $G$ is a connected Lie group.
https://en.wikipedia.org/wiki/Complex_projective_space#Homotopy_groups
https://mathoverflow.net/questions/8957/homotopy-groups-of-lie-groups
$pi_2(mathbb{C}P^n)$ is $mathbb{Z}$ and $pi_2(G)$ is trivial where $G$ is a connected Lie group.
https://en.wikipedia.org/wiki/Complex_projective_space#Homotopy_groups
https://mathoverflow.net/questions/8957/homotopy-groups-of-lie-groups
answered 18 mins ago
Tsemo Aristide
55.2k11444
55.2k11444
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0
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A complex projective space (of positive dimension) never admits a Lie group structure. There are lots of ways to prove this. For instance, the rational cohomology ring of any Lie group is a graded Hopf algebra (the comultiplication coming from the group operation) but the cohomology ring $mathbb{Q}[x]/(x^n)$ of $mathbb{CP}^n$ does not admit a Hopf algebra structure. Indeed, for reasons of degree, $Delta(x)$ would have to be $xotimes 1+1otimes x$ but then $Delta(x^n)=Delta(x)^n=sum_{k=0}^n binom{n}{k} x^kotimes x^{n-k}$ would be nonzero (all the terms except $k=0$ and $k=n$ are nonzero), which is a contradiction.
add a comment |
up vote
0
down vote
A complex projective space (of positive dimension) never admits a Lie group structure. There are lots of ways to prove this. For instance, the rational cohomology ring of any Lie group is a graded Hopf algebra (the comultiplication coming from the group operation) but the cohomology ring $mathbb{Q}[x]/(x^n)$ of $mathbb{CP}^n$ does not admit a Hopf algebra structure. Indeed, for reasons of degree, $Delta(x)$ would have to be $xotimes 1+1otimes x$ but then $Delta(x^n)=Delta(x)^n=sum_{k=0}^n binom{n}{k} x^kotimes x^{n-k}$ would be nonzero (all the terms except $k=0$ and $k=n$ are nonzero), which is a contradiction.
add a comment |
up vote
0
down vote
up vote
0
down vote
A complex projective space (of positive dimension) never admits a Lie group structure. There are lots of ways to prove this. For instance, the rational cohomology ring of any Lie group is a graded Hopf algebra (the comultiplication coming from the group operation) but the cohomology ring $mathbb{Q}[x]/(x^n)$ of $mathbb{CP}^n$ does not admit a Hopf algebra structure. Indeed, for reasons of degree, $Delta(x)$ would have to be $xotimes 1+1otimes x$ but then $Delta(x^n)=Delta(x)^n=sum_{k=0}^n binom{n}{k} x^kotimes x^{n-k}$ would be nonzero (all the terms except $k=0$ and $k=n$ are nonzero), which is a contradiction.
A complex projective space (of positive dimension) never admits a Lie group structure. There are lots of ways to prove this. For instance, the rational cohomology ring of any Lie group is a graded Hopf algebra (the comultiplication coming from the group operation) but the cohomology ring $mathbb{Q}[x]/(x^n)$ of $mathbb{CP}^n$ does not admit a Hopf algebra structure. Indeed, for reasons of degree, $Delta(x)$ would have to be $xotimes 1+1otimes x$ but then $Delta(x^n)=Delta(x)^n=sum_{k=0}^n binom{n}{k} x^kotimes x^{n-k}$ would be nonzero (all the terms except $k=0$ and $k=n$ are nonzero), which is a contradiction.
answered 15 mins ago
Eric Wofsey
177k12202328
177k12202328
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It is an amusing observation that a polynomial $f$ over $Bbb C$ that does not split into linear factors gives a non-trivial finite field extension $F/Bbb C$, and $Bbb P(F) = Bbb CP^{dim F - 1}$ is then a commutative positive-dimensional Lie group, and so the proofs below give as a corollary the fundamental theorem of algebra.
– Mike Miller
14 mins ago