Difference between revisions of "Lieb-Thirring inequalities"

Inequalities concerning the negative eigenvalues of the Schrödinger operator (cf. also Schrödinger equation)

$$ \begin{equation*} H = - \Delta + V ( x ) \end{equation*} $$

on $L ^ { 2 } ( \mathbf{R} ^ { n } )$, $n \geq 1$. With $e _ { 1 } \leq e _ { 2 } \leq \ldots < 0$ denoting the negative eigenvalue(s) of $H$ (if any), the Lieb–Thirring inequalities state that for suitable $\gamma \geq 0$ and constants ,

$$ \begin{equation} \tag{a1} \sum _ { j \geq 1 } | e _ { j } | ^ { \gamma } \leq L _ { \gamma , n } \int _ { \mathbf{R} ^ { n } } V _ { - } ( x ) ^ { \gamma + n / 2 } d x \end{equation} $$

with $V _ { - } ( x ) : = \operatorname { max } \{ - V ( x ) , 0 \}$. When $\gamma = 0$, the left-hand side is just the number of negative eigenvalues. Such an inequality (a1) can hold if and only if $$ \begin{equation} \tag{a2} \left\{ \begin{array} { l l } { \gamma \geq \frac { 1 } { 2 } } & { \text { for } n= 1, } \\ { \gamma > 0 } & { \text { for }n = 2, } \\ { \gamma \geq 0 } & { \text { for } n\geq 3. } \end{array} \right. \end{equation} $$ The cases $\gamma > 1 / 2$, $n = 1$, $\gamma > 0$, $n \geq 2$, were established by E.H. Lieb and W.E. Thirring [a14] in connection with their proof of stability of matter. The case $\gamma = 1 / 2$, $n = 1$, was established by T. Weidl [a16]. The case $\gamma = 0$, $n \geq 3$, was established independently by M. Cwikel [a15], Lieb [a6] and G.V. Rosenbljum [a10] by different methods and is known as the CLR bound; the smallest known value (as of 1998) for $L _ { 0 , n }$ is in [a6], [a7]. Closely associated with the inequality (a1) is the semi-classical approximation for $\sum | e | ^ { \gamma }$, which serves as a heuristic motivation for (a1). It is (cf. [a14]): $$ \begin{equation*} \sum _ { j \geq 1 } | e | ^ { \gamma } \approx \end{equation*} $$

$$ \begin{equation*} \approx ( 2 \pi ) ^ { - n } \int _ { {\bf R} ^ { n } \times {\bf R} ^ { n } } [ p ^ { 2 } + V ( x ) ] _ { - } ^ { \gamma } d p d x = \end{equation*} $$

$$ \begin{equation*} = L _ { \gamma , n } ^ { c } \int _ { {\bf R} ^ { n } } V _ { - } ( x ) ^ { \gamma + n / 2 } d x, \end{equation*} $$

with $$ \begin{equation*} L _ { \gamma , n } ^ { c } = 2 ^ { - n } \pi ^ { - n / 2 } \frac { \Gamma ( \gamma + 1 ) } { \Gamma ( \gamma + 1 + n / 2 ) }. \end{equation*} $$ Indeed,

$L _ { \gamma , n } ^ { c } < \infty$

for all

$\gamma \geq 0$,

whereas

(a1)

holds only for the range given in

(a2).

It is easy to prove (by considering

$V ( x ) = \lambda W ( x )$

with

$W$

smooth and

$\lambda \rightarrow \infty$)

that

\begin{equation*} L _ { \gamma , n } \geq L _ { \gamma , n } ^ { c }. \end{equation*}

An interesting, and mostly open

(1998)

problem is to determine the sharp

value

of the constant

,

especially to find those cases in which

$L _ { \gamma , n } = L _ { \gamma , n } ^ { c }$.

M. Aizenman

and

Lieb

[a3]

proved that the ratio

is a monotonically non-increasing function of

$\gamma$.

Thus, if

$R _ { \Gamma , n } = 1$

for some

$\Gamma$,

then

$L _ { \gamma , n } = L _ { \gamma , n } ^ { c }$

for all

$\gamma \geq \Gamma$.

The equality

$L _ { \frac { 3 } { 2 } ,\, n } = L _ { \frac { 3 } { 2 } ,\, n } ^ { c }$

was proved for

$n = 1$

in

[a14]

and for

$n > 1$

in

[a2]

by

A. Laptev

and

Weidl.

(See also

[a1].)

The following sharp constants are known:

$L _ { \gamma , n } = L _ { \gamma , n } ^ { c }$,

all

$\gamma \geq 3 / 2$,

[a14],

[a3],

[a2];

$L _ { 1 / 2,1 } = 1 / 2$,

[a11].

There is strong support for the

conjecture

[a14]

that

\begin{equation} \tag{a3} L _ { \gamma , 1 } = \frac { 1 } { \sqrt { \pi } ( \gamma - \frac { 1 } { 2 } ) } \frac { \Gamma ( \gamma + 1 ) } { \Gamma ( \gamma + 1 / 2 ) } \left( \frac { \gamma - \frac { 1 } { 2 } } { \gamma + \frac { 1 } { 2 } } \right) ^ { \gamma + 1 / 2 } \end{equation}

for

$1 / 2 < \gamma < 3 / 2$.

Instead of considering all the negative eigenvalues as in

(a1),

one can consider just

$e_1$.

Then for

$\gamma$

as in

(a2),

\begin{equation*} | e _ { 1 } | ^ { \gamma } \leq L _ { \gamma , n } ^ { 1 } \int _ { \mathbf{R} ^ { n } } V _ { - } ( x ) ^ { \gamma + n / 2 } d x. \end{equation*}

Clearly,

$L _ { \gamma , n } ^ { 1 } \leq L _ { \gamma ,n }$,

but equality can hold, as in the cases

$\gamma = 1 / 2$

and

$3 / 2$

for

$n = 1$.

Indeed, the conjecture in

(a3)

amounts to

$L _ { \gamma , 1 } ^ { 1 } = L _ { \gamma , 1 }$

for

$1 / 2 < \gamma < 3 / 2$.

The sharp value

(a3)

of

$L _ { \gamma , n} ^ { 1 }$

is obtained by solving a differential equation

[a14].

It has been conjectured that for

$n \geq 3$,

$L _ { 0 ,\, n } = L _ { 0 ,\, n } ^ { 1 }$.

In any case,

B. Helffer

and

D. Robert

[a12]

showed that for all

$n$

and all

$\gamma < 1$,

$L _ { \gamma , n } > L _ { \gamma , n } ^ { c }$.

The sharp constant

$L _ { 0 , n } ^ { 1 }$,

$n \geq 3$,

is related to the sharp constant

$S _ { n }$

in the

Sobolev inequality

\begin{equation} \tag{a4} \| \nabla f \| _ {{ L } ^ 2 ( \mathbf{R} ^ { n } ) } \geq S _ { n } \| f \| _ { L ^{ 2 n / ( n - 2 ) } ( \mathbf{R} ^ { n } ) } \end{equation}

by

$L _ { 0 , n } ^ { 1 } = ( S _ { n } ) ^ { - n }$.

By a

"duality argument"

[a14],

the case

$\gamma = 1$

in

(a1)

can be converted into the following bound for the

Laplace operator,

$\Delta$.

This bound is

referred to as a

Lieb–Thirring kinetic energy inequality

and its most important application is to the

stability of matter

[a8],

[a14].

Let

$f _ { 1 } , f _ { 2 } , \ldots$

be

any

orthonormal sequence (finite or infinite, cf. also

Orthonormal system)

in

$L ^ { 2 } ( \mathbf{R} ^ { n } )$

such that

$\nabla f _ { j } \in L ^ { 2 } ( \mathbf{R} ^ { n } )$

for all

$j \geq 1$.

Associated with this sequence is a

"density"

\begin{equation} \tag{a5} \rho ( x ) = \sum _ { j \geq 1 } | f _ { j } ( x ) | ^ { 2 }. \end{equation}

Then, with

$K _ { n } : = n ( 2 / L _ { 1 , n } ) ^ { 2 / n } ( n + 2 ) ^ { - 1 - 2 / n }$,

\begin{equation} \tag{a6} \sum _ { j \geq 1 } \int _ { \mathbf{R} ^ { n } } | \nabla f _ { j } ( x ) | ^ { 2 } d x \geq K _ { n } \int _ { \mathbf{R} ^ { n } } \rho ( x ) ^ { 1 + 2 / n } d x. \end{equation}

This can be extended to

anti-symmetric functions

in

$L ^ { 2 } ( \mathbf{R} ^ { n N } )$.

If

$\Phi = \Phi ( x _ { 1 } , \dots , x _ { N } )$

is such a function, one defines, for

$x \in \mathbf{R} ^ { n }$,

\begin{equation*} \rho ( x ) = N \int _ { \mathbf{R} ^ { n ( N - 1 ) } } | \Phi ( x , x _ { 2 } , \ldots , x _ { N } ) | ^ { 2 } d x _ { 2 } \ldots d x _ { N }. \end{equation*}

Then, if

$\int _ { \mathbf{R} ^ { n N } } | \Phi | ^ { 2 } = 1$,

\begin{equation} \tag{a7} \int _ { R ^ { n N } } | \nabla \Phi | ^ { 2 } \geq K _ { n } \int _ { {\bf R} ^ { n } } \rho ( x ) ^ { 1 + 2 / n } d x. \end{equation}

Note that the choice

$\Phi = ( N ! ) ^ { - 1 / 2 } \operatorname { det } f _ { j } ( x _ { k } ) | _ { j , k = 1 } ^ { N }$

with

$f_j$

orthonormal reduces the general case

(a7)

to

(a6).

If the conjecture

$L _ { 1,3 } = L _ { 1,3 } ^ { c }$

is correct, then the bound in

(a7)

equals the

Thomas–Fermi kinetic energy Ansatz

(cf.

Thomas–Fermi theory),

and hence it is a challenge to prove this conjecture. In the meantime,

see

[a7],

[a5]

for the best available constants to date

(1998).

Of course,

$\int ( \nabla f ) ^ { 2 } = \int f ( - \Delta f )$.

Inequalities of the type

(a7)

can be found for other powers of

$- \Delta$

than the first power. The first example of this kind, due to

I. Daubechies

[a13],

and one of the most important physically, is to replace

$- \Delta$

by

$\sqrt { - \Delta }$

in

$H$.

Then an inequality similar to

(a1)

holds with

$\gamma + n / 2$

replaced by

$\gamma + n$

(and with a different

$L _ { \gamma , n _ { 1 }}$,

of course). Likewise there is an analogue of

(a7)

with

$1 + 2 / n$

replaced by

$1 + 1 / n$.

All proofs of

(a1)

(except

[a11]

and

[a16])

actually

proceed by finding an upper bound to

$N _ { E } ( V )$,

the number of eigenvalues of

$H = - \Delta + V ( x )$

that are below

$- E$.

Then, for

$\gamma > 0$,

\begin{equation*} \sum | e | ^ { \gamma } = \gamma \int _ { 0 } ^ { \infty } N _ { E } ( V ) E ^ { \gamma - 1 } d E. \end{equation*}

Assuming

$V = - V _ { - }$

(since

$V _ { + }$

only raises the eigenvalues),

$N _ { E } ( V )$

is most accessible via the positive semi-definite

Birman–Schwinger kernel

(cf.

[a4])

\begin{equation*} K _ { E } ( V ) = \sqrt { V _ { - } } ( - \Delta + E ) ^ { - 1 } \sqrt { V _ { - } }. \end{equation*}

$e < 0$

is an eigenvalue of

$H$

if and only if

$1$

is an eigenvalue of

$K _ { |e| } ( V )$.

Furthermore,

$K _ { E } ( V )$

is

operator

that is monotone decreasing in

$E$,

and hence

$N _ { E } ( V )$

equals the number of eigenvalues of

$K _ { E } ( V )$

that are greater than

$1$.

An important generalization of

(a1)

is to replace

$- \Delta$

in

$H$

by

$| i \nabla + A ( x ) | ^ { 2 }$,

where

$A ( x )$

is some arbitrary vector field in

${\bf R} ^ { n }$

(called a

magnetic vector potential).

Then

(a1)

still holds, but it is not known if the sharp value of

changes. What is known is that all

presently

(1998)

known values of

are unchanged. It is also known that

$( - \Delta + E ) ^ { - 1 }$,

as a kernel in

$\mathbf{R} ^ { n } \times \mathbf{R} ^ { n }$,

is pointwise greater than the absolute value of the kernel

$( | i \nabla + A | ^ { 2 } + E ) ^ { - 1 }$.

There is another family of inequalities for orthonormal functions,

which is closely related to

(a1)

and to the CLR

bound

[a9].

As before, let

$f _ { 1 } , \dots , f _ { N }$

be

$N$

orthonormal functions in

$L ^ { 2 } ( \mathbf{R} ^ { n } )$

and set

\begin{equation*} u _ { j } = ( - \Delta + m ^ { 2 } ) ^ { - 1 / 2 } f _ { j }, \end{equation*}

\begin{equation*} \rho ( x ) = \sum _ { j = 1 } ^ { N } | u _ { j } ( x ) | ^ { 2 }. \end{equation*}

$u _ { j }$

is a

Riesz potential

($m = 0$)

or a

Bessel potential

($m > 0$)

of

$f_j$.

If

$n = 1$

and

$m > 0$,

then

$\rho \in C ^ { 0,1 / 2 } ( \mathbf{R} ^ { n } )$

and

$\| \rho \| _ { L^\infty ( {\bf R} )} \leq L / m$.

If

$n = 2$

and

$m > 0$,

then for all

$1 \leq p < \infty$,

$\| \rho \| _ { L ^ { p } ( R ^ { 2 } ) } \leq B _ { p } m ^ { - 2 / p } N ^ { 1 / p }$.

If

$n \geq 3$,

$p = n / ( n - 2 )$

and

$m \geq 0$

(including

$m = 0$),

then

$\| \rho \| _ { L ^ { p } ( \mathbf{R} ^ { n } ) } \leq A _ { n } N ^ { 1 / p }$.

Here,

$L$,

$B _ { p }$,

$A _ { n }$

are universal constants. Without the orthogonality,

$N ^ { 1 / p }$

would have to be replaced by

$N$.

Further generalizations are

possible

[a9].

References

Elliott H. Lieb

Copyright to this article is held by Elliott Lieb.