AP07_2-3.vp


1 Scalar products and metric
operators
In classical mechanics, the system is described by its coor-

dinates in N-dimensional phase (configuration) space. The
unique trajectory is a solution of canonical Hamiltonian or
Euler-Lagrange equations and satisfies fixed initial condi-
tions. The observable quantities (energy, angular momentum,
…) of the systems are represented by a function on the phase
space.

The description of the system is completely different in
quantum theory. We are dealing with a infinite dimensional
Hilbert space in this case, which is a vector space complete
with respect to the norm induced by the associated scalar
product. The quantum mechanical system is represented by
a vector in the Hilbert space. The observables are represented
by the operator acting on the Hilbert space. By postulate,
the measurable quantities are associated with spectra of the
operators which are required to be real. For this reason,
only self-adjoint operators are considered to be physically
admissible.

The evolution equations of classical mechanics are re-
placed by the Schrödinger equation

i
t

H�
�

�
� ��

and the initial conditions are replaced by the requirement
that � lies in the domain of the Hamiltonian. The task of solv-
ing the evolution equations is more complicated in quantum
mechanics. From the mathematical point of view, we face a
second order differential equation of complex valued func-
tions. Additionally, the involved self-adjoint Hamiltonians
are mostly unbounded, which requires careful determination
of their domains.

The scalar product plays the key role in interpreting the
solutions of the Schrödinger equation. The quantity ( , )� �1 2
is proportional to the transition amplitude that the system in
state �1 will transform to the state described by the vector �2 .

When the system does not depend on time explicitly, the
measured quantities have to be independent with respect to
time translations. Particularly, the time evolution of the states
� �i it U t( ) ( ) ( )� 0 should not violate the transition amplitude.
In other words, there should hold

� � � �� � � �1 2 1 20 0 0 0( ), ( ) ( ) ( ), ( ) ( )� U t U t .
This implies that the time evolution operator has to be

unitary, i.e. U t U t†( ) ( ) � 1. The dagger denotes hermitian con-

jugation with respect to the scalar product (., .) , which is usu-
ally taken to be

( , ) *� � � �1 2 1 2� � dqN , (1)
where * is complex conjugation. The time evolution opera-
tors form a one-parameter group, U( )0 1� ,
U t t U t U t( , ) ( ) ( )1 2 1 2� .

The Hamiltonian of the system plays the role of the gener-
ator of time translations, we have U t iHt( ) exp( )� � . The rela-
tion is consistent with Stone’s theorem which establishes a cor-
respondence between self-adjoint operators and one-param-
eter groups of unitary operators.

A few years ago, we witnessed a boom in the study of
��-symmetric Hamiltonians [1–21]. These operators are spe-
cific by their ��-symmetry, i.e. [ , ]�� H � 0 , where � is space
reflection and � is time reversion. These can be covered by a
broad class of pseudo-hermitian operators which satisfy the
following operator equation

H H† � �� � 1

The operator � is required to be hermitian, invertible and
bounded. The standard self-adjointness is a special case of the
preceeding relation as long as � � 1.

It was observed that these operators possess a real spec-
trum in many cases. The natural question emerged whether
it would be possible to replace the standard requirement
of self-adjointness by the less restrictive requirement of
pseudo-hermiticity.

The answer showed to be affirmative as long as we are
dealing with operators having purely real spectra. At first
sight, we encounter a serious problem that the time evolution
generated by these Hamiltonians is non-unitary with respect
to the scalar product (1). This problem has been fixed by
the theorem which states [14]: for any pseudo-hermitian
operator with a purely real spectrum there exists a positive-
-definite operator � with respect to which the Hamiltonian is
pseudo-hermitian, i.e.

H H† ,� � �� � 0

The consistent unitary evolution generated by H is recov-
ered by redefining of the scalar product. Instead of (1), we fix
it in the following form

( , )� � � �1 2 2� �� � 1* dqN . (2)

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 71

Acta Polytechnica Vol. 47 No. 2–3/2007

Pseudo-Hermitian Operators in a
Description of Physical Systems

V. Jakubský

We present some basic features of pseudo-hermitian quantum mechanics and illustrate the use of pseudo-hermitian Hamiltonians in a
description of physical systems.

Keywords: pseudo-hermitian operators, Klein-Gordon and Proca equation, thermodynamics.



The Hamiltonian H is self-adjoint with respect to the new
scalar product and may consequently serve as a generator of
time translations.

So, we encounter a twofold problem in pseudo-hermitian
quantum mechanics.

First, one has to check the spectrum of the operator. When
it consists of real eigenvalues only, the existence of posi-
tive-definite metric operator � is guaranteed and its explicit
construction follows. The construction is non-trivial in most
cases and contains an additional subtlety: the resulting metric
operator is non-unique. For given Hamiltonian H, there exist
rather a class of admissible metric operators and associated
scalar products.

The mathematical framework does not provide any re-
striction to make the result of the construction unique. To
weaken the ambiguity, one employs additional, physically mo-
tivated requirements on the scalar product – metric operator.

In the following section, we will provide an example of
pseudo-hermitian systems which appear in relativistic quan-
tum mechanics. It illustrates the construction of a proper
positive-definite scalar-product and discusses consequent
restriction of its ambiguity by the additional physical require-
ment of relativistic invariance.

2 Pseudo-hermitian Hamiltonians in
relativistic quantum mechanics
Attempts to marry the special theory of relativity (STR)

and quantum mechanics gave rise to the well known equa-
tions of relativistic quantum mechanics. The theory built on
the Dirac equation provides a consistent description of rela-
tivistic spin one-half particles, at least in the presence of weak
external fields.

The theory based on Klein-Gordon and Proca equations
representing evolution equations for spin zero and spin one
particles has met serious problems with probabilistic inter-
pretation of their solutions. The associated scalar product
showed to be indefinite. The problem is closely related to the
fact that the equations are of the second order in the time
derivative.

Nowadays, the genuine fusion of STR and quantum
theory is represented by quantum field theory. However, rela-
tivistic quantum mechanics may serve as a powerful tool in
describing compound particles in the weak external fields
or may provide relativistic corrections to the non-relativistic
systems.

Recently, relativistic integer-spin systems have been recon-
sidered within the framework of pseudo-hermitian quantum
mechanics. The positive scalar product for both cases has
been constructed [15, 16]. The dynamics of the free spin-less
particle is governed by the well-kown Klein-Gordon equation

( )� �t p m
2 2 2 0� � � . (3)

The first derivative of the wave function in time can be
understood as a new physical degree of freedom. In this con-
text, we introduce the following denotation

i t� � �� . (4)
Together with this relation, eq. (3) turns to a couple of

mutually intertwined differential equations of functions � and
�. This system can be rewritten in terms of two-compo-

nental formalism into the compact form, which resembles the
Schrödinger equation

i i
m p

Ht t� �
�

�

�

�
� ��

�

	




�

�


 � �

�

	




�

�


�

	




�

�


 �

0 1
02 2

. (5)

It was shown a long time ago [22] that the relativistic evo-
lution equations can be unified formally in the framework of
2(2s � 1)-component formalism, where s denotes spin of the
particle. Spin-one half keeps its privileged position even in
this framework, as the associated Hamiltonian (Dirac Hamil-
tonian) is hermitian in contrast to the integer-spin systems.

The operator H ceases to be hermitian. Instead, it satisfies
the relation

H PHP P† ,� �
�

	




�

�



0 1
1 0

, (6)

which establishes its pseudo-hermiticity with respect to P.

The Hamiltonian has a purely real spectrum which
consists of the values � � � �� p m2 2 . Consequently, the

existence of the positive metric operator is guaranteed. Its
explicit form in momentum representation reads

� �
�( )

( ) ( ) ( ) ( )

( ) ( )
( )p

p p p p

p p
p�

� � �

� �
�

� � � �

� �
�

1
�

� 	 	 	 	

	 	
	 	�

�

	








�

�





( )p
�

. (7)

This contains positive but arbitrary functions 	�( )p which
represent the non-uniquness of the scalar product. To restrict
the ambiguity, we impose additional requirement of Lorentz
invariance of the scalar product

( , ) ( , )� � �� �� � ��1 2 1 2 , (8)

which in terms of infinitesimal transformations

� � �� �( ) , :1 0i M
 
 (9)

leads to

M M† .� �� (10)

M is a generator of the Poincare group in appropriate rep-
resentation. Instead of explicit computation, let us note that
the solution of the preceeding relation can be particularly
facilitated by the use of Shur‘s lemma [15, 16].

The additional, physically motivated constraint reduces
the ambiguity to a single parameter. Thus, we may write
the resulting scalar product of two solutions �i of the Klein-
-Gordon equation in the following form

� �( , ) ( , ) , � , �

, �

� � � � � �
�

�

�
�

1 2 1 2 1 2 1 2

1

1
2

1
� � �

�

	



�

�


�

� ��
m

i
m

� �� � � �2 1 2 1 1� � �� , , ( , ).
(11)

The system involving a free particle with spin-one can be
treated in a similar manner. The evolution equation

� �
�
 
F m A� �2 0, (12)

where F A A�
 � 
 
 �� �� � and A � are complex valued func-
tions – components of a four-potential, can be rewritten in
multi-component formalism as well. Introducing a 6-com-
ponential wave function �T TmA iE� ( , )

� �
we obtain (we define

F Ej j
0 � � for j � 1 2 3, , )

72 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 47 No. 2–3/2007



i
t

m
m

m
m m

�

�
� ��

� �

� �
�

�

�

	










�

�






�
0

0
2

grad div

grad div
H � (13)

which is pseudo-hermitian with respect to P. Its spectrum
is real, and the existence of the positive metric operator is
guaranteed again. After explicit construction of the metric
operator, we impose the requirement of relativistic invariance
of the scalar product. As a result, we obtain a one-parameter
family of the scalar product [16]. Its explicit form on the space
of solutions A A A jj j j

T� �( , ) , ,0 1 2
�

of the Proca equations is

� � � �( , ) , ,A A ia
m

A A A A A A

A

1 2 1 2 2
0

1 1
0

2

1

2
� � � � �

� �

� � � �

�

grad grad

grad gradA
m

I
p h
m

A A

A

1
0

3

2 2

3 2 2
0

1

2 2
,

� �

�
( )

,

�

�
�

�

�
�
�

�

�
�
�

�

�

�

� m
I

p h
m

A
�

�

�
,

� �
�

�

�
�
�

�

�
�
�

2 2

22

�

(14)

where � in ( , )�1 1 , .,. denotes standard scalar product and
�� �� � dp p p and �h is the helicity operator.

Formulas (11) and (14) set up the basis for direct computa-
tion of observable physical properties of the system of free
relativistic particles with spin zero and one.

3 Metric operator in thermodynamics
In the preceeding section, we considered a system which

involved a single particle described by the Hamiltonian H.
The scalar products played the crucial role in computing the
physical properties of these systems. The situation is different
when we are interested in the collective behavior of identical
systems. A statistical description of the ensemble of quantum
systems comes into play.

Let us assume that the system in equilibrium is described
by pseudo-hermitian Hamiltonian with a purely real spec-
trum. Then the state of the system is described by density ma-
trix �, which is the solution of the Bloch equation

��

��
�� �H (15)

with initial condition �( )0 1� . The parameter � equals inverse
temperature, i.e. � � 1 T. The density matrix fixes the proba-
bility that we find the system in a given state. It provides only
statistical information on the system in this sense.

The formal solution of the Bloch equation reads
�

�� �e H

and should be normalized to identity (Tr � = 1) to acquire the
desired statistical properties. The temperature dependent
normalization factor

Z Tr H� �exp[ ]�
is of crucial importance, as it allows direct computation of
thermodynamic quantities (entropy, inner and free ener-
gy, …) and subsequent derivation of the thermodynamic
properties (state equation) of the system. It is called a parti-
tion function.

It has been shown [20] that the partition function is not
dependent on the explicit form of the scalar product. This
implies that information on the thermodynamics of the sys-

tem can be gained without explicit knowledge of the scalar
product. This statistical approach may represent a contribu-
tion to the discussion on the ambiguity of the scalar product,
in the sense that the thermodynamics of the system is insensi-
tive with respect to the choice of the metric operator.

4 Conclusion
This paper was intended as a brief look into the realm of

pseudo-hermitian, or ��-symmetric, quantum mechanics. To
satisfy the need for more detailed information, we refer to the
review article [18] and special issues of Czech. J. Phys. and
J. Phys. A dedicated to ��-symmetric (pseudo-hermitian)
quantum mechanics [7–11], and to the references in these
publications.

In our presentation, we have tried to illustrate using
examples how the formalism of pseudo-hermitian quantum
mechanics can be used in the description of a physical system.
Particularly, we have illustrated how this contributes to a
consistent approach to the relativistic quantum mechanics
of integer-spin systems.

Pseudo-hermitian operators can be used in a description
of physical systems. However, their use requires a specific
approach. One has to be careful about the spectrum of the
operator – only operators with a real spectrum are physically
admissible. Derivation of the physical properties of the system
requires the construction of the new scalar product. The con-
struction depends on the Hamiltonian, so that the scalar
product is dynamically generated in this sense.

As we have remarked, the study of thermodynamic prop-
erties of the system described by pseudo-hermitian Hamil-
tonians represents a new stream in the field, and may provide
an insight into the physical properties of these systems.

Acknowledgment
The author would like to thank the Universidad de Santi-

ago de Chile for its kind hospitality. The work was partially
supported project No. LC06002 and by GAČR grant
Nr. 202/07/1307.

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Ing. Vít Jakubský, Ph.D.
phone: +420 266 173 255
email: jakub@ujf.cas.cz

Departamento de Física
Universidad de Santiago de Chile
Casilla 307, Santiago 2, Chile

(and
phone: +420 266 173 255
Academy of Science of the Czech Republic

250 68 Rež, Czech Republic)

74 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 47 No. 2–3/2007