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NMR and electron spectroscopic studies of La (III), Lu (III), Nd (III), Ho (III) complexes with glutamic acid
INORG. NUCL. CHEM. LETTERS VoI.]7, pp.57-61. Pergamon Press Ltd. 1981. Printed in Great Britain.
0020-1650/8|/020057-05502.00/0
NMR AND ELECTRON SPECTROSCOPIC Lu(III),
Nd(III),
Ho~III)
J. Legendziewicz,
Institute
of
Joliet-Curie
(Received 29 September
The
coordination
different NMR a n d
electron
ions
Chemistry,
University
of
1~,
Wroc£aw,
Poland
of in
absorption
Budapest. from
meter
at
oxides
50-383
glutamio
aqueous
amino The
ratio
acid
were acid
concentration
to
in
out
spectra
equal
integration
the
recorded
in
their
which
£-f
H.
of
the
bands
environment.
obey
the
selection
used
He t o
The
the
by means
an
Asp
l&nthanide
However,
as
rules
of
it
from
Nd(IlI) in
rof.
internal
N-512
O. 1 t o
of
(or
pH-meter.
0.2
were
Glu)
1204
obtained
[ ~ ) MHZ s p e c t r o -
In
The the
pH
h~4R s t u -
M. and
strengths Odra
Reanal
standard.
the
14 s p e c t r o p h o t o m e t e r
an
and
obtained
on a JEOL JNM-PS-100
oscillator
usin~
as
given
as
from
on a Cary
0.05
in
was
the
to
transitions
towards
established
He ( I I I } a n d
on a Mera.EImat
Results The
used
recorded
varied of
were
description
D20 wore
concentration
were
was
groups
tal
Lu~III),
Dioman
oarTied
absorption
carboxyl
solutions
acid
La(III),
(FT mode).
solutions
graphic
of
accordi~
25 ~z
Wroolaw,
spectra.
L-glutamic
1~C NMR s p e c t r a
measurements dies
and
Perohlorates
metal The
acid
H. K o z l o w s k i ,
owska
Ex~rtmen L-aspartic
ACID
1980; received in revised form 24 November ]980)
ability
lanthanide
COMPLEXES WITH G L U T ~ I C
E. Huskowska,
B. Je~owska-Trzebiat
S T U D I E S OF L a ( I I I ) ,
were
Nd:Glu=l: at
1 molar
a metal
calculated
ion with
computer.
Discussion ions
was ~J
57
~
are
slightly
reported 2
(~L
sensitive
earlier(2) ~
2,
~S
,
to the
= O) a r e
char~es transitions unusually
58
NMR
sensitive
to s u c h c h a n g e s .
covalent~
dynamic
when
And Electron Spectroscopic Studies
No m a t t e r w h i c h m e c h a n i s m
coupling(l-~))would be a s s u m e d
the c o o r d i n a t i o n
of a l a n t h a n i d e
a coordinated water molecule takes place~ m a r k e d
by means
oscillator
those t r a n s i t i o n s ,
ion to a l i g a n d or the r e p l a c e m e n t
in the a q u o - i o n b y a n o t h e r
F o r that r e a s o n
tran-
c o u l d be
transitions.
s p e c t r a w e r e r e c o r d e d i n the 3 1 9 . 5
ion a n d in the 289 -
of
sclvatin~ molecule
the c o m p l e x a t i o n p r o c e s s
of the ohar~ges of h y p e r s e n s i t i v e
The absorption the Nd(III)
relevant for
c h a n ~ e s in the i n t e n s i t y of the a b o v e m e n t i o n e d f-f
s i t i o n s are o b s e r v e d . followed
(forced e l e c t r i c dipole,
- 909 nm r e g i o n f o r
1250 nm r e g i o n f o r the H o ( I I I ) ion. T h e
strengths were calculated from
the f o r m u l a
:
f
P
4.31 Io'9~ ~&~
=
v4
where
~ i is a m o l a r a b s o r b a n c e T h e pH d e p e n d e n c e
transitio~ as f o r
5I 8
,
of the o s c i l l a t o r
5G6,
the N d (III)ion
are g i v e n i n T a b l e s
c o e f f i c i e n t and
7F I
s t r e n g t h s f o r the He (III)
P
~I9/2
is
to these f o u n d
116 (pH = 2.5~)
complex
in the Nd(III)
and
Pexp 108
pH
ion
- P
with glutamic acid
aquo-lon
)
: G l u s o l u t i o n s a r e vet T
f o r A s p c o n t a i n i n ~ s o l u t i o n s a n d 91
f o r Giu c o n t a i n i n g s o l u t i o n s °
T~BLE 1 O s c i l l a t o r S t r e n g t h of 5I 8 --~ 5G6, 7F 1 T r a n s i t i o n f o r H o ( I I I ) S o l u t i o n s a t V a r i o u s pH pH
-1
: A s p s y s t e m s t u d i e d earlier(8)i.e. A P
186(pH = 4.241
(pH = 2.78) and 209 (pH -- 4.84)
cm
2G7/2
i 4G5/2,
T h e i n t e n s i t y o h a n ~ e s f o u n d f o r the N d (III) close
a wave number
w i t h a s p a r t i c a c i d and g l u t a m i c a c i d as w e l l
transition
1,2,3 { n P =
~
Pexp 108
pH
: Asp
Pexp" 108
aquo
612
2.93
7~6
5.2
896
2.k8
703
4.47
891
5.3
885
2.75
7~2
~.86
884
5.6
936
NMR And Electron Spectroscopic Studies
TABLE Oscillator Solutions
Strength
for Ho(III)
: Glu
Pox~ 108
pH
Pexp
pH
aquo
572
2.56
635
4.45
919
1.62
606
2.8
688
4.95
899
2.28
633
3,27
725
5,8
967
TABLE Oscillator
Strength
Glu Solutions
pH
3
of ~ I 9 / 2 --*
at V a r i o u s
Pex/~ 108
4G5/2
2G7/2,
Transition
pH
Pexl:; 108
pa
Pexp"
2.78
1052
4.56
1243
1,97
1002
3.16
1103
4.8h
1261
2.52
1027
4.38
1241
5.03
1258
libria
are
similar It
the
~
P value
the
same,
lue
was the
is
first
these
observed
two t i m e s
for
absorption
higher.
different
that
for
second That
might
group
or
spectral
= 5.3)
coordination
presented
above
suggests
in a s i m i l a r way, NMR data f o r
which
the
of
the
by its
different
behaviour ~P to
i.e.
coordination
to
containir~
COO- g r o u p group the
equi-
Nd(III),
was a l m o s t
the
~
stronger
coordination
is o b s e r v e d f o r
P va-
bonding
mode
I8).
the He iIII) : A s p
c a u s e d by a c o o r d / n a t i o n
of the
133 a n d
of the
~P
the c o o r d i n a t i o n
only s l i g h t l y groups
they are s i m i l a r
w i t h A s p a n d Olu. The
that GIu c o o r d i n a t e s is not
~
carborFlio
of the G l u c a r b o x y l
complexes
the La(III)
systems
be due either
increases
f o r pH = 2.8 and 221 for pH = 4.95 the case of the Nd III
that
the
coordinated
g r o u p ( pH < 3) is equal
second c a r b o x y l g r o u p ( p H a correspondin~
all
coox~Ltnation
In the HoIIIII : A s p s o l u t i o n
carboxyl
spectra
108
systems,
for
the
oarboxylio
Slightly system.
in
the
characteristic
whereas
second
from
:
pH
961
appears
1o 8
f o r Nd{Ill)
aquo
It
of
7F 1 T r a n s i t i o n
pH
Pexp 108
pH
2
of 5I 8 ---# 5G6,
at V a r i o u s
59
to
140. For
to H o ( I I I 1 ~ P
= 116
to those f o u n d in spectroscopic
to light a n d h e a v y
data
lanthanldes
the case f o r Asp. a n d Lu(III)
c o m p l e x e s w i t h G l u are p r e s e n t e d
60
NMR And Electron Spectroscopic Studies
in Tabte
/4.
dination
to Glu at
1.1 a n d All
shift
pH 2 . 5 6
1 . 0 ppm d o w n £ i e l d
other
tion
1~C c h e m i c a l
at
carbons this
pH r e g i o n
to
the
ion,
and Lu(IlI)
. The do~ield
L,(III)
of
ion
metal
ion
to
and a water
this
are
These
metal
and
the
may d e r i v e
Ln(III)
s y ,
t
e -
Shifts
pH
mode i s
are
~ CO0- i n
the
coordina-
bound in
similar
for
tbLs
La(IlI)
presence
coordination
bond formation
of
the
o£ t h e
between
~ C00H
/4
of GIu
Qcoo~"
Ocoo~
p.p.m Glu c = 0.1 M
ton
~ COO" i s
from partial
they
~ COO- c a r b o n s .
to metal
that
of
and
coor-
aquo-ion.
TABL~ 13C c h e m i c a l
1.0 for
ooordXnatton shift
Lu(III)ion
similar
Insensitive
or from hydrogen
the
are
and
s~ggest
chemical
~ COO- g r o u p of
rather
results
pH r e g i o n
molecule
by La(III)and
~ COO- a n d 0 . 9
C ~
pH r e g i o n .
caused
( ~ COO- d e p r o t o n a t e d ) for
expect
changes
p.p.m
Ocp
~c~
,~c~-
p.p.m
p.p.m
p.p.m
2.59
110.1
106.5
-13.1
--36.8
-/41.-3
= 1:1 0.2M
2.57
111.0
107.6
-1-3.0
--36./4
-741.3
L u : G l u = 1:1 o = O.2H
2.56
111.1
107.5
-1-3.0
-36./4
-/41.3
Glu
/4.8/4
113.6
107.8
-12.1
-3/4.0
-39.9
/4.79
117.2
108.5
-12.3
-33.6
-/40.5
/4.81
117.8
108./4
-12.3
-.3/4.0
-/40.5
La:Glu o
=
o = 0.2 M
La:Olu c
= 1:1 = 0.2g
L u - Gku = 1:1 c = 0.2H At a higher field This
shift
indicates
The it
~ is
(Table of 0.6 that in
of
pH r a n g e
~ COO- c a r b o n
of
that
~ C00- group
also
ligan4
pH m n ~ e
shifted
pH r e g i o n
the La(III)
~ COO- r e - s i n s the
this
up£ield
/4~. A t t h e ppm f o r
/4.8 m e t a l
the
CO0- s h X £ t a t
slightly
above
bound
molecule
is
as above
tons
3.6(La
is
almost to
/4.8 a l s o
the
metal
the
CA
ion
not
the
same a s
and
that
to
eqtml
the
for
both
solutions
that
the
metal at
This
charge
o f pH ~ 2 . 6 .
tons. ions
and
pH 2 . 5 6
an up~ield
solution.
down-
(Lu ( I T I I ) .
lanthanide
undergoes
containing
to
a oonstdex~able
~ I I I ) ) a n d /4.2 ppm
coordinates
compared
and LulIII )
caused
sh4ft
stq~geste distribution
NMR And Electron Spectroscopic Studies
The c o n s i d e r a b l e difference in
i~ COO"
Glu a n d
in Asp strongly s ~ g e s t s
of those groups w i t h lanthanide strengths
in the chemical
shifts of b o u n d
a different
~ COO-
c o o r d i n a t i o n mode
ions. This m a y result f r o m t h e different
of the chemical bends or f r o m the different
lexes e.g. A s p m a y f a v o u r
6
g e o m e t r y of t h e comp-
the f o n a a t i o n of the chelate complex more
than
Glu since in the latter case, a t h e r m o d y n a m i c a l l y unstable eight m e m b e r e d rin~ has to be
formed.
In the latter case the f o r m a t i o n dimerio or polyme-
ric species is more likely. ctra were n o t able 13C NMR spectra
As was m e n t i o n e d
to distinguish,
between
of the lanthanide
detect chan~es in the a m i n o a c l d molecule
the a b s o r p t i o n
spe-
those differences found in the
. E l e c t r o n s p e c t r o s c o p y m a y allow
in the closest environment
lanthanide
previously
to f i n d the d i f f e r e n c e s
ion while
the N M R parameters
caused by its i n t e r a c t i o n w i t h
ion (8-10).
References
I.
J.LEGENDZIEWICZ, Phys.Aoad.Sci.,
K.BUKIETY~SKA Hungary,
~5,
2. C . K . J ~ R G E N S E N and B.R.JUDD, 3. B.R.JUDU,
J.Chem. Phys., 4~4,
and B.JETOWSKA-THZEBIATOWSKA,Aota
187
1971
Mol. Phys., --8, 281 839
1964
1966 B.
4. D . E . H E N R I E and G.R.CHOPPIN, J.Chem. Phys., 49, 477 5. K . B U K I E T Y ~ S K A
and G.R.CHOPPIN,
6. S . F . H A S O N , R . D . P E A C O C K
J.Chem. Phys.,
and B.STEWARD
7- R.D.PEACOCK, S t r u o . B o n d l n g ,
22,
83
1968
52, 2875
Mol. Phys., 30,
1829
14, 4o9-141
and E.BURZALA,
J.Am.Chem.Soc°,
a n d EoHUSKOWSKA,
Inorg.Nucl°Chem.Lett. ,
1978
10. A.D.SHERRY a n d E.PASCUAL,
1975
1975
6 . J.LEGENDZIE~/ICZ, H.KOZLOWSKI, B.JE~OWSKA-TRZEBIATOWSKA Inorg.Nucl.Chem.Lett. , 15, 349-353 1979 9. J . L E G E N D Z I E W I C Z , H . K O Z L O W S K I
1970
99,
18
1977
0020-1650/8|/020057-05502.00/0
NMR AND ELECTRON SPECTROSCOPIC Lu(III),
Nd(III),
Ho~III)
J. Legendziewicz,
Institute
of
Joliet-Curie
(Received 29 September
The
coordination
different NMR a n d
electron
ions
Chemistry,
University
of
1~,
Wroc£aw,
Poland
of in
absorption
Budapest. from
meter
at
oxides
50-383
glutamio
aqueous
amino The
ratio
acid
were acid
concentration
to
in
out
spectra
equal
integration
the
recorded
in
their
which
£-f
H.
of
the
bands
environment.
obey
the
selection
used
He t o
The
the
by means
an
Asp
l&nthanide
However,
as
rules
of
it
from
Nd(IlI) in
rof.
internal
N-512
O. 1 t o
of
(or
pH-meter.
0.2
were
Glu)
1204
obtained
[ ~ ) MHZ s p e c t r o -
In
The the
pH
h~4R s t u -
M. and
strengths Odra
Reanal
standard.
the
14 s p e c t r o p h o t o m e t e r
an
and
obtained
on a JEOL JNM-PS-100
oscillator
usin~
as
given
as
from
on a Cary
0.05
in
was
the
to
transitions
towards
established
He ( I I I } a n d
on a Mera.EImat
Results The
used
recorded
varied of
were
description
D20 wore
concentration
were
was
groups
tal
Lu~III),
Dioman
oarTied
absorption
carboxyl
solutions
acid
La(III),
(FT mode).
solutions
graphic
of
accordi~
25 ~z
Wroolaw,
spectra.
L-glutamic
1~C NMR s p e c t r a
measurements dies
and
Perohlorates
metal The
acid
H. K o z l o w s k i ,
owska
Ex~rtmen L-aspartic
ACID
1980; received in revised form 24 November ]980)
ability
lanthanide
COMPLEXES WITH G L U T ~ I C
E. Huskowska,
B. Je~owska-Trzebiat
S T U D I E S OF L a ( I I I ) ,
were
Nd:Glu=l: at
1 molar
a metal
calculated
ion with
computer.
Discussion ions
was ~J
57
~
are
slightly
reported 2
(~L
sensitive
earlier(2) ~
2,
~S
,
to the
= O) a r e
char~es transitions unusually
58
NMR
sensitive
to s u c h c h a n g e s .
covalent~
dynamic
when
And Electron Spectroscopic Studies
No m a t t e r w h i c h m e c h a n i s m
coupling(l-~))would be a s s u m e d
the c o o r d i n a t i o n
of a l a n t h a n i d e
a coordinated water molecule takes place~ m a r k e d
by means
oscillator
those t r a n s i t i o n s ,
ion to a l i g a n d or the r e p l a c e m e n t
in the a q u o - i o n b y a n o t h e r
F o r that r e a s o n
tran-
c o u l d be
transitions.
s p e c t r a w e r e r e c o r d e d i n the 3 1 9 . 5
ion a n d in the 289 -
of
sclvatin~ molecule
the c o m p l e x a t i o n p r o c e s s
of the ohar~ges of h y p e r s e n s i t i v e
The absorption the Nd(III)
relevant for
c h a n ~ e s in the i n t e n s i t y of the a b o v e m e n t i o n e d f-f
s i t i o n s are o b s e r v e d . followed
(forced e l e c t r i c dipole,
- 909 nm r e g i o n f o r
1250 nm r e g i o n f o r the H o ( I I I ) ion. T h e
strengths were calculated from
the f o r m u l a
:
f
P
4.31 Io'9~ ~&~
=
v4
where
~ i is a m o l a r a b s o r b a n c e T h e pH d e p e n d e n c e
transitio~ as f o r
5I 8
,
of the o s c i l l a t o r
5G6,
the N d (III)ion
are g i v e n i n T a b l e s
c o e f f i c i e n t and
7F I
s t r e n g t h s f o r the He (III)
P
~I9/2
is
to these f o u n d
116 (pH = 2.5~)
complex
in the Nd(III)
and
Pexp 108
pH
ion
- P
with glutamic acid
aquo-lon
)
: G l u s o l u t i o n s a r e vet T
f o r A s p c o n t a i n i n ~ s o l u t i o n s a n d 91
f o r Giu c o n t a i n i n g s o l u t i o n s °
T~BLE 1 O s c i l l a t o r S t r e n g t h of 5I 8 --~ 5G6, 7F 1 T r a n s i t i o n f o r H o ( I I I ) S o l u t i o n s a t V a r i o u s pH pH
-1
: A s p s y s t e m s t u d i e d earlier(8)i.e. A P
186(pH = 4.241
(pH = 2.78) and 209 (pH -- 4.84)
cm
2G7/2
i 4G5/2,
T h e i n t e n s i t y o h a n ~ e s f o u n d f o r the N d (III) close
a wave number
w i t h a s p a r t i c a c i d and g l u t a m i c a c i d as w e l l
transition
1,2,3 { n P =
~
Pexp 108
pH
: Asp
Pexp" 108
aquo
612
2.93
7~6
5.2
896
2.k8
703
4.47
891
5.3
885
2.75
7~2
~.86
884
5.6
936
NMR And Electron Spectroscopic Studies
TABLE Oscillator Solutions
Strength
for Ho(III)
: Glu
Pox~ 108
pH
Pexp
pH
aquo
572
2.56
635
4.45
919
1.62
606
2.8
688
4.95
899
2.28
633
3,27
725
5,8
967
TABLE Oscillator
Strength
Glu Solutions
pH
3
of ~ I 9 / 2 --*
at V a r i o u s
Pex/~ 108
4G5/2
2G7/2,
Transition
pH
Pexl:; 108
pa
Pexp"
2.78
1052
4.56
1243
1,97
1002
3.16
1103
4.8h
1261
2.52
1027
4.38
1241
5.03
1258
libria
are
similar It
the
~
P value
the
same,
lue
was the
is
first
these
observed
two t i m e s
for
absorption
higher.
different
that
for
second That
might
group
or
spectral
= 5.3)
coordination
presented
above
suggests
in a s i m i l a r way, NMR data f o r
which
the
of
the
by its
different
behaviour ~P to
i.e.
coordination
to
containir~
COO- g r o u p group the
equi-
Nd(III),
was a l m o s t
the
~
stronger
coordination
is o b s e r v e d f o r
P va-
bonding
mode
I8).
the He iIII) : A s p
c a u s e d by a c o o r d / n a t i o n
of the
133 a n d
of the
~P
the c o o r d i n a t i o n
only s l i g h t l y groups
they are s i m i l a r
w i t h A s p a n d Olu. The
that GIu c o o r d i n a t e s is not
~
carborFlio
of the G l u c a r b o x y l
complexes
the La(III)
systems
be due either
increases
f o r pH = 2.8 and 221 for pH = 4.95 the case of the Nd III
that
the
coordinated
g r o u p ( pH < 3) is equal
second c a r b o x y l g r o u p ( p H a correspondin~
all
coox~Ltnation
In the HoIIIII : A s p s o l u t i o n
carboxyl
spectra
108
systems,
for
the
oarboxylio
Slightly system.
in
the
characteristic
whereas
second
from
:
pH
961
appears
1o 8
f o r Nd{Ill)
aquo
It
of
7F 1 T r a n s i t i o n
pH
Pexp 108
pH
2
of 5I 8 ---# 5G6,
at V a r i o u s
59
to
140. For
to H o ( I I I 1 ~ P
= 116
to those f o u n d in spectroscopic
to light a n d h e a v y
data
lanthanldes
the case f o r Asp. a n d Lu(III)
c o m p l e x e s w i t h G l u are p r e s e n t e d
60
NMR And Electron Spectroscopic Studies
in Tabte
/4.
dination
to Glu at
1.1 a n d All
shift
pH 2 . 5 6
1 . 0 ppm d o w n £ i e l d
other
tion
1~C c h e m i c a l
at
carbons this
pH r e g i o n
to
the
ion,
and Lu(IlI)
. The do~ield
L,(III)
of
ion
metal
ion
to
and a water
this
are
These
metal
and
the
may d e r i v e
Ln(III)
s y ,
t
e -
Shifts
pH
mode i s
are
~ CO0- i n
the
coordina-
bound in
similar
for
tbLs
La(IlI)
presence
coordination
bond formation
of
the
o£ t h e
between
~ C00H
/4
of GIu
Qcoo~"
Ocoo~
p.p.m Glu c = 0.1 M
ton
~ COO" i s
from partial
they
~ COO- c a r b o n s .
to metal
that
of
and
coor-
aquo-ion.
TABL~ 13C c h e m i c a l
1.0 for
ooordXnatton shift
Lu(III)ion
similar
Insensitive
or from hydrogen
the
are
and
s~ggest
chemical
~ COO- g r o u p of
rather
results
pH r e g i o n
molecule
by La(III)and
~ COO- a n d 0 . 9
C ~
pH r e g i o n .
caused
( ~ COO- d e p r o t o n a t e d ) for
expect
changes
p.p.m
Ocp
~c~
,~c~-
p.p.m
p.p.m
p.p.m
2.59
110.1
106.5
-13.1
--36.8
-/41.-3
= 1:1 0.2M
2.57
111.0
107.6
-1-3.0
--36./4
-741.3
L u : G l u = 1:1 o = O.2H
2.56
111.1
107.5
-1-3.0
-36./4
-/41.3
Glu
/4.8/4
113.6
107.8
-12.1
-3/4.0
-39.9
/4.79
117.2
108.5
-12.3
-33.6
-/40.5
/4.81
117.8
108./4
-12.3
-.3/4.0
-/40.5
La:Glu o
=
o = 0.2 M
La:Olu c
= 1:1 = 0.2g
L u - Gku = 1:1 c = 0.2H At a higher field This
shift
indicates
The it
~ is
(Table of 0.6 that in
of
pH r a n g e
~ COO- c a r b o n
of
that
~ C00- group
also
ligan4
pH m n ~ e
shifted
pH r e g i o n
the La(III)
~ COO- r e - s i n s the
this
up£ield
/4~. A t t h e ppm f o r
/4.8 m e t a l
the
CO0- s h X £ t a t
slightly
above
bound
molecule
is
as above
tons
3.6(La
is
almost to
/4.8 a l s o
the
metal
the
CA
ion
not
the
same a s
and
that
to
eqtml
the
for
both
solutions
that
the
metal at
This
charge
o f pH ~ 2 . 6 .
tons. ions
and
pH 2 . 5 6
an up~ield
solution.
down-
(Lu ( I T I I ) .
lanthanide
undergoes
containing
to
a oonstdex~able
~ I I I ) ) a n d /4.2 ppm
coordinates
compared
and LulIII )
caused
sh4ft
stq~geste distribution
NMR And Electron Spectroscopic Studies
The c o n s i d e r a b l e difference in
i~ COO"
Glu a n d
in Asp strongly s ~ g e s t s
of those groups w i t h lanthanide strengths
in the chemical
shifts of b o u n d
a different
~ COO-
c o o r d i n a t i o n mode
ions. This m a y result f r o m t h e different
of the chemical bends or f r o m the different
lexes e.g. A s p m a y f a v o u r
6
g e o m e t r y of t h e comp-
the f o n a a t i o n of the chelate complex more
than
Glu since in the latter case, a t h e r m o d y n a m i c a l l y unstable eight m e m b e r e d rin~ has to be
formed.
In the latter case the f o r m a t i o n dimerio or polyme-
ric species is more likely. ctra were n o t able 13C NMR spectra
As was m e n t i o n e d
to distinguish,
between
of the lanthanide
detect chan~es in the a m i n o a c l d molecule
the a b s o r p t i o n
spe-
those differences found in the
. E l e c t r o n s p e c t r o s c o p y m a y allow
in the closest environment
lanthanide
previously
to f i n d the d i f f e r e n c e s
ion while
the N M R parameters
caused by its i n t e r a c t i o n w i t h
ion (8-10).
References
I.
J.LEGENDZIEWICZ, Phys.Aoad.Sci.,
K.BUKIETY~SKA Hungary,
~5,
2. C . K . J ~ R G E N S E N and B.R.JUDD, 3. B.R.JUDU,
J.Chem. Phys., 4~4,
and B.JETOWSKA-THZEBIATOWSKA,Aota
187
1971
Mol. Phys., --8, 281 839
1964
1966 B.
4. D . E . H E N R I E and G.R.CHOPPIN, J.Chem. Phys., 49, 477 5. K . B U K I E T Y ~ S K A
and G.R.CHOPPIN,
6. S . F . H A S O N , R . D . P E A C O C K
J.Chem. Phys.,
and B.STEWARD
7- R.D.PEACOCK, S t r u o . B o n d l n g ,
22,
83
1968
52, 2875
Mol. Phys., 30,
1829
14, 4o9-141
and E.BURZALA,
J.Am.Chem.Soc°,
a n d EoHUSKOWSKA,
Inorg.Nucl°Chem.Lett. ,
1978
10. A.D.SHERRY a n d E.PASCUAL,
1975
1975
6 . J.LEGENDZIE~/ICZ, H.KOZLOWSKI, B.JE~OWSKA-TRZEBIATOWSKA Inorg.Nucl.Chem.Lett. , 15, 349-353 1979 9. J . L E G E N D Z I E W I C Z , H . K O Z L O W S K I
1970
99,
18
1977