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Spin trimers in Ca3Cu2Ni(PO4)4M. Ghosh and K. Ghoshray
Citation: Low Temperature Physics 38, 645 (2012); doi: 10.1063/1.4734011 View online: http://dx.doi.org/10.1063/1.4734011 View Table of Contents: http://scitation.aip.org/content/aip/journal/ltp/38/7?ver=pdfcov Published by the AIP Publishing Articles you may be interested in Magnetic and dielectric properties of one-dimensional array of S=1/2 linear trimer system Na2Cu3Ge4O12 J. Appl. Phys. 115, 17E125 (2014); 10.1063/1.4865776 Transition from Pauli-paramagnetism to ferromagnetism in CaCu3(Ru4xMnx)O12 (0 x 3) perovskites J. Appl. Phys. 109, 123914 (2011); 10.1063/1.3597783 Size-driven magnetic transitions in La 1 / 3 Ca 2 / 3 MnO 3 nanoparticles J. Appl. Phys. 108, 063918 (2010); 10.1063/1.3488619 Submillimeter and Millimeter Wave ESR Measurements of the S=1/2 Trimer Chain M3Cu3(PO4)4 (M=Sr,Ca) AIP Conf. Proc. 850, 1037 (2006); 10.1063/1.2355057 Magnetic properties and spin dynamics in hole-doped S=1 AF chain: 89 Y NMR and susceptibility in Y 2x Ca xBaNiO 5 J. Appl. Phys. 83, 6605 (1998); 10.1063/1.367608
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Spin trimers in Ca3Cu2Ni(PO4)4
M. Ghosh and K. Ghoshraya)
ECMP Division, Saha Institute of Nuclear Physics, 1/AF Bidhannagar, Kolkata 700064, India(Submitted February 29, 2012)
Fiz. Nizk. Temp. 38, 815–820 (July 2012)
The nature of spin trimer and 3d spin dynamics in Ca3Cu2Ni(PO4)4 is studied using 31P NMR
measurements. The data are obtained by replacing one of the Cu ions by a Ni ion in the one
dimensional spin trimer compound Ca3Cu3(PO4)4. The NMR spectrum suggests the presence of
two types of magnetically inequivalent phosphorous atoms, as in the parent compound. This reveals
the presence of only one type of trimer, Cu2-Ni-Cu2, rather than of three types, Cu2-Cu1-Cu2,
Cu2-Cu1-Ni and Ni-Cu1-Ni, as indicated by neutron scattering. Hence, the ground state of
Ca3Cu2Ni(PO4)4 appears to be a quintet. These results also explain the magnetic susceptibility
behavior, which indicates no reduction in the net spin of the trimer in Ca3Cu2Ni(PO4)4, as expected
for JNi-Cu¼�0.85 meV compared to the value JCu-Cu¼�4.74 meV derived from neutron
scattering. The spin lattice relaxation rate suggests that the three magnon mediated scattering
process dominant in Ca3Cu3(PO4)4 is reduced in Ca3Cu2Ni(PO4)4. VC 2012 American Institute ofPhysics. [http://dx.doi.org/10.1063/1.4734011]
1. Introduction
Low-dimensional quantum spin systems have attracted
considerable attention because of the possibility of novel
magnetic effects such as quantum critical phenomena,1 Hal-
dane gap formation,2 and field induced Bose-Einstein con-
densation.3 Enhancement of quantum fluctuations due to low
dimensionality could suppress the magnetic ordering and
give rise to several such unusual phenomena. Recently it has
been suggested that in an S¼ 1/2 antiferromagnetic (AF)
chain with period 3, exchange coupling exhibits a plateau in
the magnetization curve where the magnetization stays con-
stant at a fraction of the saturation level over a finite range
of magnetic fields.4–6 This phenomenon in quantum spin
chains is analogous to the quantum Hall effect-topological
quantization of a physical quantity in a changing magnetic
field. Trimer chains are the first spin systems predicted to
have magnetization plateaux. However, spin trimer systems
are rare in nature. Among the few such systems, La4Cu3-
MoO12 is a 2D AF system in which the three Cu2þ spins
form a triangle, so that AF intra-trimer interactions are
frustrated7; nevertheless this system undergoes an AF
ordering near 2.6 K. Due to strong nearest neighbor (NN)
AF exchange, the net spin of the trimer decreases from 3/2
to 1/2 below 250 K, as revealed by the inverse susceptibility
v�1 curve.
A3Cu3(PO4)4 (A:Ca, Sr, Pb) is another spin trimer
system, in which Cu2-Cu1-Cu2 trimers are arranged in linear
chain, and the inter-trimer AF exchange interaction J2 is 3 K
while the intra trimer NN AF exchange interaction J1 is
about 126 K.8,9 As a result, below 45 K, the v�1 vs T curve
shows clear signs of a reduction in the net spin of the trimer
from 3/2 to 1/2.10 Thus, the ground state is a doublet, and is
a model system of a linear HAF trimer. In principle, a dou-
blet ground state of this kind can be changed into a singlet
ground state by substituting a Cu2þ (S¼ 1/2) spin in the
trimer by Ni2þ (S¼ 1), provided only one type of trimer
(e.g., Ni-Cu1-Cu2/Cu-Cu1-Ni) is formed. For the first time,
this provides an opportunity of realizing a gapped quantum
spin trimer system, with the possibility of observing Bose-
Einstein condensation (BEC) above a certain critical value
of an external magnetic field. BEC was observed in the spin
dimer system TlCuCl3 by inelastic neutron scattering.10,11
To investigate this in Ca3Cu3(PO4)4, Podlesnyak et al.12
studied inelastic neutron scattering in Ca3Cu3(PO4)4.
Unfortunately the singlet state was not realized. These stud-
ies also indicated that the middle position is exclusively
occupied by Cu2þ, whereas the end positions are statistically
populated by Cu2þ and Ni2þ; thus, three types of trimer,
Cu2-Cu1-Cu2, Cu2-Cu1-Ni and Ni-Cu1-Ni, are created with
doublet, triplet, and quintet ground states, respectively,
instead of only one type, Cu2-Cu1-Ni, with a triplet ground
state. The same result was obtained in an elastic neutron
scattering study.13 From these findings it was concluded that
the possible reason for the failure to observe a singlet ground
state in Ca3Cu2Ni(PO4)4, is the formation of three types of
trimers. Moreover, it was also shown that, JCu-Cu in Ca3Cu2-
Ni(PO4)4 increases to �4.92 meV from the �4.74 meV
observed in A3Cu3(PO4)4 and JNi-Cu¼�0.85 meV. Surpris-
ingly, the magnetic susceptibility data for Ca3Cu2Ni(PO4)4
(Refs. 13 and 14) in the range 2-300 K, did not manifest the
expected reduction in the net spins of the trimers Cu2-Cu1-
Cu2 and Cu2-Cu1-Ni, because of strong NN AF exchange
between the Cu2þ spins, as was seen in Ca3Cu2(PO4)4, where
only one type of trimer, Cu2-Cu1-Cu2, is present, with
weaker NN AF exchange as mentioned above. On the other
hand, the same behavior in Ca3Cu2Mg(PO4)4 indicated the
presence of more than one type of trimer with a clear
reduction in the net spins of certain types of trimers.14 A
comparison of the susceptibility data in Ca3Cu2(PO4)4,
Ca3Cu2Ni(PO4)4 and Ca3Cu2Mg(PO4)4, indicated that the Ni
atom in Ca3Cu2Ni(PO4)4 probably occupies the middle posi-
tion instead of the end positions of a trimer. On the other
hand, the Mg atom in Ca3Cu2Mg(PO4)4 occupies an end
position. In this connection it may be mentioned that, based
on neutron scattering in Ca3Cu2Ni(PO4)4, Pomjakushin
1063-777X/2012/38(7)/6/$32.00 VC 2012 American Institute of Physics645
LOW TEMPERATURE PHYSICS VOLUME 38, NUMBER 7 JULY 2012
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et al.13 also suggested that the valance of Ni has a reasonable
value if it occupies the middle position of the Cu2-Cu1-Cu2
trimer (according to a bond valence sum (BVS) calculation),
so that the Ni could occupy the middle position. Thus the
possibility of forming only one type of trimer, Cu2-Ni-Cu2,
with a quintet ground state cannot be neglected in the case of
Ca3Cu2Ni(PO4)4.
To understand this further, we have made a 31P NMR
study of polycrystalline samples of Ca3Cu2Ni(PO4)4. Fig. 1
illustrates the existence of a single type of trimer, Cu2-Cu1-
Cu2, in the unit cell of Ca3Cu2(PO4)4, when projected in the
ab plane, along with bonding of the two types of phospho-
rous (P) atoms, via the oxygen atom. P1 is bonded with two
nearest neighbor magnetic ions within a trimer and P2 is
bonded with the magnetic ions between the two trimers.
Now, if in Ca3Cu2Ni(PO4)4, the Ni ion occupies the Cu2 site,
resulting in three types of trimers as mentioned above, then
it follows from Fig. 1 that the local magnetic environments
of all the P1 atoms in the unit cell will not be identical and
that same would be true for P2. As a result, the resonance
line positions of all the P1 atoms would not superimpose at a
particular frequency, and the same would be true for P2.
This would produce a more complicated 31P NMR spectrum
than that observed for Ca3Cu3(PO4)4,15 where the spectrum
is a superposition of two resonance lines corresponding to
P1 and P2 indicating that all the P1 nuclei experience the
same local magnetic field, and that the same is true for P2.
On the other hand if the Ni atom occupies the Cu1 position,
then there will be only one type of trimer, i.e., Cu2-Ni-Cu2.
In this case, Fig. 1 implies that all the P1 atoms will be
linked with Cu2 on one side and with Ni on the other side
within a trimer, and therefore, will have identical magnetic
environments, while all the P2 atoms will be bonded on both
sides with Cu2 atoms of the trimers of the two consecutive
chains. In this case the 31P resonance line for Ca3Cu2-
Ni(PO4)4 would be a superposition of two lines similar to
that in the pure compound. Thus NMR studies should pro-
vide valuable information about the possible type of trimers
formed in Ca3Cu2Ni(PO4)4, and, therefore, on the magnetic
ground state of this system. In addition, the 31P nuclear spin
lattice relaxation rate should provide additional information
about the effect of Ni substitution on the one-dimensional
spin dynamics, which is currently a topic of great interest.
2. Experiment
A polycrystalline sample of Ca3Cu2Ni(PO4)4 was synthe-
sized using the solid state reaction method, by heating a stoi-
chiometric mixture of CuO (99.99%), NiO (99.99V), CaCO3
(99.99%) and NH4H2PO4 (99.99%) very slowly up to 600 �Cand then annealing at 900 �C for 120 h, with several interme-
diate grindings. The sample is characterized at room tempera-
ture using x-ray diffraction (XRD) with CuKa radiation
(k¼ 1.5406 A). All the peaks can be indexed on the basis of
monoclinic structure with space group P21/a and cell parame-
ters a¼ 17.718(1) A, b¼ 4.888(2) A, c¼ 8.84(1) A, and
b¼ 123.8(1)�, in satisfactory agreement with reported values.13
The NMR measurements were carried out at fields H¼ 1.39 T
(vR¼ 24.005 MHz) and H¼ 7.04 T (vR¼ 121.423 MHz) using
a conventional phase-coherent Thamway PROT4103 pulse
spectrometer. The spectrum was recorded by changing the fre-
quency step by step and recording the spin-echo intensity by
applying a p/2-s-p/2 solid echo sequence. Observations at tem-
peratures in the range 4-300 K were made in an Oxford contin-
uous flow dynamic cryostat with a ITC503 controller. The shift
is measured with respect to the position of the 31P NMR line
(vR) in H3PO4 solution.
3. Results and discussion
3.1. NMR spectra and shift parameters
Figure 2 shows the 31P NMR spectrum of Ca3Cu2-
Ni(PO4)4 at 300 K in a field of 7 T along with the same for
Ca3Cu3(PO)4 (Ref. 14) and Ca3CuNi2(PO4)4 (Ref. 14) as a
comparison. The spectrum for Ca3Cu2Ni(PO4)4 shows a typ-
ical overlap of two powder patterns for nuclear spin I¼ 1/2
having different component of shift parameters, similar to
that observed in the other two compounds. It is to be noted
that the position of the resonance line for P2 in Ca3Cu3(PO)4
FIG. 1. Three trimers (A, B, and C) in Ca3Cu2(PO4)4, viewed from the zaxis showing the possible superexchange paths between the trimers in the abplane. Cu1 and Cu2 atoms are indicated by blue and yellow spheres, respec-
tively, and O and P atoms by red and green spheres. The Ca atoms are not
shown. The structure has been drawn using the coordinates given in Ref. 13.
FIG. 2. 31P NMR spectra of polycrystalline Ca3CuNi2(PO4)4,14 Ca3Cu2-
Ni(PO4)4 and Ca3Cu3(PO4)4 (Ref. 14) at 300 K recorded at H¼ 7 T (open-
circles). The theoretical curve (dashed) calculated using Eq. (1), along with
two constituent lines (continuous) corresponding to resonance lines of two
inequivalent phosphorous atoms are also shown. The vertical line indicates
the reference position at frequency 121.42 MHz.
646 Low Temp. Phys. 38 (7), July 2012 M. Ghosh and K. Ghoshray
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and in Ca3Cu2Ni(PO4)4 are close to each other, whereas, in
Ca3CuNi(PO4)4 the shift of the line for P2 is higher. In the
case of Ca3CuNi2(PO4)4, a higher value of the shift is
expected, as the P2 atom is bonded on both sides with Ni2þ
ions with S¼ 1. On the other hand, in Ca3Cu3(PO4)4, P2 is
bonded on both sides with Cu2þ ions with S¼ 1/2. In
Ca3Cu2Ni(PO4)4, if the Ni atom occupies the Cu1 position,
with the end positions of the trimer being occupied by Cu2
atoms, then P2 in this compound will also be bonded with
Cu2 atoms on both sides, so that the local magnetic field
experienced by P2 in this compound would also be similar to
that of the pure compound. Moreover, if only Cu2-Ni-Cu2
trimer is present in Ca3Cu2Ni(PO4)4, then P1 atoms would
be bonded with Cu2 on one side and Ni on the other side,
similar to the situation in Ca3CuNi2(PO4)4, where the only
the trimer Ni- Cu2-Ni is present. In this case, the local mag-
netic field at a P1 site in Ca3CuNi2(PO4)4 and Ca3Cu2-
Ni(PO4)4 would be almost the same. Interestingly, it can be
seen from Fig. 2 that the positions of the resonance lines of
P1 in Ca3Cu2Ni(PO4)4 and Ca3CuNi2(PO4)4 are very close
to each other. These observations indicate that the Ni atom
in Ca3Cu2Ni(PO4)4 most probably occupies the Cu1 position
of the trimer in Ca3Cu2Ni(PO4)4; this means that only one
type of trimer, Cu2-Ni-Cu2, is present in this compound. In
order to determine the shift parameters, the experimental
spectra for Ca3Cu2Ni(PO4)4 were fitted to the following
equation over the entire temperature range,
v ¼ vR½1þ Kiso þ Kaxðcos2 h� 1Þ þ Kansin2h cos 2/�; (1)
where Kiso, Kax and Kan are the isotropic, axial and anisotropic
parts of the shift, respectively, arising from Hlocal at the site of
the 31P nucleus through the electron nuclear hyperfine and the
dipolar interactions. �R is the reference frequency as men-
tioned earlier. h and u are the Euler angles between the princi-
pal axes of the hyperfine coupling tensor and the direction of
the external magnetic field (Zeeman field).
Figure 3 shows the measured 31P NMR spectra at differ-
ent temperatures in the range 4-300 K for Ca3Cu2Ni(PO4)4
along with theoretical spectra. The experimental curves
below 300 K are also well fitted with two constituent lines.
This also suggests that the internal magnetic fields at each
type of P site vary identically throughout the range 4-300 K.
Therefore, based on the spectral features over the whole tem-
perature range, it also appears that the Ni atom occupies the
Cu1 position in a Cu2-Cu1-Cu2 trimer, as discussed above.
Figure 4 shows the variation of Kiso, Kax and Kan with T, and
the insets illustrate the variation of these parameters with the
bulk susceptibility.
We also did the NMR experiment at a much lower reso-
nance frequency of 24 MHz with H¼ 1.39 T. The shift param-
eters obtained by fitting the spectra recorded at H¼ 1.39 T for
160–300 K, are also included in Fig. 4. The close agreement
between the values obtained by analyzing the spectra at two
widely different resonance frequencies validates the accuracy
of the results.
The shift is related to vspin by the relation,
K ¼ K0 þHhf
NlB
vspinðTÞ; (2)
where Hhf is the hyperfine field, K0 is the chemical shift, N is
the Avogadro number and vspin(T) is the contribution of
FIG. 3. 31P NMR spectra of polycrystalline Ca3Cu2Ni(PO4)4 at different
temperatures recorded with H¼ 7 T. The notation is as in Fig. 2.
FIG. 4. Temperature variation in Kiso (a), Kax (b), and Kan (c), measured for
H¼ 7 T: the filled squares are for P1 sites and the stars are for P2 sites. For
H¼ 1.39 T: the triangles are for P1 sites and the filled circles are for P2 sites.
The inset shows the dependences of Kiso (a), Kax (b), and Kan (c) for both P1
and P2 sites on vM with temperature as an implicit parameter.
Low Temp. Phys. 38 (7), July 2012 M. Ghosh and K. Ghoshray 647
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electronic spin to the magnetic susceptibility. As long as the
hyperfine field remains constant, K should follow v(T). The
contribution to Hhf arises from the transferred hyperfine
interaction, which is a property of the electronic structure,
and the dipolar interaction, neither of which is temperature
dependent. Although K(T) need not have the same symmetry
as v(T), the temperature dependence of K(T) should reflect
that of v(T). The inset to Figs. 4(a)–4(c) shows that Kiso, Kax
and Kan vary linearly with v(T) in the range 15–300 K. The
linearity suggests a unique hyperfine coupling constant over
this temperature range. Below 15 K, there is a deviation
from linearity. By using Eq. (1), we determine the values of
isotropic, axial and the anisotropic parts of the hyperfine
field for these two sites. Table 1 lists the values of Hisohf , Hax
hf ,
and Hanhf for the P1 and P2 sites for Ca3Cu2Ni(PO4)4, together
with those for Ca3Cu3(PO4)4 (from our measurements),14 for
comparison.
3.2. Nuclear spin-lattice relaxation rates
In order to investigate the effect on the electron spin dy-
namics of replacing one of the Cu2þ ions by a Ni2þ ion in a
trimer of Ca3Cu3(PO4)4, we have measured the 31P nuclear
spin-lattice relaxation rate 1/T1, which is a very sensitive
probe of the low energy electron spin fluctuations. 1/T1 is
measured by the saturation recovery method using a single
p/2 pulse. The measurements were made in an external mag-
netic field of 7 T at temperatures of 4–300 K and in a field of
1.39 T for 160–300 K, in order to see whether the strong field
dependence of 1/T1 observed in case of Ca3Cu3(PO4)4,16 as
well as in the isostructural Sr3Cu3(PO4)4 (Ref. 16) in the
high temperature range, is also present in Ca3Cu2Ni(PO4)4.
Figure 5 shows the 1/T1 vs T curves for one type of phospho-
rous site (P2), measured in magnetic fields of 7 T and 1.39 T
for Ca3Cu2Ni(PO4)4, together with those for Sr3Cu3(PO4)4
(Ref. 16) and Ca3CuNi2(PO4)4 (Ref. 17) as a comparison. It
is seen that 1/T1 for Sr3Cu3(PO4)4 is strongly field depend-
ent, as reported for the isostructural Ca3Cu3(PO4)4, while the
same curve for Ca3CuNi2(PO4)4 shows negligible field de-
pendence. On the other hand 1/T1 for Ca3Cu2Ni(PO4)4, still
remains field dependent with the influence of H smaller than
for the pure compound. This shows that the substitution of
Ni2þ (S¼ 1) in place of Cu2þ (S¼ 1/2) strongly affects the31P nuclear relaxation mechanism. 1/T1 in such compounds
is governed by the thermal excitations of the 3 d spins, and
can be written as
1
T1
¼ 2c2nkBTRjAðqÞj2v00ðq;xnÞ=xn; (3)
where cn is the nuclear gyromagnetic ratio, A(q) is the (wave
vector dependent) hyperfine coupling, and v00(q, xn), is the
dissipative component of the chain dynamic susceptibility
evaluated at the nuclear Larmor frequency xn.18
The values of 1/T1 for Ca3Cu2Ni(PO4)4 remain almost
constant in the temperature range 6.5–300 K for H¼ 7 T.
Below 6.5 K it shows a decreasing trend which is also con-
firmed by the change in the 31P nuclear magnetization recov-
ery curves from 6.5 to 4 K (Fig. 6). In the pure compound,
however, 1/T1 remains constant over 50–300 K and decreases
continuously at lower temperatures. In Ca3CuNi2(PO4)4, 1/T1
remains constant over 26–300 K and has a peak at 16 K owing
to an antiferromagnetic transition. The T independent behav-
ior of 1/T1 is typical feature of fast spin fluctuation (xe�xn)
of the paramagnetic moments. A comparison of this behavior
in the three compounds suggests that substitution of one cop-
per ion in a trimer by a Ni ion reduces the extent of the field
dependence and also extends the range over which 1/T1 is in-
dependent of T. This indicates a reduction in the magnetic
field dependent three-magnon mediated relaxation process,
with an enhancement of the two-magnon contribution, in
TABLE 1. Values of 31P hyperfine fields.
Parameters, kOe/lB Ca3Cu3(PO4)4 Ca3Cu3Ni(PO4)4
Hisohf for P1 1.28 6 0.03 1.32 6 0.02
Hisohf for P2 0.43 6 0.03 0.3 6 0.03
Haxhf for P1 0.44 6 0.01 0.41 6 0.01
Haxhf for P2 0.16 6 0.01 0.20 6 0.02
Hanhf for P1 0.50 6 0.02 0.32 6 0.02
Hanhf for P2 0.15 6 0.01 0.13 6 0.01
FIG. 5. 1/T1 as a function of T for Sr3Cu3(PO4)4 (Ref. 16) (a), Ca3Cu2-
Ni(PO4)4 (b) and Ca3CuNi2(PO4)4 (Ref. 17) (c) for H¼ 7.045 T (solid trian-
gles) and H¼ 1.39 T (solid circles). The error bar for each point corresponds
to the size of the symbol.
648 Low Temp. Phys. 38 (7), July 2012 M. Ghosh and K. Ghoshray
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Ca3Cu2Ni(PO4)4, while the former contribution is still present.
However, replacement of two Cu ions by Ni ions reduces the
range over which 1/T1 is independent of T, because of the
appearance of magnetic ordering at 16 K, with the H depend-
ence being completely suppressed, so that 1/T1 is governed
only by the two-magnon mediated Raman process. According
to the localized spin model for a high temperature limit,18 1/
T1 at a non magnetic nucleus can be written as
1
T1
¼ffiffiffiffiffiffi
2ppð2cnHhf Þ2 z0SðSþ 1Þ=ð3xexÞ; (4)
where the local spin exchange frequency xex¼ (2/3)� (J2/
�h2)� [zS(Sþ 1)]. The constants z¼ 2 and z0 ¼ 2 correspond
to the exchange-coupled local spin numbers and those of the
local spins interacting with the probing nucleus, and J is the
exchange constant respectively.18
We have calculated the value of 1/T1 for Ca3Cu2Ni(PO4)4
and Ca3CuNi2(PO4)4 taking cn¼ 1.083�108 s�1�T�1 for the
phosphorous nucleus and the values of Hisohf from Table 1. In
the case of Ca3Cu2Ni(PO4)4, if we assume that a Ni atom
occupies the middle position of the trimer, then P1 will be
affected by an intra-trimer exchange interaction between Cu2
and Ni. The strength of this exchange interaction JNi-Cu has
been determined by neutron scattering.12 We have used this
value for calculating T1 for P1 in Ca3Cu2Ni(PO4)4. In this
compound, P2 will be bonded with Cu2 ions of adjacent
trimers. Since the inter-trimer Cu2-Cu2 exchange constant
was not reported by Podlesnyak et al.12 we have used a value
of JCu-Cu (�0.258 meV) derived from magnetic susceptibility
data9 for Ca3Cu3(PO4)4 to calculate T1 for the P2 in Ca3Cu2-
Ni(PO4)4. The resulting value (Table 2) is in close agreement
with experiment. However, in the case of Ca3CuNi2(PO4)4,
since P2 is bonded on both sides with Ni ions and the inter-
trimer JNi-Ni is not known from either neutron scattering or
magnetic susceptibility measurements, we could calculate T1
only for the P1 (Table 2). In this case the agreement of the ex-
perimental and theoretical values is also quite satisfactory. So
our conclusions based on spin-lattice relaxation data further
support our suggestion based on analyzing the 31P line
shape in Ca3Cu2Ni(PO4)4, that a Ni atom most probably
occupies the middle position of the trimer, so that there is
only one type of trimer, Cu2-Ni-Cu2, rather than the three
types, Cu2-Cu1-Cu2, Cu2-Cu1-Ni, and Ni-Cu2-Ni, indicated
by neutron scattering. So the ground state of this compound is
a quintet.
4. Conclusion
We have studied the static and dynamic magnetic prop-
erties of the trimer spin chain compound Ca3Cu2Ni(PO4)4,
which remains in a paramagnetic phase at temperatures of
4–300 K, using 31P NMR studies in the temperature range
4–300 K with an external magnetic field of 7 T and in the
temperature range of 160–300 K with H¼ 1.39 T. At all tem-
peratures the spectrum corresponds to a typical overlap of
two powder patterns, indicating the presence of two types of
P atoms within the unit cell similar to that in Ca3Cu3(PO4)4
and Ca3CuNi2(PO4)4. This finding, together with data on
spin lattice relaxation, indicates that most probably only one
type of trimer, Cu1-Ni-Cu2 exists in Ca3Cu2Ni(PO4)4; this
could also explain satisfactorily the magnetic susceptibility
behavior, which gives no indication of a reduction in the net
spin of any trimer, as the NN interaction JNi-Cu is an order of
magnitude smaller than that of JCu-Cu.12 Our NMR data,
therefore, indicate that the ground state of Ca3Cu2Ni(PO4)4
is a quintet. The behavior of the spin lattice relaxation rate
suggests that replacement of one of the Cu ions by a Ni ion
in the trimer, partially attenuates the relaxation mechanism
attenuated by three-magnon scattering which is the dominant
contribution in the case of Ca3Cu3(PO4)4.
a)Email: kajal.ghoshray@saha.ac.in
1S. Sachdev, Quantum Phase Transition (Cambridge University Press,
New York, 1999).2F. D. M. Haldane, Phys. Rev. Lett. 50, 1153 (1983).3T. Giamarchi, C. Ruegg, and O. Tchenyshyov, Nat. Phys. B 4, 198 (2008).4K. Hida, J. Phys. Soc. Jpn. 63, 2359 (1994).5H. Kageyama, K. Yoshimura, R. Stern, N. V. Mushnikov, K. Onizuka,
M. Kato, K. Kosuge, C. P. Slichter, T. Goto, and Y. Ueda, Phys. Rev. Lett.
82, 3168 (1999).6T. Ono, H. Tanaka, H.A. Katori, F. Ishikawa, H. Mitamura, and T. Goto,
Phys. Rev. 67, 104431 (2003).7M. Azuma, T. Odaka, M. Takano, D. A. Vander Griend, K. R. Poeppelme-
ier, Y. Narumi, K. Kindo, Y. Mizuno, and S. Maekawa, Phys. Rev. B 62,
R3588 (2000).8M. Drillon, M. Belaiche, P. Legoll, J. Aride, A. Boukhari, and A. Moqine,
J. Magn. Magn. Mater. 128, 83 (1993).9A. A. Belik, A. Matsuo, M. Azuma, K. Kindo, and M. Takano, J. Solid
State Chem. 178, 709 (2005).10M. Azuma, Z. Hori, M. Takano, K. Ishida, and Y. Kitaoka, Phys. Rev.
Lett. 73, 3463 (1994).11H. Kageyama, M. Nishi, N. Aso, K. Onizuka, T. Yosihama, K. Nukui,
K. Kodama, K. Kakurai, and Y. Ueda, Phys. Rev. Lett. 84, 5876 (2000).
FIG. 6. The nuclear magnetization recovery curves at 4 and 6.5 K. The inset
shows the same at 12 and 6.5 K.
TABLE 2. Values of T1 at room temperature for two compounds.
Parameters, ms Ca3Cu2Ni(PO4)4 Ca3CuNi2(PO4)4
Ttheo11 for P1 0.69 1.61
Texp11 for P1 0.85 1.82
Ttheo11 for P2 5.94
Texp11 for P2 2.0 3.2
Low Temp. Phys. 38 (7), July 2012 M. Ghosh and K. Ghoshray 649
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Wed, 03 Sep 2014 09:45:23
12A. Podlesnyak, V. Pomjakushin, E. Pomjakushina, K. Conder, and A. Fur-
rer, Phys. Rev. B 76, 064420 (2007).13V. Yu. Pomjakushin, A. Furrer, D. V. Sheptyakov, E. V. Pomjakushina,
and K. Conder, Phys. Rev. B 76, 174433 (2007).14M. Ghosh, M. Majumder, K. Ghoshray, and S. Banerjee, Phys. Rev. B 81,
094401 (2010).15S. Yamamoto, H. Hori, Y. Furukawa, Y. Nishisaka, Y. Sumida, K.
Yamada, K. Kumagai, T. Asano, and Y. Inagaki, J. Phys. Soc. Jpn. 75,
074703 (2006).
16M. Ghosh, K. Ghoshray, B. Pahari, R. Sarkar, and A. Ghoshray, J. Phys.
Chem. Solids 68, 2183 (2007).17M. Ghosh, K. Ghoshray, M. Majumder, B. Bandyopadhyay, and A. Gho-
shray, Phys. Rev. B 81, 064409 (2010).18T. Moriya, Prog. Theor. Phys. 16, 23 (1956).
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