7802 | J. Mater. Chem. C, 2015, 3, 7802--7812 This journal is©The Royal Society of Chemistry 2015

Cite this: J.Mater. Chem. C, 2015,

3, 7802

Water effect on the spin-transition behavior of
Fe(II) 1,2,4-triazole 1D chains embedded in pores
of MCM-41†

Tian Zhao,a Laure Cuignet,ab Marinela Maria Dı̂rtu,b Mariusz Wolff,b

Vojislav Spasojevic,c Ishtvan Boldog,a Aurelian Rotaru,d Yann Garcia*b and
Christoph Janiak*a

The spin-crossover (SCO) compounds [Fe(Htrz)3](BF4)2�H2O (SCO-1) and [Fe(Htrz)2trz]BF4 (SCO-2) (Htrz = 1,2,4-

triazole) were embedded in the pores of mesostructured silica MCM-41 to yield SCO@MCM composites as

evidenced by electron microscopy, gas sorption studies, powder X-ray diffractometry, atomic absorption and

infrared spectrometry. Studies of the temperature-induced spin crossover behavior of the composites by

temperature-variable 57Fe Mössbauer spectroscopy, magnetic and differential scanning calorimetry measurements

and optical reflectivity indicate that the spin transition of the composites was significantly shifted for SCO-1@MCM

to higher temperature in comparison to bulk SCO-1 compounds while the shift for SCO-2 was negligible. These

shifts in the transition temperature for SCO-1@MCM [versus bulk SCO-1] amounted to Tmc = 371/376 K [282/291 K]

and Tkc = 340/345 K [276/286 K] (magnetic/optical reflectivity data) with a broadening of the hysteresis by 25–26 K

relative to bulk SCO-1 (varying slightly with the used method). The significant difference in the SCO behavior of

the similar materials SCO-1 and SCO-2 when embedded in the MCM-41 matrix is assigned to the hydration of the

SCO-1@MCM material. Water is apparently crucial in transmitting the confinement pressure or matrix effect on the

spin transition when the SCO compound is embedded between the pore walls.

Introduction

The spin crossover (SCO) phenomenon is the switching of a transi-
tion metal complex between two different stable ground states: the
low-spin (LS) and the high-spin (HS) states.1,2 The switching between
these two states may be invoked by different external stimuli such as
light, temperature or pressure.3–5 Iron(II) SCO complexes typically
based on N-donor azole/azolate or azine ligands not only lead to a
change in magnetic moment but usually give rise to optical transi-
tions from purple in the LS state (lower temperature) to off-white in
the HS state when increasing the temperature (cf. Fig. 1).6,7 One
interesting aspect in this area concerns the case of SCO hybrid
materials where a given complex can feel the constraint of a
given matrix which is equivalent to the application of additional
pressure.8–10 Several SCO nanoparticles based on Fe(II) complexes

were prepared and embedded in matrices, such as SiO2,11 Ni,12 and
CsFe[Cr(CN)6], to name a few.13 Another manifestation of indirect
pressure effects could also be found in SCO nanoparticles for which
theoretical descriptions were recently proposed.14,15

In this work, two iron(II) SCO compounds were embedded in
mesostructured silica MCM-41. The selected materials are the
1D coordination polymers [Fe(Htrz)3](BF4)2�H2O (SCO-1) and
[Fe(Htrz)2trz]BF4 (SCO-2) with Htrz = 4H-1,2,4-triazole and trz =
1,2,4-triazolato (Scheme 1).16–18 Both are known to exhibit a
hysteretic SCO behavior with sharp spin transition (ST) above
room temperature. SCO-2 which displays a reproducible hysteresis
loop of Tm

c = 385 K and Tk
c = 345 K17 has been selected for

numerous studies, because it does not contain any water molecules
which can give rise to unstable hysteresis loops due to solvent
release. In particular, hybrid materials including SCO-2 were
recently prepared with a mesoporous silica monolith,19 graphene,20

and with silica–gold nanocomposites.21 Yet, the matrix effect with
MCM-41 has not been investigated although this material is well
known for its potential to accommodate various sorts of guests.22

The MCM-41 matrix effect, that is, the change in SCO behavior
under the constraints of surrounding silicate walls has been studied
herein by temperature-variable 57Fe Mössbauer spectroscopy,
differential scanning calorimetry, magnetic measurements and
optical reflectivity.

a Institut für Anorganische Chemie und Strukturchemie, Universität Düsseldorf,

Universitätsstr. 1, 40225 Düsseldorf, Germany. E-mail: janiak@uni-duesseldorf.de
b Institute of Condensed Matter and Nanosciences, Molecules, Solids and Reactivity

(IMCN/MOST), Université Catholique de Louvain, Place L. Pasteur 1,

1348 Louvain-la-Neuve, Belgium. E-mail: yann.garcia@uclouvain.be
c Institute for Nuclear Sciences, P. O. Box 522, 11001 Beograd, Serbia
d Department of Electrical Engineering and Computer Science & AMNOL,

Stefan cel Mare University, 720229 Suceava, Romania

† Electronic supplementary information (ESI) available. See DOI: 10.1039/c5tc00311c

Received 31st January 2015,
Accepted 8th March 2015

DOI: 10.1039/c5tc00311c

www.rsc.org/MaterialsC

Journal of
Materials Chemistry C

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Results and discussion
Synthesis

Fe(II) 1,2,4-triazole compounds were embedded in MCM-41 host
matrices by first impregnating the MCM-41 material with an
alcoholic solution of the 1,2,4-triazole ligand over a time of at
least 12 h. Then an alcoholic or an aqueous solution of the
appropriate amount of the iron(II) salt Fe(BF4)2�6H2O, was added

to form the composite SCO@MCM materials (eqn (1) and (2),
respectively). For the subsequent investigations it was crucial
to have the SCO material only inside the cylindrical pores of
MCM-41. So, careful washing with water was done to remove
any SCO precipitate outside of the pores. Both compounds
SCO-1 and -2 readily dissolve in water with plausible fragmen-
tation of the 1D chains (according to ref. 17 SCO-2 dissolves
with decomposition) (Scheme 2).

The IR spectra of the composite materials SCO@MCM com-
pared to the IR spectra of bulk SCO and MCM-41 show the
presence of both components in the composite (Fig. 2).

Scheme 2 Preparation of SCO hybrid materials used in this work.

Fig. 1 Photographs showing the color change from LS (room temperature)
to HS (B100 1C) for each sample.

Scheme 1 Schematic drawings of 1D SCO materials to be inserted into
MCM-41.

Fig. 2 IR spectra of SCO@MCM samples (black) in comparison to bulk
SCO (red) and MCM-41 (blue).

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7804 | J. Mater. Chem. C, 2015, 3, 7802--7812 This journal is©The Royal Society of Chemistry 2015

The SCO amount in the composite was calculated from the
iron analysis by atomic absorption spectroscopy to be 56.4 wt%
for SCO-1@MCM and 43.8 wt% for SCO-2@MCM (see Table 3
for details).

Matching powder X-ray diffractograms (PXRD, Fig. 3) of bulk
SCO and the SCO@MCM materials confirm the identity of the
SCO materials formed in bulk and as a SCO@MCM composite
for SCO-1 and SCO-2.

Porosity measurements

IR spectroscopy, elemental analysis and PXRD cannot distin-
guish between bulk and embedded SCO material and, hence,
do not prove the presence of SCO inside the pores of MCM.
However, with the pores of MCM filled by the SCO compound
the porosity should decrease. The remaining porosity of the
SCO@MCM composite materials was analyzed by N2 sorption
studies at 77 K (Fig. 4). The sample was degassed in vacuum
before measurement at a temperature of 393 K for 2 h. In the
composite materials the Brunauer–Emmett–Teller (BET) and
Langmuir surface areas for SCO-1 have decreased considerably
to less than 25% of the value found in MCM-41 (Table 1).

The adsorption isotherm of SCO-1@MCM is of type-IV, which
is typical for many mesoporous adsorbents,23–25 with an H2
hysteresis loop which may be associated with pores with narrow
necks and wide bodies (‘‘bottle-neck’’ pores).26 Such pore struc-
tures can result from the formation of SCO-1 microcrystals inside
the MCM mesopores. The N2 sorption isotherm for MCM-41 with

its S-shape matches the literature reports.27–30 In summary, the
decrease of surface area and porosity is a good indication that the
MCM-41 matrix was filled by SCO materials as intended.

No observable surface area was found by N2 sorption for
SCO-2@MCM. However, at the cryogenic temperature of 77 K
diffusion of N2 molecules into micropores is very slow. Diffusion
limitations at this temperature influences adsorption in ultramicro-
pores (pores smaller than 7 Å).31 For porous materials which usually
contain a wide range of pore sizes including ultramicropores, this
would require time-consuming N2 adsorption measurements and

Fig. 3 Powder X-ray diffractograms of bulk SCO complexes, and
SCO@MCM composite materials (background corrected). The MCM host
matrix is amorphous.

Fig. 4 N2 sorption isotherms of MCM-41 and SCO@MCM samples; closed
and open symbols refer to adsorption and desorption, respectively.

Table 1 Porosity data for SCO@MCM from N2 isotherms at 77 K

Composite
SBET

a

(m2 g�1)

SLang
b

(m2

g�1)
V0.1

c

(cm3 g�1)
Vtot

d

(cm3 g�1)
V0.1/
Vtot

Vmicro

(CO2)e

(cm3 g�1)

MCM-41 857 1238 0.297 0.82 0.36 0.0175
SCO-1@MCM 70 104 0.0222 0.235 0.09 0.002
SCO-2@MCM 0 0 n.a. n.a. n.a. 0.002

a BET surface area calculated at 0.05 o p/p0 o 0.2 from N2 sorption
isotherm at 77 K with a standard deviation of �50 m2 g�1. b Langmuir
surface area over the pressure range 0–110 Torr. c Micropore volume
calculated from N2 adsorption isotherm at p/p0 = 0.1 for pores with
d r 2 nm (20 Å). d Calculated from N2 sorption isotherm at 77 K ( p/p0 =
0.95) for pores r20 nm. e Pore volume for pores with d r 1 nm (10 Å,
cf. Fig. S3, ESI) from the CO2 NL-DFT model at 273 K.

Table 2 Summary of transition temperatures (Tc in K)

Material

57Fe
Mössbauer Magnetic

Optical
reflect.

DS
calorimetry

Ref.Tm
c Tk

c Tm
c Tk

c Tm
c Tk

c Tm
c Tk

c

Bulk SCO-1 n.a.a n.a.a 345b 323b 336b 323b 17
282c 276c 291c 286c

SCO-1@MCM 330 310 389d 340d 394d 345d This work
371e 340e 376e 345e

Bulk SCO-2 380 344 385 345 383g 343g 17
373 f 343 f 387h 343h This work

SCO-2@MCM 342 328 381 346 385 351 390h 355h This work

a n.a. = not available. b Hydrated material, [Fe(Htrz)3](BF4)2�H2O.
c Dehydrated material. d First heating and cooling cycle on hydrated
material. e Second to fourth cycle on dehydrated material. f Optical reflec-
tance measurements were recorded in this work on SCO-2 prepared as
nanoparticles in the liquid state according to ref. 40. g At 7 K min�1.
h At 10 K min�1.

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This journal is©The Royal Society of Chemistry 2015 J. Mater. Chem. C, 2015, 3, 7802--7812 | 7805

may still lead to under-equilibration of the adsorption isotherms,
hence, will give erroneous results of the pore volume and pore
size distribution analysis. Problems of this type can be eliminated
by using CO2 adsorption analysis at 273 K.32 The saturation
pressure of CO2 at 0 1C is very high (B26 141 Torr), therefore
low relative pressure measurements necessary for micropore
analysis are achieved in the range of moderate absolute pressures
(1–760 Torr).33 At 273 K and under higher absolute pressures CO2

molecules can more easily access ultramicropores than N2 at
B77 K and the kinetic diameter of CO2 (3.3 Å) is also slightly
smaller than for N2 (3.64 Å). CO2 micropore analysis at 273 K
versus N2 analysis at 77 K is advantageous because of (i) faster
analysis and (ii) greater confidence that measured adsorption
points are equilibrated (both due to higher diffusion rates) and
(iii) extension of the range of analysis to pores of smaller sizes
that are accessible to CO2 molecules but not to N2.34

CO2 sorption at 273 K shows that SCO-2@MCM has compar-
able porosity to SCO-1@MCM (Fig. S2 in ESI†). This indicates
that pores or pore mouths of SCO-2@MCM are narrower than
that of SCO-1@MCM. Thus, from CO2 adsorption isotherms at
273 K (Fig. S2, ESI†), the pore size distribution (PSD) for
SCO@MCM was derived between 4–10 Å by using nonlocal
density functional theory (NLDFT) with a ‘‘slit-pore model’’
(Fig. S3, ESI†). CO2 adsorption with the NLDFT model yields
a better resolved PSD towards the ultramicropore end than
from N2 adsorption isotherms for SCO-1@MCM (Fig. S3 to S5 in
ESI†). Here the two SCO@MCM materials give very similar pore
size distributions for pores below 10 Å (1 nm).

Electron microscopy

Scanning electron microscopy (SEM) images (Fig. 5) show a
morphology of the SCO@MCM composite materials which is
similar to native MCM. No characteristic SCO crystallites can be
seen. This supports the formation of SCO inside the MCM
mesopores and verifies the removal of any SCO formed outside
through the washing procedures.

Transmission electron microscopy (TEM) images reveal the
formation of nanocrystals of SCO-1 and -2 inside the MCM
matrix (Fig. 6). The dark spots which are B2 nm in diameter
contain iron and at high resolution (5 nm gauge bar, Fig. 6b
and d) it is visible that these dark spots consist of lattices planes
which are indicative of crystalline material. The crystallinity of
the SCO materials inside MCM is in agreement with the observa-
tion of PXRD patterns for the SCO@MCM composites (see Fig. 3).

Spin transition behavior

In this work, the ST behavior of the composites was investigated
and compared to those of the guest materials using the same set
of physical techniques. Such a careful comparison is important

because of the diversity of techniques presented which can
provide a different set of transition temperatures. The estab-
lished SCO research practices foresee the use of several methods
of investigation in order to cover the spread of ST parameters as
found by different techniques. Bulk techniques: Mössbauer

Table 3 AAS analysis results (Fe content)a

Sample Fe content (wt%) SCO content (wt%)

SCO-1@MCM 7.21 56.4
SCO-2@MCM 7.01 43.8

a See Tables S2–S4 in ESI for details.

Fig. 5 SEM images of (a) MCM-41, (b) SCO-1, (c) SCO-1@MCM, (d) SCO-2
and (e) SCO-2@MCM.

Fig. 6 TEM images of SCO-1@MCM (a, b) and SCO-2@MCM (c, d) at
different magnifications.

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7806 | J. Mater. Chem. C, 2015, 3, 7802--7812 This journal is©The Royal Society of Chemistry 2015

measurements (run in static mode with long acquisition times)
and DC magnetic measurements (in settle mode) and a surface
technique: optical reflectivity (in scanning mode). Mössbauer
spectroscopy is the only method which provides a careful
evaluation of the spin population given that by reflectivity, only
the surface of the sample is probed.

57Fe Mössbauer studies

SCO-1@MCM was investigated over the temperature range
78–358 K, first at 78 K and then on warming up to 358 K
followed by a cooling cycle to 298 K. The associated Mössbauer
parameters are gathered in Table 4. At 78 K, the spectrum of
SCO-1@MCM consists of one quadrupole doublet, with an
isomer shift of dLS = 0.43(1) mm s�1 and a quadrupole splitting
of DELS

Q = 0.26(2) mm s�1 characteristic for the LS state of iron(II)
ions (Table 4). The composite remains in the LS state on warming

up to 328 K (Fig. 7), showing no influence of the matrix on the
spin state. SCO-1 was only partly investigated by Lavrenova et al.
by Mössbauer spectroscopy.16 Nevertheless, the isomer shift dLS of
SCO-1@MCM at room temperature nicely corresponds to the one
reported for SCO-1 (d = 0.43 mm s�1),16 indicating that the
coordination polymer structure is not affected by the matrix
environment, i.e., the 1D chain is not located nearby the walls of
the MCM-41. No decomposition of the sample is noticed within
the composite as seen by the absence of oxidation products, which
was however clearly observed when studying a less stable deriva-
tive, [Fe(NH2trz)3](NO3)2 (NH2trz = 4-amino-1,2,4-triazole) within
the same matrix. The latter material was synthesized and pro-
cessed similarly to SCO-1,2@MCM. On warming to 333 K, a major
signal is detected for the SCO-1@MCM composite with larger
parameters (dHS = 0.97(1) mm s�1 and DEHS

Q = 2.30(1) mm s�1)
which are characteristic for the HS state of iron(II) ions (Fig. 7). The
major signal is present in 80% population compared to the LS
state. On warming further to 358 K, this population grows up to
87% indicating an incomplete spin transition. An asymmetric
quadrupole doublet is noticed for the HS state at this temperature
which is attributed to a texture effect. On cooling, a slight decrease
of the HS population is observed down to 318 K after which a
sharp transition to the LS state is observed. Interestingly, the ST is
also incomplete at room temperature with 5% of ions remaining
in the HS state. The temperature dependence of the HS molar
fraction assuming equal Debye–Waller factors for HS and LS
states, which is justified taking into account the sharpness of
the ST,35 is shown in Fig. 8. A hysteresis loop of 20 K width is
delineated with transition temperatures Tm

c = 330 K and Tk
c = 310 K.

The ST is not complete in both HS and LS states.
SCO-2@MCM was investigated over the range 78–358 K by

Mössbauer spectroscopy, first at 78 K and then on warming

Table 4 Overview of 57Fe Mössbauer parameters for SCO-1@MCMa

T [K]
d
[mm s�1]

DEQ

[mm s�1]
G/2
[mm s�1]

Relative
area [%] Sites

78 0.43(1) 0.26(2) 0.13(1) 100 LS
298m 0.42(1) 0.26(1) 0.15(1) 100 LS
303m 0.41(1) 0.26(1) 0.16(1) 100 LS
308m 0.40(1) 0.26(1) 0.16(1) 100 LS
313m 0.40(1) 0.26(1) 0.16(1) 100 LS
318m 0.39(1) 0.25(1) 0.17(1) 100 LS
323m 0.38(1) 0.26(1) 0.17(1) 100 LS
328m 0.38(1) 0.26(1) 0.18(1) 100 LS
333m 0.97(1) 2.30(1) 0.13(1) 80.0 HS

0.46(1) 0.28(1) 0.29(1) 20.0 LS
338m 0.96(1) 2.25(1) 0.13(1) 83.0 HS

0.45(1) 0.28(1) 0.26(1) 17.0 LS
343m 0.95(1) 2.21(1) 0.13(1) 83.0 HS

0.45(1) 0.34(1) 0.31b 17.0 LS
348m 0.94(1) 2.18(1) 0.14(1) 85.0 HS

0.44(1) 0.34b 0.31b 15.0 LS
353m 0.93(1) 2.15(1) 0.13(1) 87.0 HS

0.43b 0.36(2) 0.28(1) 13.0 LS
358 0.93(1) 2.10(1) 0.13(1) 87.0 HS

0.43(1) 0.38b 0.26b 13.0 LS
353k 0.94(1) 2.14(1) 0.14(1) 87.0 HS

0.43(1) 0.35b 0.32(1) 13.0 LS
348k 0.94(1) 2.13(1) 0.14(1) 87.0 HS

0.44(1) 0.38(1) 0.33(1) 13.0 LS
343k 0.95(1) 2.21(1) 0.13(1) 83.0 HS

0.45b 0.34b 0.34(1) 17.0 LS
338k 0.96(1) 2.25(1) 0.14(1) 83.0 HS

0.45(1) 0.32b 0.46(1) 17.0 LS
333k 0.97(1) 2.29(1) 0.16(1) 82.0 HS

0.46(1) 0.35b 0.44(1) 18.0 LS
328k 0.98(1) 2.32(1) 0.14(1) 82.0 HS

0.47(1) 0.30b 0.45(1) 18.0 LS
318k 0.99(1) 2.39(1) 0.14(1) 81.0 HS

0.49(1) 0.35b 0.31(1) 19.0 LS
313k 0.99(1) 2.42(1) 0.14(1) 75.0 HS

0.54(1) 0.47(1) 0.26(1) 25.0 LS
308k 0.99(1) 2.42(1) 0.15(1) 5.0 HS

0.50(1) 0.31(1) 0.16(1) 95.0 LS
303k 0.99(1) 2.40(1) 0.14(1) 5.0 HS

0.50(1) 0.30(1) 0.16(1) 95.0 LS
298k 1.07(1) 2.63(1) 0.16(1) 5.0 HS

0.49(1) 0.30(1) 0.16(1) 95.0 LS

a m indicates warming and k indicates cooling; d = isomer shift relative to
a-iron, DEQ = quadrupole splitting, G/2 = half width at half maximum.
b Fixed parameter.

Fig. 7 Selected 57Fe Mössbauer spectra of SCO-1@MCM; blue and red
colors correspond to LS and HS doublets, respectively.

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up to 358 K followed by a cooling cycle to 298 K. The spectrum
at 78 K shows one quadrupole doublet attributed to LS FeII ions
(dLS = 0.42(1) mm s�1 and DELS

Q = 0.23(1) mm s�1) (Fig. 9). At
room temperature, the hyperfine parameters of the LS state
(Table 5) are in exact agreement with the ones of the pure
material with (dLS = 0.43(1) mm s�1 and DELS

Q = 0.29(1) mm s�1),17

thus indicating that the inclusion of [Fe(Htrz)2trz]BF4 in the
MCM matrix neither changed its microstructure nor resulted in
an oxidation. However, the spin state population is modified
because 11% of HS ions detected at room temperature for SCO-2
are now switched to the LS state in the composite. Usually, this
fraction of HS ions in the LS state is attributed to chain ends, i.e.,
the formation of short chains which end with a few percent of
remaining water molecules.36 Thus the coordination polymeriza-
tion would tend to proceed completely within the matrix. Another
explanation could be that the remaining paramagnetic Fe spins
having a FeN6 environment within the matrix would switch to the
LS state due to a local pressure effect caused by the matrix. In
both cases, a matrix influence is therefore identified. On warming
up to 338 K, the composite remains in the LS state where a
second doublet attributed to HS FeII ions grows slightly in
intensity (7%), dHS = 0.98(1) mm s�1 and DEHS

Q = 2.53(1) mm s�1

(Fig. 9). This behavior indicates the onset of a SCO behavior,
a spin situation which differs from the pure material which only
switches below 380 K,17 confirming a matrix influence on the spin
state. On warming further, the HS signal (dHS = 0.95(1) mm s�1

and DEHS
Q = 2.21(1) mm s�1) increases, revealing an asymmetric

character, to reach 85% at 358 K. Worthwhile to note that the
fraction of LS ions in the HS state is dramatically increased in the
composite (Table 5) compared to the 3% detected in the pure
material.17 On cooling, a hysteresis behavior is detected for the
composite as seen in Fig. 9. The temperature dependence of the
HS molar fraction shown in Fig. 8 allows to determine the width
of the hysteresis loop DT = 14 K as well as the transition
temperatures (Tm

c = 342 K and Tk
c = 328 K) which differ from the

ones of the pure material (Tm
c = 380 K and Tk

c = 344 K) recorded by
Mössbauer spectroscopy.17 Thus the hysteresis width is consider-
ably reduced compared to the genuine material. In addition, the
sharpness of the ST is also affected indicating a loss of coopera-
tivity, and the hysteresis loop is shifted downwards.

DC magnetic measurements

The magnetic properties of both composite materials are pre-
sented for comparison in Fig. 10. For SCO-1@MCM, the first
cycle, from 200 K to 400 K, followed by a cooling to 200 K,
reveals an abrupt hysteresis loop as large as 49 K, with Tm

c =
389 K and Tk

c = 340 K. This hysteresis is not stable, due to the
expected water release on warming. Therefore, for the second
cycle, the hysteresis falls down to 31 K and is fully reversible,
with Tm

c = 371 K and Tk
c = 340 K. Compared to the magnetic data

recorded on the pure material in the crystalline state, a clear

Fig. 8 Temperature dependence of the HS molar fraction (gHS) deduced
from 57Fe Mössbauer spectroscopy over the temperature range 298–360 K
for SCO-1@MCM (top) and for SCO-2@MCM (bottom).

Fig. 9 Selected 57Fe Mössbauer spectra of SCO-2@MCM; red and blue
colors correspond to HS and LS doublets, respectively.

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shift of the ST upwards is observed. Indeed, [Fe(Htrz)3](BF4)2�
H2O (SCO-1) displays a sharp ST at Tm

c = 345 K and Tk
c =

323 K while a lower hysteresis width is obtained for the
dehydrated material with Tm

c = 282 K and Tk
c = 276 K.17

The transition temperatures recorded for the Mössbauer
studies of SCO-1@MCM show a hysteresis loop shifted down-
wards compared to SCO-1@MCM recorded by DC magnetic
measurements which is expected due the time necessary to
record each Mössbauer spectrum (one or two days in air atmo-
sphere) which is enough to slowly partially dehydrate the material.
As a result the hysteresis loop width by Mössbauer studies
decreases to 20 K, with transition temperatures Tm

c = 330 K and
Tk

c = 310 K (Fig. 8).
The SCO-2@MCM nanocomposite shows a fully reversible

hysteresis loop of width 35 K, with Tm
c = 381 K and Tk

c = 346 K.
Compared to the magnetic properties of the pure material,
a slight shift downwards of the ST curve along with an
hysteresis width decrease is noticed (bulk SCO-2: Tm

c = 385 K
and Tk

c = 345 K).17

This result is consistent with theoretical predictions about a
hysteresis reduction with particle size lowering.37 The shift was
more pronounced for the ST of nanoparticles of SCO-2 coated
with gold recorded by DC magnetic measurements with Tm

c =
373 K and Tk

c = 344 K.38,39 These two results however contradict

earlier literature reports which indicate that the ST properties of
this material are not modified when prepared as nanoparticles.40

Optical reflectivity measurements

The SCO of iron(II) complexes with azole-based ligands is
usually accompanied by a color change from purple in the LS
state (lower temperature) to white in the HS state (higher
temperature) (cf. Fig. 1).7 Hence, the change in spin state can
also be followed by optical reflectance measurements in the solid
state.41,42 The spin transitions of the SCO@MCM composites
were studied optically under a nitrogen atmosphere to exclude
any potential oxidation of the samples in air. The reflectance
measurements were carried out using an optical disk cryostat
mounted on the stage of a fluorescence microscope linked to a
CCD camera. Before each set of measurements, the cryostat was
purged for 2 h at 10 1C.

The first cycle recorded on SCO-1@MCM reveals an abrupt
transition upon heating and cooling with a hysteresis as large
as 49 K (black curve in Fig. 11). However, the hysteresis loop is
reduced to 31 K in the next cycles (blue and red curves in
Fig. 11), most presumably due to dehydration. These results
are consistent with literature data reporting a large hysteresis
loop for the hydrated SCO-1 phase (Tm

c = 336 K and Tk
c = 323 K)

and a narrow one for the dehydrated phase, (Tm
c = 291 K and

Tk
c = 286 K).17 For the SCO-1@MCM material, a hydration/

dehydration phenomenon was observed in this work (see also
below). However, the phase transitions between the alpha and
beta forms, known for the bulk SCO-1 were not observed.17

Table 5 Overview of 57Fe Mössbauer parameters for SCO-2@MCMa

T [K]
d
[mm s�1]

DEQ

[mm s�1]
G/2
[mm s�1]

Relative
area [%] Sites

78 0.42(1) 0.23(1) 0.18(1) 100 LS
298m 0.43(1) 0.28(1) 0.14(1) 100 LS
303m 0.42(1) 0.29(1) 0.14(1) 100 LS
308m 0.42(1) 0.29(1) 0.14(1) 100 LS
318m 0.42(1) 0.29(1) 0.14(1) 100 LS
323m 0.42(1) 0.29(1) 0.14(1) 100 LS
328m 0.41(1) 0.29(1) 0.14(1) 100 LS
333m 0.40(1) 0.29(1) 0.15(1) 100 LS
338m 0.98(1) 2.53(1) 0.19b 7.0 HS

0.39(1) 0.29(1) 0.15(1) 93.0 LS
343m 0.97(1) 2.29(1) 0.15(1) 47.0 HS

0.39(1) 0.27(1) 0.16(1) 53.0 LS
348m 0.96(1) 2.27(1) 0.14(1) 86.0 HS

0.41(1) 0.29b 0.37(1) 14.0 LS
353m 0.96(1) 2.25(1) 0.15(1) 86.0 HS

0.41(1) 0.28b 0.41(1) 14.0 LS
358m 0.95(1) 2.21(1) 0.14(1) 85.0 HS

0.41(1) 0.28(3) 0.32(2) 14.0 LS
343k 0.97(1) 2.32(1) 0.14(1) 85.0 HS

0.41(1) 0.28b 0.32(1) 14.0 LS
338k 0.97(1) 2.35(1) 0.15(1) 85.0 HS

0.41(1) 0.28b 0.32b 14.0 LS
333k 0.98(1) 2.37(1) 0.14(1) 85.0 HS

0.42(1) 0.30b 0.32b 15.0 LS
328k 0.99(1) 2.41(1) 0.14(1) 41.0 HS

0.40(1) 0.30(1) 0.16(1) 59.0 LS
323k 0.44(1) 0.27(1) 0.11(1) 100 LS
318k 0.42(1) 0.30(1) 0.14(1) 100 LS
313k 0.43(1) 0.29(1) 0.12(1) 100 LS
308k 0.43(1) 0.29(1) 0.13(1) 100 LS
303k 0.41(1) 0.31(1) 0.16(1) 100 LS
298k 0.41(1) 0.31(1) 0.16(1) 100 LS

a m indicates warming and k indicates cooling; d = isomer shift relative
to a-iron, DEQ = quadrupole splitting, G/2 = half width at half max-
imum. b Fixed parameter.

Fig. 10 Temperature-variable magnetic curves for SCO-1@MCM (top)
and SCO-2@MCM (bottom).

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In the previous literature on SCO-117 the hydration/dehydration
might have been ascribed to an alpha/beta phase transition.
Compared to the literature data on optical reflectivity for the free
SCO-1 compound, the transition temperatures for SCO-1@MCM
are shifted upwards with Tm

c = 376 K and Tk
c = 345 K,17 which

suggests a significant matrix effect.
Optical reflectance measurements were recorded here for

the first time on SCO-2 prepared as nanoparticles in the liquid
state thanks to the reverse micelle method.40 A hysteresis loop
with Tm

c = 373 K and Tk
c = 343 K was observed (Fig. 12), which

differs for the transition temperature in the heating mode
compared to previous reflectivity measurements in the bulk
sample (not in a nano-form) in the crystalline state Tm

c = 381 K
and Tk

c = 347 K.17

The SCO-2 compound embedded in the MCM matrix shows
a ST at Tm

c = 385 K and Tk
c = 351 K with a hysteresis of about 35 K

(Fig. 12), hence of the same width as the bulk sample but
slightly shifted upwards. This behavior is different to what was
observed in the case of SCO-1@MCM.

Differential scanning calorimetry measurements

DSC measurements of SCO-2 reveal a sharp endothermic peak
on warming and an exothermic peak on cooling at Tm

max = 387 K

and Tk
c = 343 K, respectively. SCO-2@MCM reveals a similar

pattern with a shift in temperature upwards at Tm
max = 390 K and

Tk
c = 355 K, both at 10 K min�1 (Fig. 13).

Comparison

We attribute the strong matrix effect in SCO-1@MCM to the
compound being embedded between the pore walls with a pres-
sure mediator (see below). The HS state has elongated Fe–ligand
bond lengths (Fe–N E 2.1–2.2 Å) compared to the LS state
(Fe–N E 1.9–2.0 Å) thereby requiring more space. Thus, the
ST has to operate against the higher pressure exerted by the
pore walls of the MCM matrix. In other words, higher external
pressure favors the LS state so that the LS - HS transition
occurs at higher molecular energy level, i.e., temperature.

Table 2 provides a summarizing overview of the spin transi-
tion temperatures for the SCO and SCO@MCM materials from

Fig. 11 Thermal dependence of the normalized optical reflectivity of
SCO-1@MCM at a scan rate of 2 K min�1. The transition temperatures
recorded in warming and cooling modes are indicated.

Fig. 12 Thermal dependence of the normalized optical reflectivity recorded
at 2 K min�1 on both SCO-2@MCM (black curves) and SCO-2 prepared as
nanoparticles (red curves) using the reverse micelle method. The transition
temperatures in the warming and cooling modes are given.

Fig. 13 Heat capacity versus temperature for SCO-2 and SCO-2@MCM
recorded by differential scanning calorimetry at 10 K min�1.

Fig. 14 Thermogravimetric analysis (TGA) shows that SCO-1@MCM pos-
sesses crystal water, whereas SCO-2@MCM nearly does not contain solvent.
Up to 120 1C, 4.36 and 0.95 wt% are lost for SCO-1 and SCO-2@MCM,
respectively. 4.36 wt% correlated to a Fe content of 7.2 wt% correspond
to about 2H2O molecules per SCO-1 formula unit (that is per Fe atom) in
SCO-1@MCM. Further heating shows that the SCO-1@MCM composite
contains more water which is lost above 120 1C.

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the different methods (for the hysteresis value included see
Table S1 in ESI†).

It is worth to notice that, from Mössbauer, DC magnetic and
optical reflectivity measurements, a strong matrix effect is found
only for SCO-1@MCM, whereas the matrix effect for SCO-2@MCM
is much weaker. We trace this to the hydration of SCO-1, which
contains crystal water (Fig. 14) and suggest that water is important
as a ‘‘pressure mediator’’ for delivering the ‘‘hydrostatic pressure’’
to induce a significant matrix effect. However, the specific reasons
of the action of crystal water still need further investigation.
The crystal water in SCO-1@MCM is partly lost upon heating to
127 1C (400 K) (cf. Fig. 14) which explains the shifts from the
first to the second cycle in the warming temperatures (Tm

c ) in
Fig. 10 and 11.

Conclusions

Composite materials made of MCM-41 and of two 1D SCO com-
pounds, namely [Fe(Htrz)3](BF4)2�H2O (SCO-1) and [Fe(Htrz)2trz]BF4

(SCO-2) were successfully prepared in a form of embedded
nanoobjects with 2 nm cross-section. Although, as concluded
from the 57Fe Mössbauer spectroscopy, the 1D chain is sepa-
rated from the walls of the host matrix, a pressure effect was
identified for SCO-1@MCM by temperature-variable magnetic
and optical reflectance measurements, causing the spin transi-
tion to be shifted to higher temperatures, compared to the bulk
material. For SCO-1@MCM the LS - HS transition (Tm

c ) was
increased by 44–58 K and the HS - LS transition (Tk

c ) by
17–22 K in comparison to bulk SCO-1 during the first warming-
cooling cycle. During the first warming to about 400 K partial
dehydration occurs. For the partially dehydrated SCO-1@MCM
material this shift was even more pronounced with Tm

c increased
by 85–89 K and Tk

c increased by 59–64 K relative to bulk SCO-1.

The range given reflects the values from two different methods
(temperature-variable magnetic and optical reflectance measure-
ments). Also, the hysteresis between Tm

c and Tk
c increases by

26–33 K when placing SCO-1 into the MCM-41 matrix (Table S1
in ESI†). In the case of SCO-2@MCM this pressure or matrix
effect only becomes evident upon comparison to a nanoSCO-2
reference material which was done by the optical reflectance
measurements. The significant difference in matrix effect on
the SCO behavior of the similar materials SCO-1 and SCO-2
is traced to the hydration of the SCO-1 and SCO-1@MCM
material. This hydration is only partially lost during the first
heating cycle which is additional evidence to the change of
transition parameters and the role of water. Water is apparently
crucial in exerting a confinement pressure or matrix effect on
the spin transition (Fig. 15).

Experimental section
Materials

Iron(II) tetrafluoroborate hexahydrate (Fe(BF4)2�6H2O, Aldrich),
1,2,4-4H-triazole (99%, Alfa Aesar), and mesostructured silica
(MCM-41 type, Aldrich; unit cell size: 4.5–4.8 nm; 0.98 cm3 g�1 pore
volume; 2.1–2.7 nm pore size; BET surface area B 1000 m2 g�1)
were used as received without further purification.

Instrumentation

Powder X-ray diffractograms. Powder X-ray diffractograms
were acquired at ambient temperature on a Bruker D2 Phaser
using a flat low background sample holder and Cu-Ka radiation
(l = 1.54182 Å) at 30 kV covering 2 theta angles 5–801 over a
time of 2 h, that is 0.011 s�1.

Nitrogen adsorption isotherms. Nitrogen adsorption isotherms
were acquired on a Quantachrome Novas, with 2 h degassing at a
temperature of 120 1C in vacuum prior to each measurement.

CO2 sorption isotherms. CO2 sorption isotherms were measured
using a Micromeritics ASAP 2020 automatic gas sorption analyzer
at 0 1C, with 4 h degassing at a temperature of 120 1C in vacuum
prior to each measurement.

Thermogravimetric analysis (TGA). Thermogravimetric analysis
(TGA) was measured on a Netzsch TG 209 F3 at 5 1C min�1 heating
rate using aluminum sample holders and nitrogen as carrier gas.

FT-IR measurements. FT-IR measurements were carried out on
a Bruker TENSOR 37 IR spectrometer at ambient temperature in
the range of 4000 to 500 cm�1 with an ATR unit (Platinum ATR-QL,
Diamond).

Synthesis of SCO@MCM and SCO materials

Bulk SCO-1 and SCO-2 was synthesized according to ref. 17;
see in ESI† for the analytical data. Nanoparticles of SCO-2 for
optical reflectivity measurements were prepared as a purple
solution following a procedure described in ref. 40, see in ESI†
for the analytical data.

SCO-1@MCM. 1,2,4-4H-Triazole (208 mg, 3.0 mmol) and
MCM-41 (100 mg) were stirred in 100 mL of methanol for 12 h.
A solution of 337.5 mg (1.0 mmol) of Fe(BF4)2�6H2O in 60 mL of

Fig. 15 Schematic presentation of the confinement pressure on the
SCO-1 material mediated by water.

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methanol was added to the slurry and the solvent was removed
rapidly at 70 1C using a rotary evaporator. The formed product
was collected and thoroughly washed with water 3 times and
10 mL each. The product was dried in an evacuated desiccator
over silica gel. Yield B253 mg of a red-pink powder.

SCO-2@MCM. To a solution of 416 mg (6.0 mmol) of 1,2,4-
4H-triazole in 2 mL ethanol, 100 mg of MCM-41 powder was added
and the slurry was stirred for 12 h. The formed suspension was
transferred to a solution of 675 mg (2.0 mmol) of Fe(BF4)2s�6H2O in
4 mL of water and the mixture was stirred for 24 h at room
temperature. The solid product was filtered, washed with ethanol
and water for three times (10 mL each), and dried in an evacuated
desiccator over silica gel. Yield B235 mg of a light-pink powder.

Washing procedure. Any SCO precipitate, which formed on the
outer MCM surface, was removed by washing procedures. SCO-1@
MCM was washed three times with water because SCO-1 is very
easy dissolved in water.

For SCO-2@MCM, the solid product was first placed in a
beaker, stirred for 2 h with water and separated by centrifugation.
This step was repeated 3 times. Then the solvent was changed to
ethanol, stirred for 2 h again and centrifuged. The ethanol washing
was repeated until no pink color appeared in the supernatant.

Atomic absorption spectrometry (AAS). Atomic absorption
spectrometry (AAS) was used to measure the iron content. A few
carefully weighted milligrams of each sample were completely
dissolved in 2 mL HNO3 (65%) solution. These solutions were
transferred into 20 mL volumetric flasks. The iron content of
each sample was determined by comparison to standard solution
(Table 3).

Mössbauer studies
57Fe Mössbauer spectra were recorded in transmission geometry
using a Wissel spectrometer, equipped with a 57Co(Rh) source from
Cyclotron Ltd and fitted to an Oxford Instruments bath cryostat for
low temperature measurements. Samples were inserted into
aluminium foils for the low temperature measurements.
Measurements above room temperature were carried out with
a Wissel Furnace MBF-1100. The sample was fixed between two
round plates of B4C, made of heat- and corrosion-resistant steel
with high nickel content. The sample holder and heat screens
were positioned in quartz tubes in air atmosphere. Spectra were
fitted to a sum of Lorentzian line shapes by least-squares refine-
ment using Recoil 1.05 Mössbauer Analysis Software.43

Magnetic measurements

DC magnetic measurements were performed by using a Quantum
Design MPMS XL-5 SQUID magnetometer. For both samples,
magnetization measurements were carried out in a magnetic field
of 1000 Oe, starting from 200 K up to 400 K (heating), and then
cooling back to 200 K. No attempt was made to evaluate the molar
magnetic susceptibility.

Optical reflectance measurements

Thermal dependence of the optical reflectance has been carried
out at 2 K min�1, with a Linkam optical cryostat mounted on

the stage of an Olympus BX51 fluorescence microscope linked to
a CCD camera. Data were treated using ImageJ software (Wayne
Rasband, National Institute of Mental Health, Bethesda,
Maryland, USA).

Differential scanning calorimetry measurements

DSC were carried out in a He(g) atmosphere using a Perkin-Elmer
DSC Pyris 1 instrument equipped with a cryostat and operating
down to 98 K. Aluminum capsules were loaded with 20–50 mg of
sample and sealed. The heating and cooling rates were fixed at
10 K min�1. Temperatures and enthalpies were calibrated over the
temperature range of interest (298–400 K) using the solid–liquid
transitions of pure indium (99.99%)44 over the range 78–298 K.

Acknowledgements

We acknowledge financial support from the Fonds National de la
Recherche Scientifique (FNRS) (FRFC 2.4537.12), Walloon region
(MELMINK), Romanian National Authority for Scientific Research,
CNCS – UEFISCDI, (project number PN-II-RU-TE-2011-3-0307),
Romanian Academy – WBI and DG06 (MEMLINK). T. Z. thanks
the China Scholarship Council (CSC) for a doctoral fellowship
and I. B. thanks the Alexander von Humboldt foundation for a
postdoctoral fellowship. We also acknowledge the COST actions
MP1202 and CM1305, and thank the Fonds pour la Formation à
la Recherche dans l’ Industrie et dans l’ Agriculture for scholar-
ship allocated to L. C. M., and the Fonds National de la Recherche
Scientifique for a chargé de recherches position allocated to
M. M. D.

Notes and references

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