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View Journal  | View Issue
Study on the stru
2

aFaculdade de Ciências e Tecnologia, UNES

Simonsen, 305, 19060-900, Presidente Pru

unesp.br; Tel: +55 1832295748
bInstituto de Biociências, Letras e Ciências E

Rua Cristóvão Colombo, 2265, 15054-000 S
cInstituto de Qúımica de São Carlos, Univers

13566-590, Brazil

† Electronic supplementary informa
10.1039/c6ra22508j

Cite this: RSC Adv., 2016, 6, 104529

Received 8th September 2016
Accepted 17th October 2016

DOI: 10.1039/c6ra22508j

www.rsc.org/advances

This journal is © The Royal Society of C
ctural and electrocatalytic
properties of Ba +- and Eu3+-doped silica xerogels
as sensory platforms†

Paulo A. Raymundo-Pereira,abc Diego A. Ceccato,ab Airton G. B. Junior,ab

Marcos F. S. Teixeira,ab Sergio A. M. Limaab and Ana. M. Pires*ab

This work reports on the sol–gel synthesis of barium- and europium-doped silica xerogel and its use as an

electrocatalytic sensor. Barium was chosen to assist the network framing and europium to provide

electronic properties, including the Eu2+/Eu3+ redox process. The results from different molecular and

structural techniques indicated that this xerogel is a composite material that combines a non-crystalline

polymeric silica network with a high level of agglomeration and a low degree of reticulation formed by

the hydrolysis and condensation of TEOS and M–O bonds (M ¼ Ba2+ and/or Eu3+), whereas the oxygen

atoms belong to the xerogel phase. The electrochemical behavior of the silica xerogel:Ba2+,Eu3+ with

different amounts of Eu3+ under several different conditions was investigated. The electrochemical

sensing platform showed a well-defined redox coupling with a formal potential of 0.06 V, assigned to

europium redox sites in silicate. Electrocatalytic activity was observed with an increasing anodic peak

current to the isoniazid oxidation, indicating that the electrochemical sensing platform designed here

was successfully achieved.
1. Introduction

The development of electrocatalytic devices has been an area
that has seen great advancement in recent years1–10 due to their
low cost of instrumentation and the possibility of being
assembled by different materials,1–12 with several reviews found
in the literature.11,13–15 Furthermore, by adding different chem-
ical species to the electrode surface, electron transfer in slow
electrochemical reactions is facilitated9 as the physicochemical
nature of the electrode/solution interface is changed. The
operation mechanism of these devices depends on the proper-
ties of the material immobilized at the electrode surface to
promote electron transfer toward the target species.16 Carbon
paste electrodes (CPEs) have been extensively applied for this
purpose since their surfaces are easily modied.9 Electro-
catalytic devices based on CPE have been widely applied toward
the determination of trace amounts of elements, the evaluation
of electrochemical processes, the preparation of biosensors,
P – Univ Estadual Paulista, Rua Roberto

dente, SP, Brazil. E-mail: anapires@fct.

xatas, UNESP – Univ Estadual Paulista,

ão José do Rio Preto, SP, Brazil

idade de São Paulo-USP, São Carlos, SP,

tion (ESI) available. See DOI:

hemistry 2016
and the investigation of electrocatalytic mechanisms and
organic species.1–10

Lanthanides are very versatile and can be used in the
production of glasses, ceramics,17 alloys, and electronics, and
they also nd application in agriculture and natural sciences.18

Lanthanide luminescent-based chemical and biological sensors
have been highlighted due to their photophysical properties
and their selective emission response to specic analytes.19–23

Despite the huge and increasing number of applications using
rare earth ions, proportionally there are few studies related to
the development and use of rare earth-based electrocatalysts for
sensors;3,11,24–34 nonetheless, this application should be explored
due to the excellent catalytic behavior that lanthanides exhibit.

Silica xerogels obtained from the sol–gel method have been
the focus of attention for electrochemists because of their
advantageous features, such as mechanical stability, durability,
and the possibility of doping them with metal cations.35 In this
context, our strategy was to develop a carbon paste electrode
modied with a composite material that would combine a high
surface area and high porosity allied with the peculiar electronic
properties of europium ions. Despite the fact that 3+ is the most
stable oxidation state for europium, depending on the chemical
environment, europium can be stabilized in its reduced atypical
2+ state. Therefore, due to having a similar ionic radius and the
same charge, Ba2+ was chosen as the network polymeric frame
in order to provide suitable sites to stabilize Eu2+ ions, thus
favoring the electrochemical Eu3+/Eu2+ redox process.36 To fulll
the physical characteristics of the material, the chosen
RSC Adv., 2016, 6, 104529–104536 | 104529

http://crossmark.crossref.org/dialog/?doi=10.1039/c6ra22508j&domain=pdf&date_stamp=2016-11-01
https://doi.org/10.1039/c6ra22508j
https://pubs.rsc.org/en/journals/journal/RA
https://pubs.rsc.org/en/journals/journal/RA?issueid=RA006106


RSC Advances Paper

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synthesis method was the sol–gel method.37–39 Finally, in order
to evaluate the potential of this system for use in sensing
devices, the electrocatalytic activity of the silica xerogel:Ba,Eu
was explored to identify isoniazid molecules in physiological
media.
2. Experimental section
2.1 Synthesis of silica xerogel:Ba2+,Eu3+ via the sol–gel route

Silica xerogels containing Ba2+ and Eu3+ (xerogel:Ba2+,Eu3+)
were synthesized via the sol–gel route by using Ba(CH3COO)2
(VETEC, 99.9%), Eu2O3 (Aldrich, 99.99%), C8H20O4Si, (TEOS,
Fluka, 99.9%), and CH3COOH (VETEC, 97%) as the starting
reagents. A sample containing only barium, i.e., silica xero-
gel:Ba2+, was prepared as a control sample. The amount of Ba2+

ions was kept constant by using 2eqBa(CH3COO)2:1eqTEOS,
while the amount of Eu3+ ions was varied relative to the Ba2+

ions as 0.5, 1.0, 5.0, and 10 ch% (charge percentage). Here, we
considered an isoelectronic doping process or charge compen-
sation mechanism (CCM), since Ba2+ and Eu3+ have different
charges, whereby for each three Ba2+ ions taken, we introduced
two Eu3+ ions, so the total positive charge remained unchanged.

For the gel synthesis, stoichiometric amounts of barium and
europium acetates dissolved in 10 mL of acetic acid and TEOS
in an isopropyl alcohol solution (5.55 � 10�1 mol L�1) were
used as the starting reagents (2Ba2+:1 TEOS). The doping
percentage was calculated in relation to Ba2+ ions. Then, 0.4 mL
of deionized water was added to the mixture to initiate the
hydrolysis reactions. Acetic acid was also added and acted as
a solvent and catalyst. The mixture was kept under stirring for
6 h at room temperature until gel formation. The gel was
thermally treated at 100 �C in a static air atmosphere for 2 h to
allow solvent evaporation, resulting in the xerogel phase. Then,
the silica xerogel:Ba2+,Eu3+ (1.0 ch%) sample was calcinated at
100, 200, 300 or 400 �C in an O2 atmosphere with a heating
ramp of 5 �C min�1 for 2 h in an EDG muffle furnace type.
2.2 Structural and molecular characterization

The produced xerogel samples were used to develop a sensory
platform, and their electrochemical performance were investi-
gated by using cyclic voltammetry. The inuence of several
parameters, such as pH, oxidizing atmosphere, supporting
electrolyte, europium amount (%), and potential scan rate, on
the electrochemical behavior of the silica xerogel:Ba2+,Eu3+ were
analyzed by the cyclic voltammetry. The sample xero-
gel:Ba2+,Eu3+ (1.0%) calcinated at 100 �C was also characterized
by Fourier Transform Infrared Spectroscopy (FTIR) using a Shi-
madzu Spectrometer IR Affinity-1 model; by scanning electron
microscopy (SEM) using a Carls Zeiss model EVO LS15 scanning
electron microscope with a detector of secondary electron (SE)
in a high vacuum and at constant temperature; and by thermal
analysis using a Universal V45A TA Instruments, no ow of air,
and a heating ramp of 10 �C min�1 up to 1200 �C. Solid-state
NMR of 29Si{1H} cross-polarization experiments were conduct-
ed using a Bruker Avance spectrometer at a magnetic eld of
9.4. The 29Si{1H} CP-MAS spectra were measured under
104530 | RSC Adv., 2016, 6, 104529–104536
a spinning speed of 10 kHz and using a CP contact time of 2.5
ms and relaxation delay of 5 s. All the spectra were acquired with
TPPM proton decoupling during the data acquisition applying
decoupling pulses. Chemical shis are reported herein relative
to the TMS referencing standard.
2.3 Preparation of electrocatalytic devices with silica
xerogel:Ba2+,Eu3+

As described elsewhere,24,40 the modied carbon paste electrode
(MCPE) used to set up the sensory platform was prepared by
carefully mixing 55 wt% of graphite powder (1–2 mm particle
size, Aldrich), 25 wt% silica xerogel:Ba2+,Eu3+ with different
percentages of Eu3+ (0, 0.5, 1.0, 5.0, or 10 ch%), and 20 wt% of
mineral oil (Aldrich), for a total mass of 0.5 g. This mixture was
prepared under magnetic stirring in a Becker (50 mL) contain-
ing 20 mL of hexane. The nal paste was obtained by evapora-
tion of the solvent. The modied carbon paste was packed into
an electrode body, consisting of a plastic cylindrical tube (o.d. 7
mm, i.d. 4 mm) equipped with a stainless steel staff serving as
an external electric contact. Appropriate packing was achieved
by pressing the electrode surface (surface area of 12.6 mm2)
against a lter paper.
2.4 Reagents and solutions for electrochemical assays

All the solutions were prepared using water puried with
a Millipore Milli-Q system. All the chemicals were of analytical
grade and used without further purication. The supporting
electrolyte used for the initial experiments was a 0.1 mol L�1

KCl solution. The isoniazid (1.0 � 10�3 mol L�1) was prepared
in solutions of NaCl 0.1 mol L�1, and then used as the storage
solution. The solutions were purged with nitrogen to remove
dissolved oxygen before the measurements.
2.5 Voltammetric apparatus

All the voltammetric measurements were carried out in a 50 mL
thermostatted glass cell at 25 �C with a three-electrode cong-
uration: a sensory platform as the working electrode, a satu-
rated calomel electrode (SCE) as the reference electrode, and
platinum wire as the auxiliary electrode. During the measure-
ments, the solution in the cell was neither stirred nor aerated.
The measurements were conducted with a mAutolab type III
(Eco Chimie) connected to a microcomputer and controlled by
GPES soware.
3. Results and discussion
3.1 Silica xerogel doped samples characterization

Thermogravimetric (TG) and differential scanning calorimetry
(DSC) analyses for the silica xerogel:Ba2+,Eu3+ (1.0 ch%) and
xerogel:Ba2+ samples showed a mass loss of approximately 5%,
with exothermic peaks around 450 �C related to the formation
of barium carbonate, and an endothermic peak at 1100 �C with
no mass loss related to the formation of barium silicate (Fig. 1).
X-ray diffraction patterns recorded for the xerogel:Ba2+ sample
heated under 450 �C and another one heated under 1100 �C
This journal is © The Royal Society of Chemistry 2016

https://doi.org/10.1039/c6ra22508j


Fig. 1 Thermogravimetric (TG) and differential scanning calorimetry
(DSC) analyses for the silica xerogel:Ba2+,Eu3+ (1 ch%) sample.

Fig. 2 FTIR spectra of (a) silica xerogel:Ba2+ and (b) silica xero-
gel:Ba2+,Eu3+ (1 ch%), both in KBr pellets.

Fig. 3 SEM images of silica xerogel:Ba2+ (a) and (b); and silica xero-
gel:Ba2+,Eu3+ (1 ch%) (c) and (d).

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supports this phase assignment, and can be found in the
ESI, S1.†

The solid-state 29Si NMR spectra for the silica xerogel:Ba2+

and silica xerogel:Ba2+,Eu3+ (1.0 ch%) samples treated at 100 �C,
as seen in Fig. S2(a) and (b),† exhibit three peaks, each at�90.70
(�92.98) ppm, �104.38 (�103.60) ppm, and �112.35
(�111.96) ppm, assigned to the Si(OSi)2(OH)2 group (Q2),
Si(OSi)3(OH) group (Q3), and Si(OSi)4 group (Q4), respectively, all
corresponding to the inorganic polymeric structure of silica.41

Since the CP-MAS (29Si{1H}) cross-polarization acquisition
mode was used, those groups that have hydrogen atoms near by
the silicon nucleus are intensied; therefore, in both samples,
the most intense signal corresponds to the Q3 site. Probably, the
Si(OSi)3(OH) groups are on the xerogels surface. The intensity of
the signal assigned to the Q2 groups apparently increases for the
sample containing europium, but this could be associated with
the europium paramagnetic effect on the silica surface causing
a signal loss.

In the FTIR spectra of the silica xerogel:Ba2+ and silica
xerogel:Ba2+,Eu3+ (1 ch%) samples, as seen in Fig. 2, bands
centered near 1014 cm�1 and 892 cm�1 assigned to the (Si–O–
Si)n and Si–OH vibration modes, respectively, can be observed,
which conrms the formation of polymeric silica as a result of
TEOS hydrolysis and condensation. Also, the presence of
vibration modes with an energy lower than 700 cm�1 related to
M–O bonds (M¼ Eu3+ and/or Ba2+) ensure that metallic ions are
combined to oxygen atoms in the xerogel network. Bands
centered near 1550, 1420, and 1280 cm�1 indicate the presence
of carbonates in the xerogel structure namely originating from
the thermal decomposition of acetic acid.

SEM images of the silica xerogel:Ba2+ and silica xero-
gel:Ba2+,Eu3+ (1 ch%) samples treated at 100 �C, as seen in
Fig. 3, show that both samples exhibit a high level of agglom-
eration. According to Rios et al.,42 the presence of non-
hydrolyzable groups from TEOS leads to a xerogel with a lower
degree of reticulation.42
This journal is © The Royal Society of Chemistry 2016
3.2 Inuence of the silica xerogel:Ba2+,Eu3+ synthesis
conditions on the sensory platform electrochemical
performance

To assess the effect of the europium doping concentration in
the silica xerogel:Ba2+,Eu3+ on the sensory platform, all the
samples were prepared by heating the gel at 100 �C for 2 h.
Voltammetric proles were evaluated in 0.1 mol L�1 KCl solu-
tion at pH 5.8, while the cyclic scans were conducted in the
unstirred solution at a potential scan rate of 50 mV s�1 from
�0.50 to +0.50 V vs. SCE, recording rst the oxidation step and
then the reduction step in the presence of oxygen. All the vol-
tammograms shown in Fig. 4 were recorded in similar condi-
tions. Fig. 4(a) shows the inuence of the amount of Eu3+ ions
varying from 0.5 ch% up to 10 ch% in the silica xero-
gel:Ba2+,Eu3+ phase on the anodic and cathodic peak current
signal of the sensory platform. A dened current peak can only
RSC Adv., 2016, 6, 104529–104536 | 104531

https://doi.org/10.1039/c6ra22508j


Fig. 4 Cyclic voltammograms obtained at a potential scan rate of
50 mV s�1 between +0.5 and�0.5 V vs. SCE in the presence of oxygen
for the sensory platform with: (a) silica xerogel:Ba2+,Eu3+ containing
0.5, 1.0 5.0, or 10 ch% of Eu3+ ions; (b) xerogel:Ba2+,Eu3+ (1 ch%)
pretreated thermally at 100–400 �C; and (c) silica xerogel:Ba2+,
xerogel:Ba2+,Eu3+ (1 ch%), and Eu2O3.

104532 | RSC Adv., 2016, 6, 104529–104536

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be observed for the sample containing 1.0 ch% of Eu3+ ions in
the xerogel. When the concentration is higher than 1.0 ch%, the
ionic mobility in the electrode surface is blocked, making the
electron transfer process difficult in the xerogel, consequently
suppressing the electrochemical process in the electrode
surface. For lower concentrations, e.g., the 0.5 ch% sample, we
observe that the electrochemical process does not take place;
probably the amount of active species is not enough to promote
the oxidation/reduction processes at the surface when the
potential scan is applied onto the sensory platform. Thus, the
silica xerogel:Ba2+,Eu3+ containing 1.0 ch% of Eu3+ ions was
selected for the further studies because it exhibited the best
voltammetric prole with a well-dened peak potential. The
silica xerogel:Ba2+,Eu3+ (1 ch%) sample was thermally treated at
different temperatures prior to the preparation of the sensory
platform, and the results are shown in Fig. 4(b). It is possible to
observe that the anodic and cathodic peak currents dramati-
cally decrease for the sensory platform prepared with the silica
xerogel samples that were heat-treated under higher tempera-
tures, even disappearing completely for the sensory platform
with the xerogel treated at 400 �C. By increasing the treatment
temperature, the xerogel gradually acquires a long distance
organization, creating a crystalline structure, whereas europium
ions canmove to the interstices, thus decreasing its efficiency in
terms of the electron transfer process and ion mobility. Thus,
Eu3+ ions within a crystalline network have difficulty in
changing their oxidation state. Consequently, the sensory plat-
form prepared with silica xerogel:Ba2+,Eu3+ (1 ch%) treated at
100 �C was selected for further investigation. In order to verify if
the electrochemical response was due to the composite
combined properties or the individual components, in Fig. 4(c)
we compare the voltammetric proles of the sensory platform
prepared with silica xerogel:Ba2+, silica xerogel:Ba2+,Eu3+ (1
ch%), and pure europium(III) oxide (Eu2O3). Only the sample
containing silica xerogel:Ba2+,Eu3+ (1 ch%) exhibits a typical
cyclic voltammogram, with two peaks at +0.061 V (EPA) and
�0.168 V (EPC), both remaining stable aer the second cycle,
with a quasi-reversible wave with a DEP ¼ 229 mV. The peaks
can be attributed to the reversible single-electron-reduction/
oxidation process of the EuII/EuIII pair. This is evidence of Eu
redox activity for the electrode, although in general the redox
peaks are somewhat ill dened.43,44
3.3 General electrochemical properties of the silica
xerogel:Ba2+,Eu3+ sensory platform

The surface concentration of electroactive species (G/mol cm�2)
was estimated from the background-corrected electric charge
(Q), under the anodic peaks in accordance with the theoretical
relationship31 as follows G ¼ Q/nFA, where Q (C) is the
background-corrected electric charge, calculated by integrating
the anodic peak of the cyclic voltammogram (v ¼ 5 mV s�1) in
KCl aqueous solution; n is the number of electrons transferred;
F is the Faraday constant; and A is the electrode geometric area.
The calculated Q value was 1.9 � 10�3 C, and the estimated
surface concentration was 1.6 � 10�7 mol cm�2. To determine
the inuence of the oxygen on the electrochemical behavior of
This journal is © The Royal Society of Chemistry 2016

https://doi.org/10.1039/c6ra22508j


Fig. 5 Evolution of the anodic peak potential of the silica xero-
gel:Ba2+,Eu3+ (1 ch%) sensory platform as a function of the [ionic
charge]/[ionic radii] and hydration enthalpies for alkaline ions (a) and
for earth-alkaline ions (b).

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the sensory platform, some experiments were carried out in
degassed solution, and the prole, which is included in the ESI
in Fig. S3,† exhibited a marked small alteration in the redox
potential in the absence of dissolved O2 (DEP(presence)�(absence) ¼
40 mV), while the current values were not altered. Therefore all
the analyses were performed in the absence of oxygen.
Furthermore, this signicant difference in the current magni-
tude at �0.40 V vs. SCE could be assigned to the reduction of
dissolved oxygen in solution.45 Thus, these results indicate that
the silica xerogel:Ba2+,Eu3+ sensory platform has promise as
a sensor for dissolved oxygen.

The effect of the potential scan rates (5–300 mV s�1) on the
voltammetric response of the silica xerogel:Ba2+,Eu3+ sensory
platform in 0.1 mol L�1 KCl solution was also investigated. The
recorded cyclic voltammograms revealed that the anodic peak
current increases and that the peak potential shis as the scan
rate increases, as shown in Fig. S4.† The anodic and cathodic
peak currents varied linearly with the square root of the scan
rates (inset Fig. S4†). This linearity indicates that the redox
process follows a diffusion-controlled mechanism. This
behavior suggests a mobility of the counter-ions of the sup-
porting electrolyte, which is necessary for charge transport or to
keep the electroneutrality at the electrode surface during the
redox process.46 Moreover, in Fig. S4 (ESI†), it can be seen well-
dened peaks aer 300 CV, indicating that the leaching of ions
is not observed. In addition, the voltammetric performance of
the sensory platform was investigated in different supporting
electrolytes: alkaline chlorides (CsCl, RbCl, KCl, NaCl, and
LiCl), earth-alkaline chlorides (BaCl2, SrCl2, CaCl2, and MgCl2),
and different sodium counter-ions (NaClO4, NaCl, NaNO3,
Na2SO4, Na2CO3, and Na3PO4), all at a concentration of 0.1 mol
L�1. The potential peaks (Eu(II)/Eu(III)) in different alkaline ions
decrease with the decrease in the ionic radius (from Cs+ to Na+),
as indicated in Fig. 5(a). The lithium ions, however, show an
anomalous behavior, which can be easily explained by the high
degree of hydration hindering the mobility of lithium ions. For
the earth-alkaline ions, as seen in Fig. 5(b), the peak potential
(Eu(II)/Eu(III)) increases in line with the decreasing ionic radius
(from Ba2+ to Mg2+), demonstrating the counter-ions inuence
on the voltammetric behavior of the silica xerogel:Ba2+,Eu3+ for
both the alkaline and earth-alkaline ions. The peak potential
was found to be linearly dependent upon the ratio [charge]/
[radius], indicating the migration of such ions into the silica
xerogel:Ba2+,Eu3+ network. From these results, we assume that
a mobility of the supporting electrolyte is necessary for the
charge transport and electroneutrality on the electrode surface
during the redox process.

The inuence of the anions: chloride, acetate, nitrate,
perchlorate, sulfate, phosphate, and carbonate in the support-
ing electrolyte on the voltammetric behavior of the silica xero-
gel:Ba2+,Eu3+ sensory platform was also investigated, and the
results can be seen in Fig. S5.† When carbonate and phosphate
ions were used, the redox process of Eu(II)/Eu(III) disappears
because the ions are in their hydrolyzed form, and consequently
they are in a lower concentration. We did not nd in this study
a clear dependence of the [ionic charge]/[ionic radius] ratio with
the peak potentials; however, chloride ion had the lowest peak
This journal is © The Royal Society of Chemistry 2016
potentials. Therefore, the NaCl 0.1 mol L�1 solution was chosen
as the best pattern due to its better voltammetric prole, and
also because it had the most negative potential observed among
the electrolyte solutions.

The electrochemical behavior of the silica xerogel:Ba2+,Eu3+

sensory platform in a 0.10 mol L�1 NaCl solution was studied
over a pH range of 2.0–12.0 using cyclic voltammetry and
a potential scanning from�0.5 to +0.5 V (vs. SCE) at a 50 mV s�1

scan rate. The electrolytic solutions were adjusted with hydro-
chloric acid and sodium hydroxide. The experimental results
showed that the silica xerogel:Ba2+,Eu3+ sensory platform is
more stable in neutral aqueous solutions than in
basic solutions. The voltammetric prole of the silica xero-
gel:Ba2+,Eu3+ sensory platform was slightly changed at pH 2–10,
which is indicative that the mechanism did not involve a proton
transfer process but rather a single electron transfer process
under the experimental conditions. For pH levels higher than
10, a single anodic peak of irreversible character was observed
for a more positive potential. This behavior is probably more
related to the europium hydroxide formation being in equilib-
rium with the silica xerogel:Ba2+,Eu3+ on the electrode surface
RSC Adv., 2016, 6, 104529–104536 | 104533

https://doi.org/10.1039/c6ra22508j


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than to counter-ion inuences on the voltammetric perfor-
mance of the silica xerogel:Ba2+,Eu3+. The peak potential and
peak current values were related to the pH values but no linear
relationship was obtained (Fig. S6†); thus, the pH of the elec-
trolyte solution (i.e., pH 6.0) was selected for the sequencing
studies.

3.4 Application of the silica xerogel:Ba2+,Eu3+ sensory
platform for the electrocatalytic oxidation of isoniazid

Voltammetric measurements were carried out in 0.1 mol L�1

NaCl solution (pH 6.0) containing different isoniazid concen-
trations in order to obtain the analytical curve. Fig. 6 illustrates
the anodic peak current for different isoniazid concentrations,
suggesting an interaction between the silica xerogel: Ba2+,Eu3+

and isoniazid. The current values (at +0.06 V) obtained provided
a linear relationship with the isoniazid concentration ranging
from 2.5� 10�6 to 2.4� 10�5 mol L�1. From 2.4� 10�5 mol L�1

onwards, a deviation from linearity occurred owing to satura-
tion of the electrode surface.47

The increase in the anodic peak current clearly shows the
catalytic process of isoniazid oxidation by the central metallic
cation in the silica xerogel:Ba2+,Eu3+. The suggested interaction
is similar to an electrochemical–chemical (EC0) mechanism.48

Two redox steps can describe the electrocatalytic mechanism of
the sensory platform. In the rst: when a positive potential
higher than 0.061 V vs. SCE is applied to the working electrode,
an electrochemical oxidation of silica xerogel:Ba2+,Eu2+ occurs,
producing silica xerogel:Ba2+,Eu3+ on the electrode surface.
When the cathodic potential is swept, the silica xero-
gel:Ba2+,Eu2+ is electrochemically regenerated. In the second
step, the xerogel in the oxidized form reacts with isoniazidred
generating isoniazidoxi (see Fig. 6), consequently reducing the
silica xerogel:Ba2+,Eu3+ to silica xerogel:Ba2+,Eu2+, which is
electrochemically reduced. The increase in the magnitude of
the anodic peak current obtained at 0.061 V (versus SCE) is
proportional to the analyte concentration in solution.
Fig. 6 Linear scan voltammograms obtained at 50mV s�1 for the silica
xerogel:Ba2+,Eu3+ (1 ch%) sensory platform containing different
concentrations of isoniazid. In the inset, analytical curves for isoniazid
obtained from the voltammograms.

104534 | RSC Adv., 2016, 6, 104529–104536
The detection limit was calculated following the method
described in the experimental section and the value obtained
was 2.91 � 10�7 mol L�1. This low detection limit can be
explained by the synergetic effect between the silica xero-
gel:Ba2+,Eu3+ and isoniazid, which facilitates the electron
transfer. The silica xerogel:Ba2+,Eu3+ sensory platform exhibited
convincing repeatability without a signicant loss of electro-
catalytic activity, with a relative standard deviation (RSD) lower
than 5%. The results showed that the relative standard devia-
tion (RSD) of the peak current of Eu2+/Eu3+ varies, where the
intra-day repeatability was 3.3% (with n ¼ 10), suggesting that
the prepared silica xerogel:Ba2+,Eu3+ sensory platform has good
stability. This could be ascribed to the excellent stability and
renewability of the surface. When ve parallel-fabricated
sensors were compared for inter-day repeatability, a relative
standard deviation (RSD) of 2.9% was observed, indicating
a good reproducibility of the sensor assembling. Moreover, the
stability of the sensor was also evaluated. Fiy measurements
were recorded and the initial electrochemical response
decreased by only 4.9%; these experimental results indicate that
the current response is reproducible and that the silica xero-
gel:Ba2+,Eu3+ sensory platform possesses long-term stability.

4. Conclusions

A Ba2+,Eu3+-doped silica xerogel was fully characterized by TG,
DSC, FTIR, SEM, and solid-state 29Si NMR, which showed that it
is a composite material that combines a non-crystalline poly-
meric silica network with a high level of agglomeration and
a low degree of reticulation formed by the hydrolysis and
condensation of TEOS and M–O bonds (M ¼ Ba2+ and/or Eu3+),
whereas the oxygen atoms belong to the xerogel phase.
Furthermore, cyclic voltammetry data indicated that Eu3+ ions
present in the xerogel network facilitate the oxidation of isoni-
azid at lower potentials (0.061 V vs. SCE). Therefore, the elec-
trochemical properties of the Ba2+,Eu3+-doped silica xerogel in
addition to its catalytic ability showed greater efficiency in the
isoniazid detection, with the added advantage that the device
preparation was not time consuming. Finally, the electro-
chemical properties of the silica xerogel:Ba2+,Eu3+ electro-
chemical sensing platform combined with its high catalytic
activity yielded values for the detection limit in the micromolar
range, exhibited high reproducibility and repeatability, and
excellent sensitivity. In essence, this study highlights the
potential improvement involved in the unexploited direct
application of an inorganic composite in electrode surface
modication. The low cost of the Ba2+,Eu3+-doped silica xerogel
sensory platform applied to isoniazid electrocatalytic oxidation
compared to graphene, carbon nanotubes, or metallic nano-
particles devices, represents a competitive advantage for this
device as a suitable tool for electrochemical applications.

Acknowledgements

The authors are thankful to the Brazilian agencies FAPESP,
CNPq (302728/2012-0) and CAPES for the nancial research
support. Paulo A. Raymundo-Pereira is particularly grateful to
This journal is © The Royal Society of Chemistry 2016

https://doi.org/10.1039/c6ra22508j


Paper RSC Advances

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the São Paulo research Foundation (FAPESP) for the award of
a scholarship (Grant No. 2008/07298-7, 2012/17689-9, 2016/
01919-6 and 2015/10394-1). Laboratório de Microscopia
Eletrônica de Varredura (FCT-UNESP) and RMN Si (IQ-UNESP,
Araraquara).

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This journal is © The Royal Society of Chemistry 2016

https://doi.org/10.1039/c6ra22508j

	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j

	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j

	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j
	Study on the structural and electrocatalytic properties of Ba2tnqh_x002B- and Eu3tnqh_x002B-doped silica xerogels as sensory platformsElectronic supplementary information (ESI) available. See DOI: 10.1039/c6ra22508j