This journal is©The Royal Society of Chemistry 2015 Chem. Commun., 2015, 51, 11697--11700 | 11697

Cite this:Chem. Commun., 2015,

51, 11697

Surface plasmon & visible light for polymer
functionalization of mesopores and manipulation
of ionic permselectivity†

Nicole Herzog,a Jonas Kind,a Christian Hessb and Annette Andrieu-Brunsen*a

The near-field of surface plasmons is locally confined to nanometer

dimensions. Here, we use surface plasmons to initiate polymer-

functionalization of mesoporous silica films allowing subsequent

ionic permselectivity gating based on polymer charge. We expect

this functionalization approach to open a new dimension of func-

tional miniaturization e.g. in nanofluidics.

Many efforts are concentrated on the fabrication of miniaturized
structures and building of nanodevices. To miniaturize devices
and functionalization the limits of synthetic protocols have to be
adapted to confine synthesis to the nanoscale. Spatiotemporal
control over a polymerization reaction is mainly offered by photo-
initiation procedures.1 Recently, even sunlight was proposed to
be used for a controlled polymerization.2 Using conventional
photolithography, local resolution is limited by Abbe’s law of
diffraction.3 On the other hand, the electromagnetic field of near-
field modes is characterized by local nanometer dimensions and
tunable wavelength in the visible. Surprisingly, surface plasmons
are mainly used for sensing4,5 and only few studies on surface-
plasmon induced polymerization are reported.6,7 Polymerization
in the visible can for example, be achieved with multicomponent
initiating systems, such as the combination of dyes as photo-
sensitizer and amines as radical initiating molecules.8 Examples
are cyanine dyes,9,10 methylene blue,11 or alexa dyes.12–14 Com-
bining such visible-light photo-initiation concepts with meso-
porous membranes (surface) functionalization of mesopores,
visible light-initiated, localized near-field functionalization in
water becomes accessible.15 Very recently the group of Soppera6,16

as well as the group of Kreiter7,17 demonstrated the possibility to
initiate a solution photopolymerization with the surface plasmon
of metallic nanoparticles. In this context Chegel and co-workers
used surface plasmon at a planar metal interface to perform

photochemistry and to in situ generate a biosensor matrix with-
out taking care about surface immobilization.11 So far these
experiments are focused on generating a relatively undefined
polymer matrix and they are not taking into account the third
dimension perpendicular to a surface or covalent surface grafting
of the generated polymer. Besides, polymer-functionalized meso-
porous thin films are known to be able to gate ionic permselec-
tivity by excluding ions of identical charge and pre-concentrating
countercharged ions.18,19 Such functionalized membranes are
highly interesting for nanofluidics, filtration-sensing elements,
sensor arrays.20

The applied concept of visible light induced surface polymer
functionalization of mesoporous thin silica films is summar-
ized in Fig. 1.

Three different dyes with absorption wavelengths of 390 nm
(2-chlorothioxanthone), 510 nm (40,50-dibromofluorescein), and
660 nm (methylene blue) in combination with bis-(2-hydroxyethyl)-
3-aminopropyltriethoxysilane as co-initiator6,21 are used for visible

Fig. 1 Schematic presentation of the visible light, sunlight, or surface
plasmon near-field induced surface polymer modification of mesoporous
thin silica films using dye-sensitized polymerizations.

a Technische Universität Darmstadt, Ernst-Berl-Institut für Technische und

Makromolekulare Chemie, Alarich-Weiss-Str. 4, D-64287 Darmstadt, Germany.

E-mail: brunsen@cellulose.tu-darmstadt.de
b Technische Universität Darmstadt, Eduard-Zintl-Institut für Anorganische und

Physikalische Chemie, Alarich-Weiss-Str. 8, D-64287 Darmstadt, Germany

† Electronic supplementary information (ESI) available. See DOI: 10.1039/c5cc03507d

Received 27th April 2015,
Accepted 16th June 2015

DOI: 10.1039/c5cc03507d

www.rsc.org/chemcomm

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light initiated photopolymerization. The absorption spectra (Fig. 2)
clearly show that the absorption maxima are well separated,
covering a wavelength range from 400 to almost 700 nm. This
allows to individually address three different wavelengths for
synthetic modifications.

To ensure covalent polymer attachment to the mesopore wall
we covalently grafted the co-initiator 3-[bis(2-hydroxyethyl)amino]-
propyl-triethoxysilane to the mesoporous silica thin films. After
silica surface modification with the co-initiator, XPS analysis
(Fig. 3) revealed one co-initiator molecule per approximately ten
silica atoms in case of functionalization at an elevated temperature
of 80 1C for 225 minutes. Reducing the reaction time to 45 minutes
resulted in a slightly decreased co-initiator concentration of one
molecule per 12.5 silica atoms (Fig. S3, ESI†) as extracted from
integration of the N1s signals at around 400 eV.

Subsequently, the mesoporous silica films were function-
alized with polymer using 2-aminoethylmethacrylate (AEMA),
2-(dimethylamino)ethylmethacrylate (DMAEMA) or [2-(metha-
cryloyloxy)ethyl]trimethylammonium chloride (METAC) by irradia-
tion with visible light, sunlight or surface-plasmon near field modes
in the presence of the initiating dye. Experimental details can
be found in the ESI.†

Initially, polymer functionalization using an external irra-
diation source in the presence of different monomers and dyes
is discussed. Polymer functionalization is monitored by following
the polymer CQO infrared absorption at 1725 cm�1 (Fig. 4a). All
infrared spectra show the characteristic bands of the inorganic
framework and the organic functions incorporated into the
mesoporous films after extraction of unbound monomer and
polymer.22 All spectra are normalized to the silica matrix using the
transverse optical Si–O–Si modes at 1065 cm�1 (nas). Especially,
the remaining CQO stretching at 1725 cm�1 after extensive
extraction indicates the successful visible-light induced polymer-
ization at the mesoporous silica thin film. To proof that poly-
merization occurs as well inside the mesopores and not primarily
on the external film surface, a short CO2 plasma treatment was
used to destroy the co-initiator located at the external mesoporous
film surface.22 Subsequent polymerization as well shows polymer
functionalization with only slightly reduced CQO infrared
absorption at 1725 cm�1 (Fig. 4b) indicating the polymer function-
alization of the mesopore walls.

Comparing the IR absorption at 1725 cm�1 (CQO) for
METAC and AEMA with plasma treatment (Fig. 4b) and without
plasma treatment (Fig. 4a) a slightly reduced absorption mostly
between 10–20% and up to 50% in case of METAC polymerization
with methylene blue is observed. This indicates a reduction in
polymer amount relative to the silica amount for plasma-treated

Fig. 2 UV-vis spectra of the applied dye initiators 2-chlorothioxanthone
(orange), 40,50-dibromofluorescein (green), and methylene blue (blue) mea-
sured in a water-based solution.

Fig. 3 (a) XP-spectra showing the co-initiator presence after function-
alization for 45 minutes (red) and 225 minutes (blue) in comparison to
non-functionalized mesoporous thin films (black) including the respective
zoom into the N1s signal for the untreated mesoporous silica film (d) as
well as after functionalization for 45 minutes (c) and 225 minutes (b).

Fig. 4 Infrared spectra showing the generation of polymer as detected by
the CQO vibration at 1725 cm�1 for the polymerization of (a) METAC with
methylene blue (red), DMAEMA with 40,50-dibromofluorescein (cyan),
methylene blue (blue), 2-chlorothioxanthone (marine) and AEMA with
40,50-dibromofluorescein (olive), methylene blue (dark yellow), 2-chloro-
thioxanthone (green) for non-plasma treated samples and (b) mesoporous
silica films after plasma treatment and thus destruction of the co-initiator at
the external mesoporous film surface. (c) Schematic view of the near-field
induced polymerization in the Kretschmann configuration. The angular
spectra of a B260 nm (red) and a B550 nm (blue) thick mesoporous film
are shown in the presence of air (d) and monomer solution (f). (e) Infrared
spectra for the polymer PDMAEMA (red) and the PDMAEMA modified
mesoporous B260 nm film (black) in comparison to the DMAEMA mono-
mer (grey). In case of reduced laser intensity, shorter reaction time and an
angle of almost no energy coupling (641) in case of the B550 nm film only a
very low amount of polymer is generated (g, blue).

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films as compared to non-plasma treated samples. The observed
reduction in CQO absorption is not proportional to the inner
versus outer surface ratio which might indicate diffusional limita-
tions for the polymerization in mesopores under the applied
experimental conditions. Nevertheless, a significant amount of
polymer is generated within the mesopores (Fig. 4b) showing the
diffusion of dye and monomer into the mesoporous film and the
potential of visible light induced polymerization as functionaliza-
tion strategy for the inner mesopore surface. Polymerization
inside the mesopores was additionally verified by ellipsometry
measurements. The film thickness was determined to be around
260 nm after polymerization and the refractive index increased
upon each modification step from 1.26 to 1.36 after co-initiator
modification, exceeding 1.40 up to 1.46 after polymerization.
Based on the effective medium approximation23 a total pore
filling of 30–45% in case of METAC polymerization initiated with
methylene blue is detected. Analyzing the solution polymer for of
DMAEMA polymerization by GPC measurements, a Mw between
1 � 105 and 7 � 105 with a PDI between 2.7 and 5.7 was observed
after initiation with 40,50-dibromofluorescein or 2-chlorothiox-
anthone. In case of polymerization at planar silicon wafer sub-
strates the solution polymer molecular weight according to GPC
measurements was smaller (3–8 � 104 g mol�1). The exact values
are summarized in Table S2 (ESI†). For surface polymer analysis
an exemplary degrafting for PDMAEMA initiated with methylene
blue and with 2-chlorothioxanthone revealed very small amounts
of polymer and molecular weights of 5 monomer units per chain
as determined by mass spectroscopy. This supports earlier
observations on polymerization in confinement of mesopores
resulting in lower polymer molecular weight as compared to
polymerization at planar surfaces and in solution.22,24 Further
details can be found in the ESI.†

Ellipsometry, infrared spectroscopy, and GPC analysis of the
solution polymer indicate a successful polymerization initiated
by visible light between 400 and 700 nm for three different
initiators and three different monomers METAC, AEMA, DMAEMA.
This is building the basis for localized polymerization initiated by
near field modes such as surface plasmons. Even sunlight exposure
resulted in polymerization as verified by infrared spectroscopy. In
the following, the above discussed polymerization conditions
are transferred to surface plasmon-initiated surface polymer
functionalization of a mesoporous silica film supported on a
thin gold film.

Under the applied experimental conditions surface plas-
mons are induced between 400–700 nm in the Kretschmann
configuration (Fig. 4c). Surface plasmons generated in a 50 nm
gold film with a He–Ne-laser excitation at 633 nm in the
Kretschmann configuration25 are characterized by an exponen-
tially decaying electromagnetic field perpendicular to the metal
surface with a penetration depth of B200 nm.25 We functionalized
mesoporous silica films by using the highly localized surface
plasmon electromagnetic field to initiate dye-sensitized polymer-
ization at 633 nm. At this wavelength methylene blue as initiating
dye is used.

Mesoporous silica thin films were deposited on a gold-
covered (50 nm) high refractive index LaSFN9 glass substrate.

The gold layer is covered with a few nm thick, sputtered SiOx layer
to facilitate mesoporous film deposition by dip coating and
evaporation induced self-assembly (EISA).26 Irradiation with a
He–Ne-laser in the Kretschmann configuration results in genera-
tion of a surface plasmon under resonant angle (Fig. 4d and f).
The resonant angle for the mesoporous silica film deposited on
the SiOx-covered gold interface is around 60–651 in the presence
of air and shifts to up to 751 upon addition of water-based
monomer solution (Fig. 4d and f). The mesoporous film thick-
ness was determined to be around 260 nm for a one layer
mesoporous film and around 550 nm for a two layer mesoporous
film, which is in accordance with ellipsometry measured on wafer
substrates. Surface plasmon-induced polymerization was carried
out at the surface plasmon resonance angle with a laser irradia-
tion input energy of up to 4 mW and constant flow of monomer/
dye solution at a flow rate of 5 ml min�1. Taking into account the
loss of energy, visible by the coupling of the surface plasmon,
35% of the irradiated energy in case of the one layer film (Fig. 4d
red) is transmitted into the surface plasmon and thus used for
polymerization initiation. After dismantling the flow cell, polymer
generation for a thin, 260 nm thick, film was already visible by eye
proving the potential of surface plasmons for polymerization initia-
tion at functionalization of interfaces. Polymer generation was as
well supported by infrared spectroscopy clearly showing polymer
generation by the disappearing double bond signals at 2770 cm�1

and 1640 cm�1 (Fig. 4e) comparing monomer and polymer infrared
spectra. Additionally, the presence of polymer vibrational bands in
the absence of monomer vibrational bands for the surface-plasmon
induced polymerization in a mesoporous silica film (Fig. 4e) sup-
ports polymer functionalization. Performing the surface plasmon-
initiated polymerization with a thicker B560 nm mesoporous silica
film at an angle of 641, shorter reaction time and under reduced
irradiation energy, no or only very small DMAEMA signals were
visible in the infrared spectrum (Fig. 4g). This clearly shows
the great potential of near-field induced polymerizations for
gradual functionalization of mesoporous films applicable in
ionic permselectivity control, as well as the huge potential for
nanoscale local control on polymer functionalization by benefiting
from nanoscale near-field local distribution.

The applicability of visible-light polymer functionalization
of mesoporous films to control ionic permselectivity is demon-
strated by cyclic voltammetry measurements (Fig. 5). The
exemplarily shown cyclic voltammogramms for unmodified
mesoporous silica (Fig. 5a) and poly-DMAEMA modified meso-
porous silica after plasma treatment and 40,50-dibromofluo-
rescein initiated polymerization (CQO absorption 0.05 at
1725 cm�1) (Fig. 5b) clearly show the influence of polymer
functionalization within the mesopores. Due to the positively
charged poly-DMAEMA the mesoporous film becomes anion-
selective and excludes positively charged probe molecules at an
acidic pH, whereas the negatively charged molecules are able to
enter the pores to a higher concentration as compared to unmodi-
fied mesoporous silica films. This is demonstrated by the higher
peak current in case of poly-DMAEMA modified films (Fig. 4b) as
compared to unmodified silica mesoporous films (Fig. 4a). More
results on ionic permselectivity can be found in the ESI.†

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11700 | Chem. Commun., 2015, 51, 11697--11700 This journal is©The Royal Society of Chemistry 2015

In conclusion, we have developed a mesopore polymer
functionalization strategy based on visible light induced radical
polymerization which allows mesopore polymer functionalization
by near-field modes. Our results suggest polymer functionaliza-
tion of the inner mesopore walls with lower molecular weights as
compared to the polymer generated in solution. Polymer function-
alization results in ion permselective behavior governed by the
polymer charge. This mesopore functionalization approach is
expected to have great potential for local synthetic control with
resolution on the nanometer scale and thus especially in the field
of nanofluidics and lab on chip devices.

The authors would like to thank the Landesoffensive zur
Entwicklung Wissenschaftlich-ökonomischer Exzellenz (LOEWE
Soft Control) as well as the Fonds der chemischen Industrie and
the Adolf-Messer Stiftung for recognition and financial support of
this work. The authors thank Karl Kopp for performing the XPS
experiments and Hamid Keshmiri for initial work on mesoporous
film preparation on gold surfaces.

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Fig. 5 Cyclic voltammetry (25 mV s�1) results at an acidic pH (2–3) clearly
show the influence of the polymer (here DMAEMA) on ionic perm-
selectivity (b) for a positively charged probe molecule ([Ru(NH3)6]2+/3+

blue) and a negatively charged probe molecule ([Fe(CN)6]3�/4� green) in
comparison to unmodified mesoporous silica (a).

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