Study of interfaces in polymer metal oxide films and free volume hole using low energy positron lifetime measurements

Council of Science and Technology, Bhopal, India a r t i c l e i n f o Article history: Received 5 February 2019 Received in revised form 28 July 2019 Accepted 10 August 2019 Available o

Original Article

using low-energy positron lifetime measurements

a Vikram University, Ujjain, 456010, MP, India

b Lovely Professional University, Jalandhar, Punjab, India

c M.P Council of Science and Technology, Bhopal, India

a r t i c l e i n f o

Article history:

Received 5 February 2019

Received in revised form

28 July 2019

Accepted 10 August 2019

Available online xxx

Keywords:

Polystyrene thin films

ZnO

TiO 2

Positron annihilation

Free volume hole

Interfacial interaction

Solution cast method

a b s t r a c t

To reveal how the distribution of different nanofillers affect the UV-shielding efficiency of their polymer-based composites and to further develop a simple strategy to refrain the erection of the composites, we prepared ZnO doped polystyrene (PS/ZnO) and TiO2doped polystyrene (PS/TiO2)films by the solution cast technique with different concentrations of ZnO and TiO2(0.25%, 0.5%, 0.75% and 1%.) Contrary to the common observation, the better tunability for UV shielding efficiency was found in case of TiO2as compared to ZnO This is mainly due to the appearance of a rod like structure on neat PS which has improved the dispersion as well as provides a higher interface area that enhanced the UV-absorption

efficiency of the PS matrix This analysis is equally supported by the PALS study where the free vol-ume was closely associated with the interfacial interaction between thefiller and the PS matrix These observations recommend that the better dispersion offiller particles leads a stronger interfacial inter-action and enhances the UV-protection efficiency of the composite materials

© 2019 The Authors Publishing services by Elsevier B.V on behalf of Vietnam National University, Hanoi This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/)

1 Introduction

Previously, our group has successfully prepared TiO2/PSfilms

with concentrations up to 1 wt % by the solution cast method in the

development of photo-protective polymeric materials for the

pro-tection against ultraviolet radiation Interestingly, the as-prepared

thin films have shown a tremendous UV-shielding proficiency

[1,2] These results suggested to pursue a further study on the

re-lationships among the atomic free volume and the interfacial

interaction between thefiller particles and the PS matrix Contrary

to the common observations where numerous approaches have

been made for the development of ZnO doped composites as a

better UV protective material, in our previous study TiO2 has

expressed a better harmony for the efficient UV shielding which we

will incorporate in the present work as a comparative study To

analyze the imperfections produced at the early stage of the

process in engineering materials it is important to predict the weakness and failure of the material This work is consequential for the final understanding of the UV-shielding efficiency by comparing its results with those of a widely studied material as ZnO The very extensively studied inorganic materials ZnO and TiO2 with a wide band-gap energy of 3 eV have been expansively used as inorganic UV absorbers due to their significant optical properties [3] Consequently, such polymer nanocomposites have been regarded as excellent candidates for UV shielding applications As a matter of fact, the extraordinary properties of the polymer nano-composite include the dispersion of the nanoparticles in the matrix and the subsequent growth of enormous interfacial areas This complete dispersion allows the exploration of the available matrixeparticle interface and then the optimization of the organiceinorganic interaction which is accountable for the improved properties of thefinal material Nevertheless, there have been less reported on the research efforts in this area especially those dealing with the effect of the free volume hole and the interfacial interaction on the UV-shielding efficiency[4e6] More-over, most of the works have adopted higher dopant concentrations

to conquer a better UV-shielding efficiency of the films [4,7e10]

* Corresponding author Lovely Professional University, Jalandhar, Punjab, India.

E-mail addresses: acharyaphysics2011@gmail.com (A.D Acharya), sarbhawna@

gmail.com (B Sarwan).

Peer review under responsibility of Vietnam National University, Hanoi.

Contents lists available atScienceDirect Journal of Science: Advanced Materials and Devices

j o u r n a l h o m e p a g e : w w w e l s e v i e r c o m / l o c a t e / j s a m d

https://doi.org/10.1016/j.jsamd.2019.08.003

2468-2179/© 2019 The Authors Publishing services by Elsevier B.V on behalf of Vietnam National University, Hanoi This is an open access article under the CC BY license ( http://creativecommons.org/licenses/by/4.0/ ).

the free volume properties of polymers in the amorphous state can

be accomplished by the use of the positron annihilation lifetime

spectroscopy technique (PALS) This technique involves the

inser-tion of positrons into the material and then recording the

indi-vidual positron lifetimes until the annihilation with electrons of the

sample takes place[11,12] Since the fraction of the positrons

an-nihilates from the state of an orthopositronium (o-Ps) and the

lifetime of the orthopositronium depends on the size of the free

volume cavity where it is placed, hence, it can be employed to

characterize the free volume size in amorphous polymers

Following the above described study concern, the main motivation

of the present work is to investigate what would be the effects of

doping ZnO and TiO2 into PS on the atomic free volume, the

interfacial contact among thefiller particles and the PS matrix, and

the UV-absorption efficiency of PS at low content of fillers by the

positron annihilation lifetime spectroscopy

2 Experimental procedure

ZnO/PS and TiO2/PS thinfilms with different concentrations viz

0.25%, 0.5%, 0.75% and 1% have been prepared by using the solution

casting method The polystyrene was procured from the market

which was in the granular form The PS solution was prepared in

the dichloromethane, the requisite amount of semiconductors (ZnO

or TiO2) was then added into the solution under rapid stirring for

uniform dissolution The resultant was then poured on to a cleaned

petri dish to cast thefilm and the solvent was subsequently allowed

to evaporate gradually over a period of 12e24 h in a dry

atmo-sphere The membrane was then physically peeled off from the

surface The area of the cast surface, the material quantity and the

density of the material can determine the thickness of the

mem-brane We have prepared the polymer thinfilms of ~50mm

thick-ness For preparing the doped PS thin films, the dopant

concentration was calculated from the following equation[1,13]

wpþ wf 100

where,wf and wp represent the weight of the dopant and the

polymer, respectively

X-ray diffraction patterns of ZnO/PS and TiO2/PS thinfilms were

recorded on an X-ray diffractometer (Bruker D8 ADVANCE) with

Cu-Karadiation having the wavelength of 1.5418Å in the range of

2q¼ 200- 700 Atomic force microscopy (AFM) measurements were

carried out on a digital instrument of Nanoscope E with the Si3N4

100mm cantilever and 0.58 N/m force constant The transmittance

of thefilms has been measured with a UV-Vis Spectrophotometer

(PerkinElmer Lambda 950) Measurements of the positron lifetime

in ZnO/PS and TiO2/PS thinfilms have been done by using the slow

e fast coincidence method

3.1 Structural and surface analysis The XRD patterns of the films are shown in Fig 1 As it is perceived from the XRD patterns the pure PSfilm (Fig 1a,b) shows

an amorphous polymeric structure and the diffraction peaks of PS

do not appearein the patterns The pattern of the PS thinfilms loaded with 0.5 wt% TiO2 and ZnO (Fig 1 a,b), however, shows diffraction peaks of low intensity suggesting improved crystalinity

of the PS At the higherfiller content, the peak positions of the 1 wt

% sample is slightly shifted towards lower diffraction angles The most likely reason for this shift is the interaction between thefiller particle and the polymer structure that leads to a rearrangement of the PS chains (SeeFig 1a and b (Inset)) The increased intensity of the reflections from the diffracted planes with the higher amount of filler loadings suggests that a slowering of the crystallization rate arrised due to the enclosure offiller particles It can be concluded that a suitable, but not excessive, amount of dopant is responsible for observed good dispersion of the inorganicfiller particles in the

PS matrix

To get a further insight, we extended our approach to another important analysis using the atomic force microscopy (AFM) of the doped polymer samples.Figs 2 and 3show the AFM images of thin sections of the ZnO/PS and TiO2/PS composite surfaces loaded with the dopant content of 0.25, 0.5, 0.75 and 1.0 wt % It can be observed from AFM images (Fig 2) of PS/ZnO that the grain size increases with the increase in the ZnO concentration upto 0.5 wt% (See Fig 2c) leading to the aggregation The addition of ZnO particles at about 0.75 wt % does not encourage the faster crystallization (See Fig 2d) In case of the 1.0 wt % sample (SeeFig 2e), the efficiency of ZnO for enhancing the matrix crystallization get reduced due to the high particle density and obstructed the development of crystalline sections This illustrates that the small amount of ZnO particles i.e 0.5 wt% located in the PS matrix corresponds to the primary par-ticles and the extent of the agglomeration was found to be quite negligible The PS matrix having 0.75 wt% and 1.0 wt% ZnO particles changed to large size aggregates where several primary ZnO nanocrystallites were gathered Furthermore, the entire morphology was deformed when 1.0 wt% ZnO was employed

By comparing the AFM images, an obvious difference can be seen between the neat PS and the TiO2/PSfilm.Fig 3a shows an AFM image of thin sections of the TiO2/PS thinfilm at the dopant content of 0.25 wt % It signifies that the TiO2particles were setup in the form of aggregates of slackly linked paramount particles showing areas which are homogeneously implanted in the PS matrix After addition of 0.5 wt% TiO2into the matrix some rods appeared (SeeFig 3c) on the surface of the neat PS presuming that the formation of these rods mainly depends on the growth and nucleation conditions Moreover, a fractal type of aggregation of TiO2particles has been observed inFig 3d, such situation may arise due to the high concentration of nucleates that were formed by

adding the 0.75 wt%filler content Moreover, looking intoFig 3e,

the nucleates randomly agglomerate in the continuous phase and

cause the increase of the number of TiO2particles, thus, making the

interface area larger and the overlap of these led to opaquely

appearing TiO2/PSfilms[9,13] This area is notably higher than that

of the 0.5 wt% TiO2/PSfilms This observation suggests that the

0.75 wt% TiO2/PSfilms have large particle agglomerates, while the

0.5 wt % TiO2/PSfilms have an improved dispersion as well as a

higher interface area and therefore exhibit a higher UV- absorption

efficiency From this analysis, it may be inferred that to speed up the

matrix crystallization and for altering the synthesized

nano-structure morphology, a low concentration of dopant as such of

0.5 wt % is enough Herewith, the AFM results suggest that the inorganic semiconductor particles were well incorporated in the

PS, which consequently modify significantly the morphology of the

PSfilms

3.2 ZnO/PS and TiO2/PS UVevis shielding The transmittance characteristics of the pure PS, the ZnO/PS and TiO2/PSfilms are visualized inFig 4 It is found that almost 99% of the light was passed-on by the pure PS in the UVevis region of wavelengths from 300 to 700 nm As shown in Fig 4a, the maximum value of transmittance of the ZnO/PS films containing

Fig 1 X-ray diffraction patterns: (a) ZnO/PS and (b) TiO 2 /PS thin films.

Fig 2 AFM images of ZnO/PS film.

0.25 wt % ZnO was found as pretty as 95% By a careful

consider-ation, it can be seen that the continuous inclusion of ZnO induces a

systematic decline of the transmitted light, lowering the

trans-mittance The transparency is also dependent on the dispersion/

aggregation of the nanoparticles into the polymer matrix The

fractal distribution of discretely dispersed nanoparticles favors the

optical transparent intensity loss of the transmitted light because

the scattering abruptly rises with the particle size This causes a

significant drop in the transparency of the films[10,14] In line with

this, the gradual decrease in the visible-light transmission from 95

to 70% in thefilms containing 0.25e1 wt % ZnO was observed and

highlighted by the shaded area inFig 4a The thinfilms with 1 wt %

ZnO dopant shows a non-uniform distribution of the ZnO particles

within the polymer matrix This could be endorsed by the AFM

results (Fig 2) where no substantial ZnO agglomerations were

found The obtained experimental results provide a visual illus-tration to the UV-shielding effect in ZnO/PS When ZnO/PSfilm is irradiated with the incident radiation, the visible light perfectly passes through the material as ZnO particles are apparent for the wavelengths greater than 375 nm while the UV-spectrum is obstructed depending on the ZnO concentration For the reason that the ZnO nanoparticles build a physical obstacle that the UV light cannot cross since they act as a protective network When the dopant concentration is further increased, the scattering mean free path gets decreased Due to this reason, the light traveled strongly inside thefilm with increased obstacle leading to the reduction in UV-light transmission to 63% with 1 wt% ZnO concentration (see Fig 4a)

The UVeVis transmittance of the TiO2/PS film is plotted in Fig 4b High transparency in both the visible and UV region is

Fig 3 AFM images of TiO 2 /PS film.

Fig 4 The transmittance spectra: (a) ZnO/PS and (b) TiO 2 /PS films.

observed in the pure PSfilm (seeFig 4b), which is not competent to

filter out the UV radiations, whereas the addition of TiO2content

leads to the increase in the UV shielding efficiency due to the empty

conduction band and the filled valence band However, the UV

blocking consequence is seen in thefilms with TiO2contents as low

as 0.25 wt%, while the high transparency in the visible range is

maintained The concentration of 0.5 wt % TiO2could be assumed as

the optimal one for the better UV shielding effect as evidenced by

the graphical situation in the region bellow 355 nm, where more

than 70% transparency is observed This evidences that the

intro-duction of TiO2particles into the PS matrix is compatible to

in-crease the UV protecting proficiency of the PS film in the region

from 300 to 355 nm The further increment of TiO2 (0.75 wt %)

results in the opaque appearance with the increased absorption in

both the visible and UV region In this state, the apparent nature of

the material as a UV filter is decreased This behavior can be

interpreted by the fact that the increased amount of TiO2enhances

the interface scattering causing the reduction in the transmittance

This reduction might be ascribed to the growing cluster size[6] In

addition, the cluster size of thefilm becomes more non-uniform,

and irregular with the increasing TiO2content up to 1 wt%

lead-ing to the reduction in the transmittance as it is confirmed on the

AFM images (Fig 3e) of the compositefilms Here, the shape of the

PS latex is almost demolished and then totally vanished because of

the interdiffusion process between the polymer chains From this

result, it might apparently be easy to load the interstices of the thin

PS template with a low concentration of dopant, but it is difficult to

fill the interstices at a higher concentration So, the dopant content

can be considered as a key parameter for the permeation of the PS

templates[15]

The band gap energies (Egvalues) of the ZnO/PS and TiO2/PS films could be estimated from a plot of (ahn)2vs the photon energy (hn) inFig 5a,b Band gap values of 3.00, 2.47 and 2.61 eV were obtained for the pure PS, ZnO/PS and TiO2/PSfilms, respectively (for the optimum content, i.e 0.5%) However, two different mecha-nisms are accounted for the variation in the calculated optical band including: (1) The inclusion of a tiny amount of dopant produces charge transfer complexes in the host matrix which accelerate the electrical conductivity by providing additional charges which cause the reduction of the band gap [18,19]; (2) When the amount of dopants increases, the dopant molecules initiate to linking the gap between the localized states and thus lowering the potential bar-rier between them[16e22]

3.3 Positron annihilation lifetime studies The measurement for the positron annihilation lifetime studies (PALS) was carried out to examine the effect of TiO2and ZnO on the microstructure of the compositefilms The positron lifetime spectra

of the pure PS,ZnO/PS and TiO2/PSfilms, respectively, are presented

inFig 6 They show a systematic decreasing trend of the lifetime This indicates a decrease in the longest lifetime

The free volume size (Vf), and the o-Ps lifetime (t3) as a function

of the TiO2and ZnO content are shown inFig 7aeb, respectively FromFig 7a, it can be observed that the t3and Vfinitially drop with the TiO2 incorporation upto 0.5 wt% In the range from 0.5 to 0.75 wt%, a slight increase in t3and Vfis seen Theyfinally decrease

to the lowest value at higher doping, i.e at 1 wt% Looking again into Fig 7a, there is a decrease in t3and Vfwith the increasing TiO2 concentration (0.25e0.5 wt %) indicating that the additional

Fig 5 Plots of (a∙h∙y) 2 v/s photon energy (h ∙y): (a) ZnO/PSand (b) TiO 2 /PS thin films.

Fig 6 Positron lifetime spectra: (a) ZnO/PSand (b) TiO 2 /PS thin films.

amount of TiO2 slows down the o-Ps formation This can be

explained by the fact thatfirstly the TiO2particlesfill up some of

the free volume holes in the PS and so the values of t3 and Vf

decrease Secondly, positrons may be annihilated from the TiO2

filler and there may be a lack of positrons which should be available

to form the positronium in PS[12] On the other side, the increase of

o-Ps at the dopant concentration of 0.75 wt% TiO2 suggests the

formation of new positron trapping sites at the TiO2ePS interface

As thefiller concentration is increased to that corresponding to the

1 wt% concentration, the TiO2filler inhibits the o-Ps formation and

thefiller particles are scattered among the molecular chains of the

PS and thus reducing the free volumes size leading to the decrease

of the o-Ps lifetime in the PS Quite the reversal, a small but

sys-tematic increase in the free volume size and in the o-Ps lifetime has

also been initially observed in the case of the low ZnO doping (i.e

0.25e0.5 wt%) (seeFig 7b) This is because of the development of

new positron trapping sites at the ZnO/PS interface The highest

values of t3and Vfhave been found for the 0.5 wt% ZnO/PSfilm,

whereas when we have increased the ZnO concentration upto 1 wt

%, the values of t3and Vfdecrease showing that some of the free

volume holes in the PS are filled up by the ZnO particles It is

interesting to note that the interfacial interaction between thefiller

and the polymer matrix has caused a vital effect on the free volume

size and the o-Ps lifetime This interaction dominates the delivery

of phonons between the matrix and thefillers[23e25]mainly at

0.5 wt% ZnO concentration where both the free volume size and the

o-Ps lifetime reach their maximum We recall the main fact that the

film with a low dopant amount ZnO represents a high surface area,

thus, providing more positron trapping sites which scatter the

phonons at the interface[26e28] However, at the high ZnO

con-centrations, the ZnO agglomerates and due to this interfacial

interaction, the induced disruption effect becomes limited,

reducing the free volume size and the o-Ps lifetime

3.4 The correlation of PALS results and UV-shielding

From the calculated results of the PALS and the morphological

studies, the UV-shielding efficiency of the ZnO/PS and TiO2/PSfilms

could be clearly understood From the PALS results of TiO2/PS, it is

noticed that the free volume hole size and the o-Ps lifetime initially

drop with the TiO2incorporation It might be an evidence for the

gradual formation of neutral aggregates at the initial level offiller

concentrations which creates blockages and reduces the free

vol-ume holes, enhances the crystallization of the matrix as it was

clearly confirmed by the AFM results This decrease in the free

volume holes may also contribute to the increase in the UV

shielding effect Furthermore, this factor reduces the ion and the

segmental mobility through the unified matrix and hence, leads to

the reduction of the free volume size At the high filler

concentrations, a random distribution of filler particles might initiate the formation of free volume holes in the PS matrix This process of the free volume formation gradually dominates the creation of neutral aggregates which fairly agrees with the AFM results and confirms the transition from the crystalline state to the amorphous one at higher TiO2concentrations where the regretable interaction between the loaded TiO2particles and the PS matrix have slight limitations on the segmental mobility because of less contact area and so contributing to the increase in t3 and Vf as shown inFig 7a An explanation based on the PALS results and detailed literature survey [27e29] implies that the o-Ps mainly annihilates in the interfacial regions In fact, there is some infor-mation indicating that the interfacial free volume is a vital factor for determinating the variation in the o-Ps annihilating lifetime because the interfaces have an excellent electronic density compared to the bulk phase

It is worth noting that in the case of ZnO/PS, the initial incre-ment in t3with increasing ZnO concentration upto 0.5 wt% (see Fig 7b) suggests the formation of the free volume and amorphous phases in the blend matrix due to the sufficient separation be-tween thefiller particles at low filler concentrations Our tentative elucidation is that the dispersion of ZnO particles can cause the disorder of the molecular configuration leading to the morpho-logical change in chains and thus increase in the free volume concentration and the o-Ps lifetime The above discussion cor-roborates that the better the dispersion of the lifetime the stronger will be the distraction of the molecular morphology On the other hand, as the ZnO content further increases, this distraction of ZnO weakens as being caused by the aggregation of ZnO leads to the decrease in the free volume concentration and the o-Ps lifetime The analysis also confirms that the free volume hole decreases with the increasedfiller concentration, because the filler limits the moving space of the molecular chains

From the above explanation it can be clear that the calculated free volume hole size does not show a drastic variation with the ZnO content, but revealing a very little amount being adequate to accelerate the matrix crystallization which assures a less tunability for the UV radiation This could be probable because an excessive amount of ZnO can obstruct the formation of well crystallized re-gions and lead to the turbidity/translucency of the composite ma-terials This illustrates that the particle size of the ZnO in the PS matrix corresponds to that of the primary particles and the extent

of the agglomeration is moderately negligible, whereas in the case

of TiO2particles the reduction in the free volume hole size leads to the increase in the UV shielding effect It is evident that the more exposure of the PS to the UV causes the increase in the size of the free volume hole while the hole density remains unchanged The destruction of the PS matrix sets in when TiO2is added leading to the formation of voids in the region of the TiO2particles aggregates

This is attributed to the desorption and dispersion of the active

oxygen species produced on TiO2 surface engraving the polymer

matrix Furthermore, the rod shaped aggregation of the TiO2

nanoparticles (as shown inFig 3c) acting as the nucleating agents

leads to the increase in the UV shielding Moreover, doping with

TiO2results in a considerable increase in grain size due to the rod

shape aggregation that leads to the reduction of the grain boundary

scattering and this enhances the UV absorption and increases the

visible transparency of thefilms

To the best of our knowledge, the correlation between the

UV-absorption behavior and the free volume hole was for the first

time scrutinized Our experimental results clearly show that the

PALS are useful to understand the UV-absorption efficiency of

doped polymerfilm mixtures

4 Conclusions

The present research has explored the potential enhancement of

polymer's UV-shielding properties The attention of our study has

been focused on: (i) the analysis of properties of the atomic free

volume defect, (ii) thefiller-PS interfacial interaction and (iii) its

impact on the UV-protecting adequacy of thefilms which have

been investigated and examined by PALS Concussively, the shrink

of free volume hole size due to the highfiller concentrations is a

supporting positron lifetime parameter The calculated value for

the free volume hole size does not show any dramatic disparity

with the high ZnO concentrations revealing the less tunability of

the material for the UV radiation In the case of the TiO2particles,

however, the decrease in the free volume hole size has been

observed because of the rod shaped aggregation of the TiO2

parti-cles which act as nucleating agents contributing to the UV shielding

efficiency of the PS The results as obtained suggest that TiO2and

ZnO acting as activefillers for PS can be used for improving the

tremendous photo-protective shielding quality of the polymeric

materials to be applied in ultraviolet radiation protection Howbeit,

due to the surface free energy of the nanocrystals, ZnO particles

tend to aggregate making them obscured to attain a homogeneous

dispersal and that results in opaque compositefilms Therefore, the

main efforts should be focused on the nanocrystals without

ag-gregation in the PS

Acknowledgement

The authors are grateful to Dr Y.K Vijay (Prof.) at University of

Rajasthan, Jaipur for providing the experimental facilities to study

the positron lifetime and Dr Balram Tripathi for helping in the

analysis of the experimental data The authors also thank the

anonymous reviewers for their extremely insightful comments We

would like to convey our excellent gratitude to Prof Nguyen The

Hien Vietnam National University, Hanoi, Vietnam for the language

editing and formatting of the article Thefinancial support from

MPCST Bhopal is gratefully acknowledged

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