Abstract

Polyaniline- (PANI) praseodymium Oxide (Pr2O3) composites have been synthesized by in situ polymerization method with different weight percentages. The synthesized composites have been characterized by Fourier transform infrared spectroscopy, X-ray diffraction and scanning electron microscopy. The temperature dependent conductivity shows that the conductivity is due to the hopping of polarons and bipolarons. These composites show negative thermal coefficient (α) behavior as a function of temperature, which is characteristic behavior of semiconducting materials. Sensor studies have been carried out by two-probe method and found that the sensitivity increases with increase in % RH. It is noticed that stability increase is due to the presence of Pr2O3 in polyaniline up to 30 wt%. A fast recovery and response time along with high sensitivity make these composites suitable for humidity sensors.

1. Introduction

Conducting polymer has achieved more attention towards the humidity sensing application in present era due to its low weight, easy processing, and high absorption capability because of its porous nature [1]. Among the large variety of conducting polymers, polyaniline (PANI) has emerged as the most promising one because of its diverse properties like relatively inexpensive monomer, easy preparation, high yield of polymerization, environmental stability, and unique processability for device fabrication [2, 3]. The various techniques such as electrochemical polymerization, chemical oxidation, and electrochemical deposition and spin coating have been explored for the fabrication of polymer sensors [4]. Advantages with polymers as sensing materials are light weight, flexible, low cost, and simple fabrication process. Polyaniline has shown very promising results for sensing applications in comparison to other classical sensor materials employed in the fabrication of sensors [5, 6]. Various oxide doped polymer composite materials have been examined as the humidity sensor; for example, ZnO, CdO, and WO3 are reported to exhibit high sensitivity toward humidity [7, 8]. However, further improvements in the performance of the mixed-potential type polymer sensors are still needed in order to realize a commercially viable device of this type [9]. Basically, polymer metal oxide is used in humidity sensor applications and is prepared by conventional and advanced wet chemical processing methods at room temperature and is mainly developed to offer porous bodies. The advantage of an absorbent spongiform surface rather than a condensate is a greater permeability of water molecules, so water vapor molecules can easily pass through the pore openings and capillary condensation occurs in the capillary porous structures which are formed between the grain distributions in ceramic surface during the pore removal process.

The proper control of the surface composition of polyaniline-metal oxide humidity sensors is essential for obtaining rapid, reliable, and selective response to the adsorption of water vapor [10]. As a result of the compositional changes, the nature and extent of acidic and basic sites on the surface are altered drastically and often the resultant oxide surface behaves as a better proton acceptor/donor depending on the nature of the dopants, leading to enhanced humidity sensitivity [1113]. Parvatikar et al. synthesized composites of PANI with metal oxides such as WO3 [14], Co3O4 [15], and CeO2 [16] by using chemical polymerization and investigated the humidity sensing properties. The electrical and optical properties of polyaniline are easily tunable by doping inorganic or organic compound [1719]. These properties show a possibility of using these polymers as a humidity sensing materials. Various researches have shown that conducting polymer-metal oxide nanocomposites are also convincing humidity sensors because of their good stability and high surface to volume ratio [1820].

In this work, PANI-Pr2O3 composites have been prepared by in situ polymerization method with various weight percentages. The structural property and surface morphology have been analyzed by using Fourier transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), and scanning electron microscope (SEM). Further the DC conductivity and humidity sensing behavior of these composites have been studied by using Kelvin two-probe techniques.

2. Experimental

All chemicals used for synthesis are of analytical reagent (AR) grade. Aniline, ammonium peroxydisulphate (NH4)2S2O8; (APS), hydrochloric acid (HCl), and Pr2O3 have been purchased from Sigma-Aldrich, India. Aniline monomer is doubly distilled before use. The composite samples so synthesized are processed into circular pellets of 10 mm diameter and 2 mm thickness by applying pressure of 10 ton in a UTM-40 machine (40 Ton Universal Testing Machine) using a hydraulic press. For conductivity measurements, the pellets are coated with silver paste on either side of the surfaces to provide good electrical contacts.

2.1. Synthesis of Polyaniline

Aniline (0.1 mol) is dissolved in 1 M hydrochloric acid for 20 min to form aniline hydrochloride. The above solution is refluxed with 1 mL of camphor sulphonic acid (CAS) which acts as a surfactant for 3 hours at 0°C to 5°C. Further, 0.1 M of ammonium persulfate [(NH4)2S2O8] is added to the refluxed solution which acts as the oxidant and is added drop-wise with continuous stirring for 6 hours at ice temperature and is kept 24 hours without stirring for complete polymerization. The green precipitate powder is recovered using vacuum filter and washed with 0.1 HCl in order to remove the excess chlorine ions followed by water and acetone to remove the excess ammonium persulfate and unreacted monomers from the composites. Finally the resultant precipitate is dried under dynamic oven for 24 hours to achieve a constant weight [21, 22].

2.2. Synthesis of PANI-Pr2O3 Composites

0.1 mol aniline is dissolved in 1 M hydrochloric acid and to this known amount of Pr2O3 (10, 20, 30, 40, and 50 wt%) is added and stirred for 20 min to form metal oxide suspended aniline hydrochloride. The above solution is refluxed for 3 hours at 0°C to 5°C with 1 mL of camphor sulphonic acid (CAS) which acts as a surfactant. Further, 0.1 M of ammonium persulfate [(NH4)2S2O8] is added to the refluxed solution which acts as an oxidant and added drop-wise with continuous stirring for 6 hours at ice temperature and is kept 24 hours without stirring to complete the polymerization. The green precipitate powder of PANI-Pr2O3 composite is recovered by using vacuum filter and washed with 0.1 HCl in order to remove the excess chlorine ions followed by water and acetone to remove the excess ammonium persulfate and unreacted monomers from the composites. Finally the resultant precipitate is dried under dynamic oven for 24 hours to achieve a constant weight.

3. Characterization

The above synthesized PANI-Pr2O3 composites are structurally and surface morphologically characterized by using different techniques like FTIR, X-ray diffraction (XRD), and scanning electron microscopy.

The FTIR spectra of polyaniline and its composites are recorded on Perkin Elmer (model 783) IR spectrometer in KBr medium at room temperature. For recording FTIR spectra, sample powders are mixed with KBr in the ratio of 1 : 25 by weight and grounded to ensure the uniform dispersion of samples in KBr pellets. The mixed powders are pressed in a cylindrical dye to obtain clean discs of approximately 1 mm thickness [23].

The X-ray diffraction patterns of the prepared samples are obtained by employing Philips X-ray diffractometer using radiation ( Å). The diffractograms are recorded in terms of 2 in the range 10°–80° with a scanning rate of 2° per minute.

The surface morphology of polyaniline and its composites are studied by using Phillips XL30 ESEM scanning electron microscope (SEM). The powder samples are dispersed on the surface of carbon tape mounted on aluminum tab and conducting gold is sputtered on the sample to avoid charging at the sample surfaces and hence selected areas are photographed.

3.1. DC Conductivity Measurements

A typical experimental setup used for the measurement of dc conductivity consists of a sample holder securely locating the sample coated with silver paste in order to get better contact inserted from top aperture of the heating furnace. A potential difference is applied across the sample. The electrodes and thermocouple leads are taken out from top aperture and connected to Keithely 2100 electrometer to measure the change in current of the samples and temperature indicator, respectively. A heater placed at the bottom of the furnace is capable of giving a variable but linear rate of temperature increases over a broad range of temperatures. The DC conductivity of all the samples is obtained by measuring current flowing through a piece of the material and using the sample dimensions σ can be calculated using where(cm) is the sample thickness.is its area (cm2),  is the potential difference across the material, and is the current flowing through the material.

3.2. Fabrication of Humidity Sensor Set Up

Humidity sensor chamber is made up of side glass plates of size 250 mm × 250 mm in dimension and 5 mm thickness provided with top and bottom glass plates. The chamber is made airtight by rubber beading [13, 24]. The sample holder is then fixed at the central part of the chamber and dc fan at the left corner in order to distribute the humidity uniformly throughout the chamber. The vapors are allowed to pass through the bottom of the left side inlet which is controlled by using dimmer stat. The percentage of humidity in the chamber is monitored by using hygrometer and changes in the resistance of the samples are measured by Keithley meter. Thermal filament is inserted in right side of the bottom connected to the temperature indicator. The right upper side is connected to vacuum pump to dehumidify the chamber for the next cycle/sample. The block diagram of the sensor setup is shown in Figure 1.

4. Results and Discussion

4.1. Characterization

Figures 2(a) and 2(b) show the X-ray diffraction pattern of (a) Pr2O3 and (b) PANI-Pr2O3 composite (30 wt% of Pr2O3 in PANI). It is seen from the figure that the cubic peak of praseodymium oxide indicates the crystalline nature of the composite. By comparing the XRD pattern of composite with that of Pr2O3 (JCPDS No. 47–1111) the prominent peaks corresponding to 2 = 26.75°, 56.09° are due to (100) and (100) planes of Pr2O3. By comparing the XRD patterns of the composite and Pr2O3, it is confirmed that Pr2O3 has retained its structure even though it is dispersed in PANI during polymerization reaction [25].

Figure 3(a, b, and c) shows FTIR spectra of the pure PANI, Pr2O3, and PANI-Pr2O3 composite. Figure 3(a) represents the FTIR spectra of pure PANI. The strong peaks in wave number are in the range 1000–1600 cm−1, attributed to the vibrational bands. The band at 504 cm−1 is due to CH out of plane bending vibration. The bands at 1561 and 1450 cm−1 are attributed to C=N and C=C stretching mode of vibration for the quinoid and benzenoid units of polyaniline. The bands at 1301 and 1421 cm−1 correspond to the characteristic of pure polyaniline [26, 27]. The FTIR spectra of the composite (Figure 3(c)) exhibit the characteristic peaks similar to that of pure PANI with a small shift in the characteristic peaks corresponding to that of the pure PANI. The characteristic peaks of Pr2O3 completely disappear in the IR spectra of composite which reveals the strong interaction between PANI backbone and Pr2O3 particles during the formation of composite.

Figures 4(a), 4(b), and 4(c) show the surface morphology of pure PANI, Pr2O3, and PANI-Pr2O3 composite (50 wt%) recorded using SEM. Figure 4(a) shows the SEM micrograph of pure PANI with smooth surface having micro pores. The SEM image of Pr2O3 in Figure 3(b) shows an agglomerated particle structure having uniform distribution. Figure 4(c) shows the SEM micrograph of PANI-Pr2O3 (30 wt%) composite. From the micrograph of composite, one can clearly observe the uniform distribution of Pr2O3 particles in PANI matrix with the formation of more capillary pores and a conducting network. These capillary pores facilitate the absorption of more water molecules leading to enhanced humidity sensitivity in the composite compared to pure PANI.

4.2. D.C. Conductivity

Figure 5 shows the variation of DC conductivity as a function of temperature for polyaniline and polyaniline-Pr2O3 composites for different weight percentages. It is observed that the conductivity of polymer composites increases with increase in temperature as well as increase in dopant percentages. The three-step conductivity is observed in the range of 30°C to 180°C. In first step, the temperature from 30°C to 60°C the conductivity of the pure polyaniline and it remains constant because insufficient activation energy fails in hopping of polaron from one island to other [28]. In second step from 60°C to 130°C, the conductivity increases gradually due to the hopping of polarons and bipolarons in short range order. Further, in third step from 130°C to 180°C the conductivity suddenly increases due to hopping of charge carriers in long range order. The three-step conductivity is characteristic property of amorphous semiconducting materials explained by Mott theory. Among all composites 30 weight percentage polyaniline-Pr2O3 Composite shows high conductivity due to the elongation of polymer chain in framed network favorable of hopping polarons in long range orders. The conductivity of other composites like 10, 20, 40, and 50 followed 30 wt% and its conductivity is lower due to the partial blocking of polarons at the interface of two composite islands. However the expansion of composites is confirmed from thermal coefficient plot as shown in Figure 6. It is observed that the composite shows negative thermal coefficient (NTC) behavior as a function of temperature. The NTC value decreases with increase in metal oxide percentage in polymer matrix due to decrease in the distance between two grains [29]. It is also known that the thermal expansion will cause significant stress in the matrix as the filler does not allow expansion or contraction, which increases the electron density at the junction, causing the blocking of charge carriers [20, 30].

4.3. Humidity Sensing Properties

Figure 7 shows the change in resistance as a function of humidity from 15% RH to 95% RH at room temperature. It is found that the change in resistance increases with increase in percentage of relative humidity (% RH) due to the uncurling of polymer chain giving more favorable path for conduction of charge carriers. The proposed mechanism for change in resistance of these polymer composites is adsorption and desorption of humidity. In lower humidity level the change in the electrical resistance is slow due to the lower adsorption limit (LAL), where uncurling process of the polymer is very slow leading to large distance of hopping sites. At higher humidity, composites absorb more vapor from a long conduction path as shown in Figure 8. Hence change in resistance decreases suddenly [31]. It is important to note that the pure polymer shows large change in resistance but above 30% RH the polymer becomes unstable and starts degrading as results change in resistance almost constant. Among all composites, 30 wt% of polyaniline-Pr2O3 composite shows linear decrease of change in resistance throughout the range indicating that these composites are more stable and help in holding the vapor molecules. Another possibility is when composites are exposed to humidity, in the first stage of the interaction a few water vapour molecules are chemically adsorbed (chemisorption) at the neck of the crystalline grains on activated sites of the surface, which is accompanied with a dissociative mechanism of vapour molecules to form hydroxyl groups (two hydroxyl ions per water molecule). As an interaction between the surface ions of the grain necks and the adsorbed water, the hydroxyl group of each water molecule is adsorbed on metal cations which are present in the grains’ surfaces and possess high charge carrier density and strong electrostatic fields, thus providing mobile protons. The protons migrate from site to site on the surface and react with the neighbour surface O2− groups (oxygen) to form a second hydroxyl (OH) group. The chemisorbed layer is the first formed layer so once it has formed on the surface it will not change further by exposure to humidity. As a second stage, after chemical completion of the first layer, subsequent water vapour layers are physically adsorbed (physisorption) on the first formed hydroxyl layer and stack to form the physisorbed hydroxyl multilayer. After forming the first physisorbed layer, another water molecule adsorbs via double hydrogen bonding to two neighbouring hydroxyl groups. As water vapour continues to increase in the surface, an extra layer forms on the first physisorbed layer; therefore the physisorption changes from monolayer to multilayer. These layers are less ordered than the first physisorbed layer, and water vapour molecules in these layers may be only singly bonded to local hydrogens.

Finally, by forming more layers, a large amount of water molecules is physisorbed on the necks and flat surfaces, hence singly bonded water vapor molecules become mobile and able to form continuous dipoles and electrolyte layers between the electrodes, resulting in an increased dielectric constant and bulk conductivity. Therefore, the slight variations of conductivity with humidity adsorption can be due to a water protonation and polarons conduction mechanism on the composite surface.

The sensitivity of detecting the humidity is defined by the percentage change in resistance per 10% change in the value of relative humidity [32]. The variations in the resistivity as a function of relative humidity (RH) value for PANI/Pr2O3 composite in the form of pellets for five different weight percentages (10, 20, 30, 40, and 50 wt%). The percentage of sensitivity for detection of humidity is defined as whereis the resistivity of the sample for humidity at level 2 (highest RH level) and RH1 is the resistivity of the sample for humidity at level 1 (lowest RH level). Figure 9 shows the sensitivity of polyaniline and polyaniline-Pr2O3 composites as a function of relative humidity for different weight percentages. The sensitivity is measured from RH 20% to RH 95%. It is found that the sensitivity increases with increase in relative humidity. Among all composites 30 wt% shows high sensitivity and more stability in long range of RH % followed by other composites which shows almost similar behavior [33, 34]. These composites above 30 wt% the absorption is good but as the polymer percentages is more than metal oxide fails to hold the water vapor for longer time as a results after some period of exposing with humidity starts saturating the surface. Hence sensitivity decreases. In case of pure polyaniline sensitivity even more than composites but the stability of the polyaniline loses above 50% RH and starts degradation of polymer.

The vapor is removed from the humidity chamber by using vacuum pump but we cannot remove it completely from the samples. Therefore once the humidity of chamber attends 40% RH, heating should be switched on till the electrical resistance comes to base level in order to start next cycle. Figure 10 shows the response and recovery curves corresponding to water adsorption and desorption process for 10, 20, 30, 40, and 50 wt% of PANI/Pr2O3 composites. The average response time of PANI/Pr2O3 composite is 377 seconds and the recovery time is 453 seconds as the humidity changes from 15% to 95% RH. Among all composites 30 wt% shows first response to humidity and less recovery time. Therefore these polymer composites can be used in food industries, domestic storage chamber, packing industries, solar cell, battery, and so forth.

5. Conclusions

In this paper, we have reported humidity sensing properties of polyaniline-Pr2O3 composites prepared by in situ polymerization. The SEM micrograph of the composite shows the encapsulation of Pr2O3 in PANI matrix and reveals the presence of capillary pores which facilitate the sensing behavior. From the XRD spectrum of PANI-Pr2O3 composite, it is evident that with the Pr2O3 content in PANI, the peak intensity corresponding to both PANI and Pr2O3 is modified which confirms coexistence of PANI and Pr2O3 phase in the composite. The FTIR spectrum reveals the formation of composite with strong interaction between PANI chains and Pr2O3 particles. The humidity sensing mechanism is investigated using homemade two-probe method. The studies on temperature dependent conductivity of the composite at various humidity levels have shown the increase in sensitivity for the composite with increase in %RH. Among all composites, 30 wt% of PANI-Pr2O3 composite shows high sensitivity and exhibits the maximum humidity sensing response and shorter response-recovery time. Hence our studies suggest that PANI-Pr2O3 composite can be a promising material for high performance humidity sensing applications.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.