Open Access
Numéro
Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles
Volume 76, 2021
Numéro d'article 67
Nombre de pages 15
DOI https://doi.org/10.2516/ogst/2021043
Publié en ligne 6 octobre 2021

© Reena et al., published by IFP Energies nouvelles, 2021

Licence Creative CommonsThis is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1 Introduction

Continuous increase in demand for energy and drastic decrease in the number of discoveries of new oil and gas fields across the globe have compelled the petroleum industries to increase the life of existing well in mature oil fields (Liu et al., 2010; Ma et al., 2019; Saikia and Sultan, 2020). In addition to this, an average oil recovery factor is as low as 30%, i.e., around 70% of oil remains in the unswept hydrocarbon zones of reservoirs with severe heterogeneity (Kumar et al., 2020; Liu et al., 2017). Therefore, it has become necessary to prolong the life of mature hydrocarbon fields by using several techniques viz. advanced reservoir characterization, artificial-lift optimization, water shut-off, and different enhanced oil recovery methods (Abdulbaki et al., 2014; Kumar et al., 2020). Excess water production is one of the significant problems over time while producing petroleum reserves which has a severe impact on the technical, environmental, and economic life of production well (Kalgaonkar et al., 2017; Tongwa and Baojun, 2015). Moreover, it has been estimated that an average cost of more than 40 billion US dollars is spent annually across the world to attenuate undesirable water from oil (Bailey et al., 2000). Recently, in mature oil fields, excess water production problems have drawn considerable attention as water production usually exceeds the economic limit, thus, compelling the petroleum industries to apply water shut-off techniques (Dang Cuong et al., 2011; Xindi and Baojun, 2017).

Reservoir heterogeneity due to induced fractures or high permeable streak is one of the pivotal factors of surplus water production which eventually leads to low sweep efficiency and reduction in petroleum recovery (Elsharafi and Bai, 2012; Kumar et al., 2019). Heterogeneity within the formation prevents the injected fluid from sweeping the unproduced oil from the mature oil fields, thus, causes higher Water to Oil Ratio (WOR) in the production well (Farasat et al., 2017; Liu et al., 2016). In addition to this, due to prolong water flooding in the reservoir for pressure maintenance in the reservoir results in a high water cut. The breakthrough within the producing well is a repercussion of heterogeneity along the high permeable zones which ultimately responsible for the abandonment of the production well (Sang et al., 2014; Sharifpour et al., 2015). In recent decades, various kinds of water shut-off techniques are purposed to improve the efficiency of unswept zones which directly impacts the incremental oil recovery (Elewaut et al., 2005). To overcome the issue of excessive water production due to the presence of reservoir heterogeneity, various chemical methods e.g., polymer, in-situ gel systems, particle gel systems, foams, etc. have been widely used in the oilfield globally (Al-Anazi and Sharma, 2002; Al-Muntasheri et al., 2007; Fuseni et al., 2018; Goudarzi et al., 2014; Wassmuth et al., 2004; Zhao et al., 2014). Among them, crosslinked in-situ polymer gel systems have been a cost-effective method and are usually applied for enhancing oil recovery by controlling excessive water production in mature oil fields (Moradi-Araghi, 2000; Zhu et al., 2017). In this technique, a polymer and crosslinker solution called gelant is injected into the formation to form a 3D gel network structure under reservoir conditions (pH, salinity, and temperature) to reduce the permeability of high permeable streak (Seright, 1991; Sydansk and Moore, 1992).

The major challenges associated with techniques are lack of control on gelation time, dilution of the gelant solution, loss of constituents because of adsorption on the rock surface and most of the time destabilization due to severe conditions (Goudarzi et al., 2015; Tongwa and Baojun, 2015). These challenges are encountered by the development of the nanocomposite hydrogel as it has better properties (i.e., thermal and mechanical stabilities) as compared to that of conventional hydrogels (Adewunmi et al., 2018; Lashari et al., 2018). Most of the researchers developed and widely studied nanocomposite hydrogels by reinforcing fillers in the hydrogel matrix. Among the most commonly used reinforced materials are nano-silica (Chen et al., 2018; Lashari et al., 2018), fly ash (Jiang and Liu, 2014; Singh et al., 2018), clays (Aalaie et al., 2008; Helvacıoğlu et al., 2011; Okay and Oppermann, 2007; Tongwa et al., 2013), and carbon nanotubes (Evingür and Pekcan, 2014; Li et al., 2016; Sudha et al., 2014). However, organically modified fillers were also used to enhance the properties of hydrogel (Helvacıoğlu et al., 2011; Rezaei et al., 2016).

The present research work introduces zinc oxide as nanofiller material in nanocomposite hydrogel. The development of this research work is as follows: (1) the nanofiller material Zinc Oxide (ZnO) was obtained by biosynthesis of plant extract from Moringa oleifera leaves; (2) a Zinc Oxide (ZnO) reinforced nanocomposite hydrogel was synthesized from PolyVinyl Pyrrolidone (PVP); as polymer, Resorcinol and Formaldehyde (RF); as crosslinker and ZnO; strength modifier; (3) the effect of nano zinc oxide on gelation time and gel strength was investigated at reservoir temperatures (4) thermal and rheological properties were studied; and (5) effectiveness of the nanocomposite hydrogel for water shut-off was examined using sandpack flooding experiments.

2 Material and experimental methods

2.1 Materials

PolyVinyl Pyrrolidone (PVP) (K-30, 98.0%, M.W.: 40 000) was procured from Central Drug House Pvt. Ltd., India. Resorcinol and Formaldehyde (RF) were procured from Fisher Scientific with a purity of 99.0% to prepare crosslinker. Calcium chloride (CaCl2), sodium hydroxide (NaOH) and sodium chloride (NaCl) were bought from Molychem, India. Sodium hydroxide is used to maintain the pH of the gelant solution between 8 and 9.

2.2 Biosynthesis of ZnO nanoparticles from plant extract (Moringa oleifera leaves)

Moringa oleifera leaves were used to make the plant extract. Leaves were washed properly using distilled water. After that, leaves were dried in sunlight for 2–3 days. They were crushed into powdered form and heated with water for 2 h. Further, Zinc acetate was added to the leaf extract and this extract was stirred for 6 h at 90 °C. The basic pH was maintained in the solution. Finally, the solution was filtered and washed with water and ethanol. The overall procedure was followed as per the research article of Srivastava and Choubey (2020).

2.3 Reinforced nanocomposite hydrogel preparation

PolyVinyl Pyrrolidone (PVP) solution (1.0 wt.%) was prepared using 1.0 wt.% NaCl. The polymer solution was aged for 24 h at room temperature (298 K). ZnO (0.2 wt.%, 0.5 wt.%, 0.8 wt.% and 1 wt.%) was added to 5 mL distilled water and these samples were sonicated for 30 min for complete homogenization. Resorcinol (2.0 wt.%) Formaldehyde (RF) was used as a crosslinker (R:F/1:0.1). After that, ZnO was mixed in the polymer solution. Digital ultrasonic cleaning was immediately performed in the solution of PVP-ZnO and homogenized for one hour. After complete homogenization, freshly prepared crosslinker solution (at room temperature) was added to the solution and stirred for 30 min. The pH of PVP:RF (Polyvinyl Pyrrolidone – Resorcinol-Formaldehyde) and PVP-ZnO:RF (Polyvinyl Pyrrolidone – Zinc Oxide – Resorcinol-Formaldehyde) hydrogels were adjusted approximately 9. Eutech digital pH meter was used to maintain the pH of gel samples. The electrode of the pH meter was stored in 4M KCl solution at room temperature. Initially, the prepared gelant solutions (PVP:RF & PVP-ZnO:RF) have a pH value between 4 and 5 (low pH). In gel samples, higher pH was maintained (approximately 9) by adding few drops of 1M NaOH solution and continuously checking the pH value until it reaches around 9.

The ratio of polymer and crosslinker solution was 1:0.25. Lastly, the gelling solutions were poured into the ampoules (30 mL) and ampoules were sealed at the neck using Teflon tape. Sealed ampoules were finally kept in an oven at 90 °C.

Furthermore, the effect of salinity and temperature was also examined in conventional (PVP:RF) and reinforced nanocomposite (PVP-ZnO:RF; 0.5 wt.% ZnO) hydrogels. The pH of the gelling solution was raised from approx. 5 to approx. 9 by adding few drops of 1M NaOH solution. The salinity effect was probed by using NaCl and CaCl2 salts. In the gelation study nanocomposite hydrogel (PVP-ZnO:RF; 0.5 wt.% ZnO) sample was compared with conventional hydrogel (PVP:RF).

2.4 Characterization of ZnO filler

The UV-vis spectrum measurements were performed using Lab India UV-Vis 3200 spectrophotometer over the region 300–800 nm by a 10 mm path length quartz cuvette. Powder X-Ray Diffraction (PXRD) data were evaluated by using a PANalytical X’pert Pro MPD diffractometer. The crystallinity of the samples was checked in the range of 20–80° (2θ) with monochromatic radiation Cu Kα.

2.5 Characterization of hydrogels

Field Emission Scanning Electron Microscope (FESEM) images of gel samples were recorded to elucidate the morphological structure of gels. Before placing gel samples in a high vacuum environment, these samples were completely dried in an oven at 60 °C. Proper drying of samples is an important parameter in FESEM analysis, otherwise, water evaporation will interfere and reduced image clarity of the sample surface. Images of samples are generated by operating FESEM in reflection mode. The conductive surface of the sample is required during this analysis. For this purpose, a thin layer of conductive surface is coated on the insulated sample surface. The gold coating was used for these gel samples for 105 s. The microstructure of gel systems was examined using a Field Emission Scanning Electron Microscope (FESEM) on FESEM Zeiss Supra 40 (accelerating voltage ranged 15 kV).

Energy Dispersive X-Ray (EDX) analysis was also conducted on FESEM Zeiss Supra 40 (accelerating voltage ranged 15 kV) to identify the elemental composition of materials. The FTIR analysis of the samples was conducted for the functional group of the synthesized hydrogels using the Perkin Elmer Spectrum PIKE MIRacle spectrometer. The thermal stability of hydrogel systems was depicted from the Differential Scanning Calorimetry (DSC) profiles which were recorded on a Perkin Elmer DSC 4000 under an N2 atmosphere (20 mL/min). The hydrogel samples (15–20 mg) were kept in an aluminum pan for thermal analysis in the temperature range of −20 to 200 °C with a continuous heating rate of 3 °C min−1.

2.6 Determination of gelation time and gel strength

The bottle testing method was adopted (Tab. 1) to investigate the gelation time of nanocomposite (PVP-ZnO:RF) and conventional (PVP:RF) hydrogels as this is an inexpensive method (Reena et al., 2020; Sydansk, 1990). The gelant solutions were visually checked after a specific time interval (at 50–90 °C) to find out the gelation time.

Table 1

Gel strength codes of Bottle testing method are listed below.

The strength of gel samples can easily be influenced by several factors, viz. salinity, temperature, polymer-crosslinker-nanoparticles concentration. Generally, the breakthrough vacuum method is used to determine the gel strength of gel samples because it is a cost-effective method. The experimental set-up for this method is shown in Figure 1. In this set-up, two suction flasks were used in series in this method. A glass tube was connected to one suction flask which was dipped in the ampoule containing gel sample. Another suction flask was connected to a vacuum pump. During the experiment, a sample tube containing 25 mL gel was taken. After that, a glass tube was placed into the sample tube and the vacuum pump was started. The suction pressure starts increasing and after a specific pressure, it falls rapidly. The maximum pressure attained was noted as gel strength because at this pressure gels rupture. All the experiments were repeated thrice to reduce the errors during experimentation and the reported final data is the average of the three results obtained from this experiment.

thumbnail Fig. 1

Schematic diagram of the breakthrough vacuum method.

2.7 Rheological measurements

Viscoelastic behaviour of prepared hydrogels (i.e., hydrogels synthesized at 90 °C) was evaluated using a compact rheometer with a cone plate sensing system (MCR-52, Anton Paar, and Physica, Austria). The prepared gels were placed into the cone and plate setup after gelation. The frequency sweep test was conducted in the frequency range of 1 Hz to 100 Hz at a constant strain of 1%. All the experiments are performed at room temperature (298 K).

2.8 Water shut-off performance

To simulate conventional and nanocomposite hydrogel’s plugging capacity in high permeable streaks present in mature oil fields, sandpack flooding experiments were carried out at reservoir conditions (75 °C). The sandpack flooding experiments consist of a Teledyne’s ISCO model 500D syringe pump, two cylinders for fluid injection (brine and gelant), a stainless-steel core holder (length – 15 cm and diameter – 3 cm), a pressure gauge and a measuring cylinder for collecting the effluent fluid as shown in Figure 2. The method for sandpack flooding for determining water shut-off was the same as followed by many researchers (Karimi et al., 2014; Zhao et al., 2015). Firstly, the sandpack was prepared by ramming of sand in the core holder so that proper packing can be done. Secondly, brine (10 000 ppm of NaCl) was injected into the sandpack at a constant flow rate of 1 mL/min and the permeability of the sandpack (before gel formation) can be determined using the Darcy equation (1) (Singh et al., 2018),

k=QμLAP,$$ k=\frac{Q\bullet \mu \bullet L}{A\bullet \Delta P}, $$(1)where, μ = viscosity of the brine (cP), Q = flow rate (cm3/s), L = Length of sandpack (cm), ΔP = differential pressure (atm), A = cross-sectional area of sandpack (cm2) and k = permeability of the sandpack (Darcy).

thumbnail Fig. 2

Schematic experimental set-up for sandpack flooding studies.

Thirdly, the 3–4 pore volume of prepared gelant solution of nanocomposite hydrogel (PVP-ZnO:RF) was injected into the sandpack and the effluents were collected into the measuring cylinder (Fig. 2). This collected effluent was kept in ampules and put in the oven with the sandpack holder. The sandpack was kept approximately 3 times greater than the gelation time of effluent gel samples kept in ampules. After giving enough time to sandpack for complete gelation, brine was again injected into the sandpack and again permeability of sandpack (after gel formation) was calculated. The same procedure was adopted for sandpack flooding using conventional hydrogel (PVP:RF) for comparing against the results obtained during sandpack flooding with nanocomposite hydrogel (PVP-ZnO:RF). The Residual Resistance Factor (RRF) and percentage permeability reduction have reckoned the formulae given in equations (2) and (3), respectively:

RRF=λwiλwa=KwiμwaKwaμwi,$$ \mathrm{RRF}=\frac{{\lambda }_{{wi}}}{{\lambda }_{{wa}}}=\frac{{K}_{{wi}}{\mu }_{{wa}}}{{K}_{{wa}}{\mu }_{{wi}}}, $$(2)where, λwi = water mobility before gel treatment, λwa = water mobility after gel treatment;

PPR=(1-KwaKwi)×100,$$ \mathrm{PPR}=\left(1-\frac{{K}_{{wa}}}{{K}_{{wi}}}\right)\times 100, $$(3)Kwi = permeability before gel treatment and Kwa = permeability after gel treatment.

3 Results and discussion

3.1 UV-Vis spectra and PXRD analysis of ZnO

The UV-Vis spectrum of the synthesized nanoparticles is depicted in Figure 3a. An absorption peak at 358 nm represents the ZnO nanofiller’s characteristic peak.

thumbnail Fig. 3

(a) UV-Vis spectra of pure ZnO, (b) PXRD spectra of pure ZnO nanofiller.

The crystalline nature of the material synthesized is determined by using the Powder X-Ray Diffraction (PXRD) analysis. The output obtained through PXRD of synthesized ZnO nanofiller was compared with the Joint Committee on Powder Diffraction Standards (JCPDS) card and the synthesized nanofiller gave characteristic peaks having 2θ values 31.79°, 34.88°, 36.48°, 47.63°, 57.03°, 63.16°, and 68.18° which were indexed to (1 0 0), (0 0 2), (1 0 2), (1 1 0), (1 0 3) planes of the hexagonal phase of the wurtzite crystal structure of ZnO. The data is in agreement with the standard JCPDS card 36-145 (Fig. 3b). The average particle size of the ZnO nanofiller was determined to be 10 nm using Debye Scherrer’s equation (Bokuniaeva and Vorokh, 2019; Langford and Wilson, 1978), which is given as follows:

D=KλBcos θ,$$ D=\frac{K\lambda }{B\mathrm{cos}\enspace \theta }, $$(4)where, D = Average size of nanofiller (ZnO), K = constant (0.9), λ = X-ray wavelength in Ǻ, B = the full width at half maximum of an angular peak in radians, θ = the Bragg’s diffraction angle in radian.

3.2 Reaction scheme

Hydrogen bonding between polymer chains and nanoparticles is generally carried out by using a crosslinker. Initially, the polymer solution was prepared along with ZnO. After that, a crosslinker was prepared. Figure 4a represents a reaction between Resorcinol and Formaldehyde (RF) and Figure 4b illustrates the condensation reaction of crosslinker formation. Crosslinker (resorcinol-formaldehyde) formation reaction was adapted from Gaca and Sefcik (2013) and Gaca et al. (2017). This reaction is carried out before the crosslinking of PVP and green root synthesized ZnO. After RF formation, it is expected to increase the interaction between PVP and ZnO by the reacting –OH group of RF with C–O bond of PVP and Zn metal of ZnO following the hydrogen bonding. Hydrogen Bonding between PVP, RF and ZnO is illustrated in Figures 4c and 4d. ZnO reacts with both polymer and crosslinker (Jaisai et al., 2012; Mallakpour and Javadpour, 2016). Also, PVP-ZnO:RF interaction is shown in Figure 4d.

thumbnail Fig. 4

(a) Reaction between Resorcinol–Formaldehyde (RF), (b) condensation reaction of RF, (c) hydrogen bonding scheme of PVP:RF, (d) PVP-ZnO, and (e) PVP-ZnO:RF.

3.3 FTIR analysis

Interaction between ZnO and PVP:RF was also examined using FTIR, as depicted in Figure 5. ZnO reacts with the phenyl –OH group and –C–O group of polymer (Gaca and Sefcik, 2013; Michael et al., 2018). PVP:RF and PVP-ZnO:RF (0.5 wt.% ZnO) hydrogels were characterized to confirm the reaction between polymer and crosslinker and the presence of ZnO nanofiller. As shown in Figure 5, PVP:RF with and without ZnO gives a peak –(C–N) = 1284 cm−1, –(C=O) = 1639 cm−1, –(C–H) = 3060 cm−1, and –(O–H) 3321 cm−1 due to hydrogen bonding of PVP with RF. In PVP-ZnO:RF hydrogel, a strong absorption peak was observed at 2342 cm−1; this peak is assigned to be an asymmetrical stretch frequency of –(O–C=O) (Gaca and Sefcik, 2013). The origin of the band at 642 cm−1 is due to the metal-oxygen bond, which confirms ZnO nanofiller’s presence in PVP-ZnO:RF hydrogel (Gaca et al., 2017).

thumbnail Fig. 5

FTIR spectrum of conventional (PVP:RF) and nanocomposite (PVP-ZnO:RF) hydrogels.

3.4 FESEM and EDX analysis

The FESEM image and EDX data for the ZnO nanofiller are shown in Figures 6a and 6b. From the EDX graph (Fig. 6b) it can be deduced that the major constituents of synthesized ZnO nanofiller are Zn (79.2%) and oxygen (20.48%). Figures 6c and 6d show the images of the conventional (PVP:RF) and nanocomposite (PVP-ZnO:RF) hydrogels. Dried gel samples were used to evaluate the surface morphologies of hydrogels. Convention gel (PVP:RF) shows a smooth surface Figure 6c. SEM image of nanocomposite gels (PVP-ZnO:RF) as shown in Figure 6d reveals significant alterations in surface morphology due to the presence of ZnO. From pictures, it can be deduced that ZnO has a considerable impact on the morphology of PVP-ZnO:RF nanocomposite hydrogels. Nanocomposite hydrogel shows a very dense surface, which indicates that ZnO has significant interaction with PVP & RF in the synthesis of PVP-ZnO:RF hydrogel (Li et al., 2017).

thumbnail Fig. 6

(a) SEM image of ZnO nanofiller, (b) EDX spectrum of ZnO. SEM micrographs of investigated gel systems at × 10 000, (c) PVP:RF, (d) PVP-ZnO:RF (0.5 wt.% ZnO).

3.5 Effect of salinity and temperature on hydrogels

3.5.1 Effect of salinity on hydrogels

The effect of salinity was evaluated on Gelation Time (GT) and Gel Strength (GS) for PVP:RF and PVP-ZnO:RF (0.5 wt.% ZnO) rigid hydrogels (I type gels as per Sydansk code) samples. The effect of salinity was studied using NaCl and CaCl2 (0.25–1.0 wt.%) salts solution keeping it at the temperature of 90 °C. It was observed that as the concentration of salts (NaCl and CaCl2) increases, it decreases the gel strength whereas increases the gelation time (Fig. 7). As the sodium ion concentration increases and it accumulates around the polyvinyl pyrrolidone carbonyl ring. Double layer formation happens due to the presence of both anions and cations. Double layer formation contributes to the contraction of polymer chains. There are adverse effects on the gel strength from the presence of divalent cation (calcium). The divalent cation can also cause the deposition of the polymer (Dai et al., 2014; Li et al., 2013).

thumbnail Fig. 7

Effect of (a) NaCl and (b) CaCl2 salt on Gel Strength (GS) and Gelation Time (GT) at 90 °C.

3.5.2 Effect of temperature on hydrogels

Gelation temperature also plays a vital role in gel formation and also affects the gel strength of gel samples. The gelation time of gels can be decreased by a rise in the temperature or vice versa (Park et al., 2020). PVP:RF and PVP-ZnO:RF (0.5 wt.% ZnO) hydrogels were investigated from 50 to 90 °C. Figure 8 shows that gelation time decreases with the temperature rise. The gelling time for the conventional gel system was recorded to be 22 hours at 50 °C, whereas the gelation time of nanocomposite gel was noted to be 18 hours at the same temperature. Gelling time sharply decreased to 10 hours and 8 hours at 90 °C for PVP:RF and PVP-ZnO:RF hydrogels respectively. Due to the interaction between polymer and crosslinker molecules, inner particle forces also increase; therefore, gel strength also increases at high temperatures. At 50 °C gel strength was found to be 22.5 KPa and 25 KPa whereas at 90 °C it was found to be 26 KPa and 29 KPa for PVP:RF and PVP-ZnO:RF hydrogel systems respectively. The results elucidate that nanocomposite hydrogel (PVP-ZnO:RF) has better gel strength with less gelation time in comparison to that conventional hydrogel (PVP:RF). This may be due to as following hypothesis: (i) it has been demonstrated that as temperature rises, the curling degree of the polymer molecular decreases, resulting in a shortening of the intermolecular distance, and the crosslinking agent i.e., twisting of polymer chains which are reduced with the increase of temperature, resulting in a reduction of the intermolecular distance of gel matrix. Therefore, gelation time is reduced and gel strength is enhanced at higher temperatures and vice versa (Zhang et al., 2017). (ii) One more explanation for this finding may be attributed to the fact that increasing the thermal motion of molecules in solution with temperature accelerates the intertwining reaction between polymer molecules and crosslinkers, increasing their ability to agglomerate. Thus, it enhances the gel strength and reduces gelation time and vice-versa (Jia et al., 2016; Zhao et al., 2013).

thumbnail Fig. 8

Effect of temperature on gel strength and gelation time on conventional (PVP:RF) and nanocomposite (PVP-ZnO:RF) hydrogels.

The relationship between Gelation Time (GT) and Temperature (T) is explicated by the Arrhenius-type equation (Al-Muntasheri et al., 2008; Zhao et al., 2013):

GT=MeEaRT,$$ {\mathrm{GT}=M\mathrm{e}}^{\frac{{E}_a}{{RT}}}, $$(5)where, GT = Gelation Time (h) and M = frequency factor (h), Ea = activation energy (KJ/mol), R = gas constant (KJ/mol K) and T = Absolute temperature (K).

Equation (5) can be again modified as follows:

lnGT= EaRT+lnM.$$ \mathrm{ln}\mathrm{GT}=\enspace \frac{{E}_a}{{RT}}+\mathrm{ln}M. $$(6)

As we can see from equation (6), there is a linear relationship between ln GT and the inverse of temperature (1/T). It is depicted in Figures 9a and 9b. As calculated from the slopes of graphs (Figs. 9a and 9b), the activation energy was obtained to be 19.786 and 19.098 KJ/mol for PVP:RF and PVP-ZnO:RF hydrogels. Results from the Arrhenius-type plot indicated that in nanocomposite (PVP-ZnO:RF) hydrogel lower activation energy is required in comparison to conventional (PVP:RF) hydrogel to proceed with the gelation reaction. Hence, it leads to a shorter gelation time of nanocomposite (PVP-ZnO:RF) hydrogel gel at higher temperatures (Zhao et al., 2013).

thumbnail Fig. 9

Arrhenius type graph of (a) conventional (PVP:RF) and (b) nanocomposite (PVP-ZnO:RF; (0.5 wt.% ZnO) hydrogels.

3.6 DSC analysis

The thermal stability of a material can be evaluated using DSC analysis. In the present research, PVP:RF and PVP-ZnO:RF hydrogels were characterized using this technique. The evaluation of degradation enthalpy (i.e., the amount of energy required to break the bonds between polymer and crosslinker) helps in determining the bond strength of the interaction between polymer and crosslinker in a crosslinked hydrogel. The stronger the bond strength, the more endothermic energy is consumed to collapse bonds of hydrogel systems. In addition to this, DSC analysis helps to obtain degradation temperature (i.e., the temperature at which the crosslinked chains of hydrogel systems start to disintegrate). At this temperature, PVP chains’ mobility was observed to increase (Asloun et al., 1989).

The strength of the hydrogels is found to be dependent on various direct and indirect interactions occurring within the gel systems (Chua et al., 2007). There are numerous kinds of direct and indirect interactions possible in hydrogels. Direct interactions can occur between the PVP, RF and ZnO, which includes PVP–PVP, PVP–RF, RF–RF, or PVP-ZnO–RF interactions. Indirect interactions transpire due to the presence of water content in hydrogels. From Figure 10 it can be seen that there are three types of water (i) Strong Bound Water (SBW), (ii) Weak Bound Water (WBW), and (iii) Free Water (FW). SBW is non-freezable water and FW is freezable water but WBW can be present as both (Gun’ko et al., 2017). SBW leads to strong indirect interactions in gels because it is directly associated with PVP-ZnO:RF and FW lead to weak interactions between water molecules. The free water is referred to as the water, which gets physically absorbed by the gel system and is bonded to each other via hydrogen bond (weak indirect interaction). On the other hand, the water, which is chemically bound to the polymer surface, is known to be as bound water (strong indirect interaction) as shown in Figure 10 (Liu et al., 2017; Michael et al., 2018).

thumbnail Fig. 10

Schematic representation of free water (weak indirect interaction) and bound water (strong indirect interaction) interactions in hydrogels (Michael et al., 2018; Reena et al., 2020).

From the endothermic peak in the temperature range of 0 – 10 °C, the amount of free water can be calculated as in Figure 11 using the following equations (Liu et al., 2017):

Wf=ΔH/ΔH°,$$ {\mathrm{W}}_f=\Delta H/\Delta H\mathrm{{}^{\circ} }, $$(7)where, Wf = weight fraction of free water; ΔH = the enthalpy required for free water in hydrogels and ΔH° = melting enthalpy value of free water (333.5 J/g);

Wb=1-Wf,$$ {W}_b=1-{W}_{f,} $$(8)and Wb = weight fraction of bound water (Liu et al., 2017).

thumbnail Fig. 11

DSC thermographs for PVP-ZnO:RF (0–1 wt.% ZnO).

Moreover, higher degradation enthalpy suggests a stronger bond between PVP and ZnO nanofiller. Figure 11 shows DSC curves of the PVP-ZnO:RF nanocomposites (0.2 wt.% −1 wt.%) as well as conventional PVP:RF hydrogel alone. PVP:RF and PVP-ZnO:RF (0.2 wt.% and 0.5 wt.%) were rigid gels gel (I type gels as per Sydansk code). PVP-ZnO:RF (0.8 wt.% and 1 wt.%) gels were moderately deformable non-flowing gel (G type gels as per Sydansk code).

From Figures 11a to 11e, two peaks were observed in the DSC profiles of the hydrogel systems.

The first peak of the profile represents the presence of free water in the hydrogel systems while the second peak portrays the degradation temperature (Tdeg) of the hydrogels. It was deduced that a lower amount of free water was attached to the surface of PVP:RF 0.5 wt.% ZnO hydrogel system in comparison to PVP:RF 1 wt.% ZnO hydrogel system. Moreover, in a nutshell, from the graphs (Fig. 11), it can be depicted that with the increase in ZnO nanofiller concentration, the degradation temperature exhibits an increasing trend (i.e., up to 0.5 wt.% ZnO concentration) afterward the addition of ZnO nanofiller shows a decreasing trend of the degradation temperature. It may be due to the shorter length of polymer chains in the hydrogel network or agglomeration of ZnO filler which assisted the polymer molecules to slide over each other at higher ZnO concentrations easily. Low degradation temperatures of hydrogels having a high concentration of ZnO nanofiller may be apparent due to the multiple types of interactions such as ZnO nanofiller-PVP and nanofiller-nanofiller interaction occurring within the gel network (El-Mekawy and Jassas, 2017). Thus, it can be deduced that PVP-ZnO:RF hydrogels with 0.5 wt.% of ZnO are thermally more stable among other PVP-ZnO:RF hydrogels.

3.7 Rheological measurements of hydrogels

The interaction between polymer and nanofiller can also impact the viscoelastic properties of the hydrogels. The strength of the gels can be determined through their rheological properties. These properties include dynamic moduli (i.e., storage modulus (G′) and loss modulus (G″). Solid like behaviour of gel or energy stored by gels which can be recovered are represented by storage modulus (G′) while liquid-like behaviour of gel or dissipated energy and cannot be recovered are represented by loss modulus (G″). The ratio of storage and loss modulus (i.e., G′/G″) is measured as gel strength of hydrogels (Liu et al., 2017). The higher ratio shows solid like behaviour while the lower ratio leads to the liquid-like behaviour of hydrogels.

The ZnO nanofiller’s effect on the rheological behaviour of hydrogels was determined by conducting the frequency sweep test. It was observed from the result that the elastic modulus values (G′) are higher than loss modulus (G″) as shown in Figures 12a and 12b which indicates that the value of elastic modulus is dominating over the value of viscous modulus. Thus, these results suggest a solid or rubber-like behaviour of hydrogel systems. Moreover, there is also no crossover or gel point in the entire frequency range (i.e., 1–100 Hz) which recommends that hydrogel retains its rubber-like behaviour or solid-like behaviour in the whole frequency range. The graphs (Figs. 12a and 12b) show nanofiller’s effect on the dynamic moduli of hydrogels. The value of storage modulus (G′) and loss modulus (G″) shows an increase in value with the rise in ZnO concentrations (i.e., 0.2–0.5 wt.%) whereas the respective values diminish on further increasing the ZnO concentrations (0.8–1 wt.%). The decrease in the dynamic moduli at higher concentrations may be due to the agglomeration of ZnO nanofiller (Arsad et al., 2013). From obtained results, nanocomposite hydrogel (PVP-ZnO:RF) showed higher elastic and loss modulus than conventional gel (PVP:RF) if the ZnO concentration is not too high (i.e., less than 0.8 wt.%).

thumbnail Fig. 12

Frequency sweep test, (a) storage modulus, (b) loss modulus for PVP-ZnO:RF (0–1 wt.%) (T = 298 K).

3.8 Water shut-off performance

To simulate the higher permeable zones, present in mature oil fields sandpack experiments were conducted using both the hydrogels, i.e., conventional hydrogel (PVP:RF) and nanocomposite hydrogel (PVP-ZnO:RF; 0.5 wt.%). The experimental data of the sandpack studies are shown in Table 2.

Table 2

Sandpack study results for PVP:RF and PVP-ZnO:RF.

The value of injection flow rate was maintained at 1 ml/min while testing both the hydrogel systems (i.e., PVP:RF and PVP-ZnO:RF). The respective porosity of both sandpack (i.e., PVP:RF and PVP-ZnO:RF) are found to be 27% and 28%. The corresponding interstitial velocity during the coreflood test is 24.7543 ft/day (or 0.3144 m/h) and 23.8703 ft/day (or 0.30315 m/h) for PVP:RF and PVP-ZnO:RF hydrogels. The initial permeability of the sandpack using brine was found to be 3.82 and 4.26 Darcy respectively for PVP:RF and PVP-ZnO:RF gel systems. After that, the gelant solution was injected into the sandpack and was kept in an oven at a temperature of 75 °C for 3 days to ensure complete gel formation. After gelation, the absolute permeability to brine was measured as 0.30 and 0.13 Darcy respectively for PVP:RF and PVP-ZnO:RF hydrogel systems. Thus, Percentage Permeability Reductions (PPR) were 97% and 92%, respectively for conventional gels (PVP:RF) and nanocomposite (PVP-ZnO:RF) hydrogel systems (Fig. 13). Also, it was found that Residual Resistance Factors (RRF) were 31.31 and 12.71 for nanocomposite and conventional hydrogels respectively (Fig. 13). The higher value of PPR and RRF in nanocomposite hydrogel (PVP-ZnO:RF) compared to conventional hydrogel (PVP:RF) shows that ZnO nanofiller’s use has enhanced its capability to reduce water in heterogeneous layer present in mature oil fields.

thumbnail Fig. 13

Percentage Permeability Reduction (PPR) and the Residual Resistance Factor (RRF) of PVP:RF and PVP-ZnO:RF hydrogels (at 343 K or 75 °C).

The purposed mechanism for water shut-off due to the placement of nanocomposite hydrogel (PVP-ZnO:RF) in the high permeable zone is elucidated in Figures 14a14c.

thumbnail Fig. 14

Schematic of excessive water production problem and water shut-off mechanism, (a) a high permeable zone due to long term waterflooding produces mainly water, (b) gel treatment was done from a producer well, (c) water sweeps untouched low permeable zones after hydrogel placement in the high permeable zone for incremental oil recovery.

In Figure 14a due to the presence of a high permeable zone flooded water is mainly produced leaving the crude oil unswept in low permeable zones. The placement of nanocomposite hydrogel (PVP-ZnO:RF) restricts the flooded water to flow through the high permeable zones (Fig. 14b). Due to the obstruction created by the placement of nanocomposite hydrogel, flooded water is compelled to sweep the crude oil present in low permeable zones (Fig. 14c) which in turn results in incremental oil recovery.

4 Conclusion

The following conclusions were derived from the studies:

  1. Zinc Oxide (ZnO) was successfully prepared by biosynthesis of plant extract from Moringa oleifera leaves and its average particle size was found to be 10 nm.

  2. Convention hydrogel (PVP:RF) and zinc oxide reinforced nanocomposite hydrogel (PVP-ZnO:RF) were successfully prepared.

  3. From the FTIR analysis, a peak at 642 cm−1 was observed which signifies the presence of metal-oxygen bond, thus, confirming the presence of ZnO nanofiller in the nanocomposite hydrogel (PVP-ZnO:RF) matrix.

  4. FESEM images revealed that the nanocomposite hydrogel (PVP-ZnO:RF) has a significant alteration in surface morphology, which suggests the ZnO nanofiller’s presence in the hydrogel.

  5. Gel strength of hydrogels (i.e., conventional (PVP:RF) and nanocomposite (PVP-ZnO:RF)) decreases with the increase in salinity due to the rise in salts concentrations (NaCl and CaCl2). However, reinforcement of ZnO nanofiller leads to a decrease in gelation time but an increase in gel strength at a specific salt concentration.

  6. Both conventional (PVP:RF) and nanocomposite hydrogel (PVP-ZnO:RF) demonstrate a decrease in gelation time and an increase in gel strength with the temperature rise. Moreover, the reinforcement of ZnO nanofiller results in a decrease in gelation time and an increase in gel strength at a higher temperature in hydrogel systems.

  7. DSC analysis illustrates that ZnO nanofiller (at lower concentration i.e., 0.2–0.5 wt.%) enhances nanocomposite hydrogel’s thermal stability. The addition of higher concertation of ZnO nanofiller leads to a decrease in thermal stability (0.8–1 wt.%). The optimum temperature was found to be around 92 °C up to which the nanocomposite (PVP-ZnO:RF; 0.5 wt.% of ZnO) hydrogel is thermally stable.

  8. The rheological studies depicted that the prepared hydrogels i.e., conventional (PVP:RF) and nanocomposite (PVP-ZnO:RF) exhibit viscoelastic nature. Reinforcement of ZnO (at lower concentration i.e., 0.2–0.5 wt.%) in the PVP-ZnO:RF nanocomposite hydrogel increases its dynamic moduli (i.e., storage modulus as well as loss modulus); afterward, further reinforcement leads to a decrease in dynamic moduli. The optimum value of dynamic moduli of PVP-ZnO:RF hydrogel was found at 0.5 wt.% of ZnO.

  9. Sandpack studies determined that Percentage Permeability Reduction (PPR) and a Residual Resistance Factor (RRF) are 97% and 31.31 respectively for nanocomposite hydrogel (PVP-ZnO:RF) which are higher than that of conventional (PVP:RF) hydrogel. Thus, reinforcement of biosynthesized – ZnO nanofiller has enhanced the water shut-off performance of PVP-ZnO:RF hydrogel for heterogeneous layer present in mature hydrocarbon fields.

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All Tables

Table 1

Gel strength codes of Bottle testing method are listed below.

Table 2

Sandpack study results for PVP:RF and PVP-ZnO:RF.

All Figures

thumbnail Fig. 1

Schematic diagram of the breakthrough vacuum method.

In the text
thumbnail Fig. 2

Schematic experimental set-up for sandpack flooding studies.

In the text
thumbnail Fig. 3

(a) UV-Vis spectra of pure ZnO, (b) PXRD spectra of pure ZnO nanofiller.

In the text
thumbnail Fig. 4

(a) Reaction between Resorcinol–Formaldehyde (RF), (b) condensation reaction of RF, (c) hydrogen bonding scheme of PVP:RF, (d) PVP-ZnO, and (e) PVP-ZnO:RF.

In the text
thumbnail Fig. 5

FTIR spectrum of conventional (PVP:RF) and nanocomposite (PVP-ZnO:RF) hydrogels.

In the text
thumbnail Fig. 6

(a) SEM image of ZnO nanofiller, (b) EDX spectrum of ZnO. SEM micrographs of investigated gel systems at × 10 000, (c) PVP:RF, (d) PVP-ZnO:RF (0.5 wt.% ZnO).

In the text
thumbnail Fig. 7

Effect of (a) NaCl and (b) CaCl2 salt on Gel Strength (GS) and Gelation Time (GT) at 90 °C.

In the text
thumbnail Fig. 8

Effect of temperature on gel strength and gelation time on conventional (PVP:RF) and nanocomposite (PVP-ZnO:RF) hydrogels.

In the text
thumbnail Fig. 9

Arrhenius type graph of (a) conventional (PVP:RF) and (b) nanocomposite (PVP-ZnO:RF; (0.5 wt.% ZnO) hydrogels.

In the text
thumbnail Fig. 10

Schematic representation of free water (weak indirect interaction) and bound water (strong indirect interaction) interactions in hydrogels (Michael et al., 2018; Reena et al., 2020).

In the text
thumbnail Fig. 11

DSC thermographs for PVP-ZnO:RF (0–1 wt.% ZnO).

In the text
thumbnail Fig. 12

Frequency sweep test, (a) storage modulus, (b) loss modulus for PVP-ZnO:RF (0–1 wt.%) (T = 298 K).

In the text
thumbnail Fig. 13

Percentage Permeability Reduction (PPR) and the Residual Resistance Factor (RRF) of PVP:RF and PVP-ZnO:RF hydrogels (at 343 K or 75 °C).

In the text
thumbnail Fig. 14

Schematic of excessive water production problem and water shut-off mechanism, (a) a high permeable zone due to long term waterflooding produces mainly water, (b) gel treatment was done from a producer well, (c) water sweeps untouched low permeable zones after hydrogel placement in the high permeable zone for incremental oil recovery.

In the text

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