Startseite Investigation of improved optical and conductivity properties of poly(methyl methacrylate)–MXenes (PMMA–MXenes) nanocomposite thin films for optoelectronic applications
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Investigation of improved optical and conductivity properties of poly(methyl methacrylate)–MXenes (PMMA–MXenes) nanocomposite thin films for optoelectronic applications

  • KimHan Tan EMAIL logo , Lingenthiran Samylingam , Navid Aslfattahi , Mohd Rafie Johan und Rahman Saidur
Veröffentlicht/Copyright: 28. November 2022
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Open Chemistry
Aus der Zeitschrift Open Chemistry Band 20 Heft 1

Abstract

Polymer matrix composites composed of poly(methyl methacrylate) (PMMA) and MXenes (Ti3C2T x ) are synthesized using direct solution blending and casting techniques. MXenes are a new family of two-dimensional materials. Both optical and conductivity properties of the resulting PMMA-MXene nanocomposite thin films are studied as a function of MXene concentration, for the first time. The resulting thin films are in the micrometer range (8.10–8.80 µm) in thickness. As the concentration of MXenes increases, the PMMA embeds MXenes, causing structural disturbance but without any change in the crystal structure. The MXene thickness in single-layered structure is 15–20 nm. Optical investigations such as UV-Vis absorption, absorption coefficient, extinction coefficient, and band gap have been reported to study the light absorption of nanocomposites. Resistivity measurement associated with electrical conductivity is studied. The relationship between optical responses and electrical conductivity is discussed. When compared to pure PMMA (1 × 10−14 to 1 × 10−13 S m−1), nanocomposites have electrical conductivity that is more than 3,000 times higher. The nanocomposites containing 15 wt% MXenes had the highest conductivity of 1.35 × 10−3 S m−1. Both the conductivity improvement and tunable optical findings accelerate the route of integrating MXenes into polymers to create more promising multifunctional composites for optoelectronic applications such as conductive electrodes, thin film transistors, and logic circuits.

Keywords: MXenes; nanocomposites; impedance; conductivity; optical

1 Introduction

In general, most polymers display good compatibility characteristics with a wide variety of materials owing to their interfacial tension, which enables them to easily construct low-cost polymer matrix composites (PMCs). Polymers are good hosts for incorporating filler substances, particularly 2D compounds like graphene-based materials, silicate clays, metal oxide nanosheets, etc. [1]. Electrical, optical, mechanical, and thermal properties of more versatile composites enable their successful fabrication and use in optoelectronics, photonics, microelectronics, and optical transistor devices [1,2]. The optimal polymer-to-filler ratio, synthesizing techniques, type of solvent used, their resulting structures, inherent characteristics, and filler’s distribution inside the host material, must be studied from a research standpoint [3,4]. Poly (methyl methacrylate) (PMMA) is one of the best organic optical materials due to its transparency, which makes it an ideal host material for the fabrication of various optical devices, such as optical lenses, gratings, waveguides, and so on [5]. By harnessing its strong chemical resistance, mechanical flexibility, hardness, color versatility, thermal stability, biocompatibility, and low processing temperature, it is used to fabricate organic electrical devices, sensors, solar display units, pneumatic actuators, as well as in wide range of biomedical and medicinal applications [4,6,7]. Another important advantage of this polymer is that it has less potentially hazardous components, such as bisphenol-A, which is often present in polycarbonates, polysulfones, and epoxy resins [7].

MXenes are two-dimensional (2D) carbides or nitrides, which were first reported in 2011. However, this whole new big family of 2D materials was born in 2012. MXenes have the general formula M n+1X n T x (n = 1–4), where M indicates a transition metal (Ti, Cr, V, Nb, Hf, Ta, etc.), X denotes carbon and/or nitrogen atoms, and T x represents the terminations (–O, –OH, and –F) on the surface of the outmost transition metal layers. By using wet etching methods, which vary according to the type of etchant used [8,9,10,11], Al is selectively etched away from the Al-containing MAX phases and the freshly exposed transition metal (M) atoms are immediately coordinated by anions (–O, –OH, or –F) in the etchant, forming the surface terminations T x and eventually, leading to the formation of MXenes. The surface termination or functionalization of MXenes results in excellent hydrophilicity and superior solution processing capabilities. The abundance of transition metals, the possibility of in-plane and out-of-plane ordering of the metal atoms, as well as surface and mixed terminations, all contribute to the formation of an almost infinite variety of 2D materials with diverse characteristics. Therefore, these 2D materials can be conveniently tuned by using a suitable mix of transition metals and etchants [8,9]. Hydrofluoric acid (HF) is one of the primary candidates (etchants) to be used predominantly for MXenes synthesis. However, HF exposure is considered severe due to the fact that it can pass through the epidermis and dermis to enter the bloodstream and attack tissues, leading to heart function and liquefactive necrosis, respectively. Hence, safety precautions must be taken [10,11].

MXenes have metallic electrical conductivity that is not present in the majority of other 2D materials, such as semiconductors, semimetals, or dielectrics. The highest conductivity values reported in a past work is up to 20,000 S cm−1 [9]. MXenes also allow for the modification of their electronic characteristics since their Fermi levels can be tuned by surface functionalization. The surface functionalization can significantly reduce the density of states of surface transition metal at the Fermi level, resulting in the behavior of certain MXenes as semiconductors [12]. Since the efficiency of electromagnetic interference (EMI) shielding is directly associated with the electrical conductivity and thickness of materials, MXenes’ high electrical conductivity makes them ideal for EMI shielding applications. The incident electromagnetic wave may be reflected and absorbed several times by a great intensity of free electrons which are located on the surface of MXenes [8,9]. Furthermore, MXenes have been proven to exhibit nonlinear light absorption and plasmonic properties [9]. Their optical properties can be further altered when they serve as intercalation hosts for a variety of important cations [8,9,12].

MXenes are superior to other nanoparticles or 2D materials because of their excellent metallic conductivity and high hydrophilicity, which enable them to possess excellent electronic conductivity, high capacitance, good electrochemical performance, and easy processing properties [8,9]. Their metallic conductivity is due to the presence of transition metal backbones that provide abundance of free electrons. Meanwhile, the surface terminations contribute to their hydrophilicity. In addition, MXenes are an excellent filler in PMCs due to their improved strength and stiffness over other solution-based 2D materials. Currently, only some studies have been conducted on the synthesis of PMCs employing MXenes [13,14,15,16,17,18,19,20,21,22]. The involved methods for preparing MXenes-based PMCs are such as dry mixing, solution blending, in situ polymerization, electrospinning, emulsion mixing, and lamination stacking [23]. Electrical properties of polymers such as polyethylene oxide [18], polyvinyl acetate [17], polystyrene (PS) [20], poly(2-(dimethylamino)ethyl methacrylate) [21], and polyvinylidene fluoride [22] have been improved by MXenes in the past works. In addition, polymeric MXene composites such as MXenes/PS [20], MXenes/poly(3,4-ethylenedioxythiophene):polystyrene sulfonate ultrathin film [24], and MXenes/cellulose nanofiber composite film [25] have displayed high EMI shielding effectiveness values of more than 42 dB, which make them as excellent potential and flexible EMI shielding materials. Other MXenes-based PMCs have been discovered to exhibit enhanced thermal, mechanical, catalytic, and environmentally friendly antibacterial capabilities [1,23,26]. Further study is needed to investigate the nanocomposites’ electrical conductivity and optical properties in depth, especially the role played by MXenes. Both PMMA and MXenes are mixed by stirring and sonication. The solution blending and casting approach is used to fabricate the PMMA–MXenes nanocomposite thin films. In specified formulations, both PMMA and MXenes are designed to achieve a specific range of film thickness. Thin film optical constants such as absorption coefficient, extinction coefficient, and band gap are determined. Additionally, resistivity and impedance measurements are conducted. Both optical and electrical conductivity results are connected to justify the prospective uses of the resulting nanocomposite thin films in optoelectronic devices.

2 Materials and methods

Sigma Aldrich supplied the poly(methyl methacrylate) (PMMA) (MW = 996,000). Wet chemistry approach was used to produce the MXenes (Ti3C2T x ). Both MXenes (1.5 mg/mL) and PMMA (3 mg/mL) solutions were prepared, respectively. By using solution blending and casting techniques, PMMA–MXenes nanocomposite thin films with different MXenes concentration of 2, 5, 8, 10, and 15 wt% were formed. Field emission scanning electron microscope (FESEM) was used to investigate the morphological aspect of the nanocomposites. Fourier transform infrared (FTIR) spectrometer was used to explore distinct chemical bonds between host and filler via the identification of chemical functional groups. An Ultraviolet-visible (UV-Vis) spectrometer was used to examine the relationship between the incident electromagnetic waves and materials. The electrical conductivity nature and electrochemical characteristics of the samples were correlated to each other by probing their resistivity and impedance values with the use of a four-point probe and impedance spectroscopy. More information is provided in the sub-sections that follow.

2.1 Synthesis of MXenes

MAX Phase material (Ti3AlC2) from Y-Carbon Ltd, ammonium hydrogen difluoride (NH4HF2; reagent grade 95%, Sigma Aldrich), sodium hydroxide (97% purity, pellets, Sigma Aldrich), and dimethyl sulfoxide (DMSO; analytical reagent grade, Fisher Chemicals) were used without any further purification. To begin, 20 mL of NH4HF2 solution in 2 M was prepared precisely, which acted as a chemical etchant for the wet-chemistry etching process. The NH4HF2 dilution procedure was carried out using deionized (DI) water and required magnet-stirring at 500 rpm for 1 h at room temperature using a magnet stirrer (RCT BASIC, IKA). A microbalance (Explorer series, EX224, Ohaus) was used to weigh 1 g of Ti3AlC2. The Ti3AlC2 was then added slowly into the well-prepared NH4HF2 solution since the reaction is exothermic. With this approach, HF was not used directly to etch the Al layer from the MAX phase as HF is a dangerous chemical and it must be handled with extreme care. Alternatively, NH4HF2 was used as a mild etchant through in situ HF formation and is less hazardous than HF [10,11]. Both the removal of Al layer via etching as well as intercalation of ammonium species were done simultaneously to form MXenes, while minimizing unnecessary risk. The mixture (NH4HF2 and Ti3AlC2) was continuously stirred at 300 rpm for 48 h at room temperature. When the etching treatment ended, a diluted NaOH solution was added slowly into the mixture to achieve a pH of 6. The solution was washed with DI water, centrifuged at 4,000 rpm for 10 min using an ultrahigh centrifuge (Sorvall LYNX 6000, Thermo Scientific), and eventually followed by solution removal. These washing procedures were repeated four times.

After washing, the resulting multilayered flakes of MXene powder were delaminated by magnetically stirring a mixture of 1 g as-prepared MXenes and 15 mL of DMSO for 15 h at room temperature [27]. Similar washing procedures mentioned earlier were conducted again in order to completely remove DMSO from the MXenes. The resulting powder was stirred in water for 5 h within an inert condition (nitrogen), followed by 1 h of sonication via an ultrasonic probe sonicator (FS-1200N) under a setting of 60% power and 7/3 s on/off time. The final supernatant will be known as the MXenes colloidal solution from now on.

2.2 Synthesis of PMMA–MXenes nanocomposite thin films

The PMMA solution (3 mg/mL) was made by dissolving the PMMA into the versatile solvent tetrahydrofuran (THF) at 40°C using magnetic stirring. The resulting PMMA solution and the as-prepared MXenes solution (1.5 mg/mL) were magnetically mixed for 0.5 h. The mixture was sonicated for 1 hour in a water bath to obtain a homogenous mixture before being cast into a 5 cm diameter Petri dish. A vacuum oven (MEMMERT VO 500, Germany) was used to remove water with a drying time of 12 h. All the preceding steps were repeated to form nanocomposite thin films with varying concentrations of MXenes; 2, 5, 8, 10, and 15 wt% MXenes (Figure 1).

Figure 1 A simplified schematic diagram illustrating the whole synthesis process of PMMA–MXene nanocomposites.
Figure 1

A simplified schematic diagram illustrating the whole synthesis process of PMMA–MXene nanocomposites.

2.3 Morphological, crystallinity, and chemical structural studies

Both the pure MXenes and PMMA–MXene nanocomposites were viewed, and images were captured by using FESEM (Hitachi SU8000, Japan) at a 5 kV accelerating voltage and a working distance in the range of 10,000–11,100 µm. A suitable cross-sectional region of a sample is inspected to estimate its thickness. The crystal phases of all samples were examined by the D/teX Ultra2 X-ray diffractometer (XRD; Rigaku, Japan) with Cu Kα radiation (λ = 0.154 nm) over the range of 3–90° (2θ) at a scan speed of 6° min−1. Atomic force microscopy (AFM) (Bruker JPK NanoWizard 3, Germany) was employed to examine the surface topography profile of a sample. The involved functional groups present in the sample was examined and detected by the FTIR spectrometer. The FTIR spectrum was probed by using PerkinElmer Spectrum Two-UATR integrated with a detector of MIR TGS. All FTIR measurements were performed in the range of 4,000–400 cm−1 at a resolution of 4 cm−1 and 32 scans at a scanning speed of 0.2 cm s−1.

2.4 Optical analysis

UV-Visspectrum was applied to the nanocomposite thin films to evaluate how good the interacting electromagnetic waves were absorbed by them. The PerkinElmer Lambda 750 was used to acquire the absorption data in the wavelength range of 200–900 nm at room temperature. The samples were scanned by an 860 nm monochromatic source.

When electromagnetic waves travel through a material, their intensity is attenuated by a factor known as the absorption coefficient (α). The higher the value of α, the more the light can pass through a material in a shorter length before being absorbed, which can be used to determine with ease which sample absorbs light. This parameter is associated with both equations (1) and (2). Subsequently, α is calculated by using equation (3) [28,29,30].

(1) A = log 10 T ,

(2) α = 1 l ln 1 T ,

(3) α = ( ln 10 A ) / l ,

where α is the absorption coefficient (cm−1); A is the light absorbance; l is the thickness (cm); T is the transmittance.

Another important parameter, extinction coefficient (k), explains the amount of light absorption loss in a material, which is related to how quickly the light disappears owing to absorption or scattering in a substance. It can be calculated according to equation (4) [29,31].

(4) k = α λ / 4 π .

In solid-state chemistry, band gap energy is employed to deduce the nature of a matter’s outer shell electrons. It is a measure of the mobility of these electrons, which are responsible for the inherent characteristics of matter, such as electrical conductivity and light absorption. Therefore, band gap energy is utilized to correlate with the abovementioned features, as it is determined by the movement of the outer shell electrons [32]. The band gap energy of a nanocomposite thin film was determined by using the method described by Tauc [31,33,34]. The Kubelka–Munk function, as defined in equation (5), was used. The band gap energy was estimated by extrapolating the linear component of the Tauc plot of (αE) 1/n vs photon energy from the intercept to the abscissa axis (E).

(5) α E = α o ( E E g ) n ,

where E is the photon energy (eV); α o is the transition probability constant; E g is the band gap energy (eV); n is the value of 1/2, 3/2, 2, or 3 that depends on the types of electronic transition.

2.5 Conductivity studies

The electrical conductivity of nanocomposite thin films with varying MXenes concentration was evaluated by using electrochemical impedance spectroscopy (EIS) at room temperature. EIS was used to understand any involved conduction mechanism and complex relaxation occurring in materials as a function of frequency. EIS was performed using a Gamry Interface 1010 E potentiostat under a setting of 10 mV amplitude in the range of 10 mHz to 200 kHz, so that the phase shift of current and impedance were measured. Both the imaginary part, Z Imaginary and the real part, Z Real were measured and presented in a plot, the so-called Nyquist impedance plot, in order to estimate the values of the circuit parameters that correspond to the charge carrier transport properties. Using the two-probes approach, the bulk resistance (R b) of a nanocomposite was calculated in this study [35]. A circular sample with a 32 mm radius was placed between two probes that served as electrodes. To provide a secure physical and electric contact for the interface between the probes and sample, a fixed spring was used while silver paste was applied on a sample prior to any measurement. Both resistivity (ρ) and electrical conductivity (σ) were then calculated by using equation (6) (19, 35, 36) and equation (7), respectively. The thickness of all the samples was previously measured by FESEM.

(6) ρ = R b A l ,

(7) σ = 1 ρ ,

where ρ is the resistivity (Ω m); R b is the bulk resistance (Ω); A is the surface area (m2); l is the thickness (m); σ is the electrical conductivity (S m−1).

To achieve consistent results, an average of three different measurements was obtained on each thin film sample. The potentiostat also worked as the current source to probe the voltage for the purpose of calculating the resistance of a sample, R.

3 Results and discussion

3.1 Morphologies, crystallinity, and chemical structures

As observed in Figure 2(a), the as-prepared MXenes display both multilayered and delaminated structures, indicating that exfoliation of the MAX phase to MXene sheets occurred by etching treatment. However, several layers of MXene flakes are partially aligned parallel to one another with a certain separation distance, indicating that the MXene sheets are not perfectly delaminated. The presence of MXene flakes reveals the morphological nature of 2D materials. By using direct solution blending and casting techniques, the PMMA–MXenes thin film is successfully formed (Figure 2(f)). The cross-section of all thin film samples is captured, and their thicknesses are measured and tabulated in Table 1. The thickness values for all thin film samples fall in the range of 8.10–8.88 µm. The compatibility between PMMA and MXenes is probably assisted by the delamination treatment done on the MXenes prior to the blending of the two components. The delaminated MXenes consist of a few layers of flakes instead of multilayered flakes, providing more space between the flakes to be conveniently accessed and surrounded by PMMA [14]. The series of stirring and ultrasonication steps makes it easier for PMMA to get into MXenes, which makes for a good mix [37].

Figure 2 FESEM images of MXenes and PMMA–MXenes nanocomposite. (a) The formation of multilayered and delaminated pure MXenes; (b) cross-section of thin film with 2 wt% MXenes; (c) cross-section of thin film with 5 wt% MXenes; (d) thin film with 8 wt% MXenes; (e) thin film with 10 wt% MXenes; (f) top view of thin film with 15 wt% MXenes.
Figure 2

FESEM images of MXenes and PMMA–MXenes nanocomposite. (a) The formation of multilayered and delaminated pure MXenes; (b) cross-section of thin film with 2 wt% MXenes; (c) cross-section of thin film with 5 wt% MXenes; (d) thin film with 8 wt% MXenes; (e) thin film with 10 wt% MXenes; (f) top view of thin film with 15 wt% MXenes.

Table 1

Various characterization data for all samples

Sample configuration Thickness, l (µm) Band gap, E g (eV) Bulk resistance, R b (Ω) Resistance, R (Ω) from V–I curve Resistivity, ρ (Ω m) Electrical conductivity, σ (S m−1)
PMMAMXenes 2 wt% 8.40 2.90 5.05 × 106 1.93 × 109 5.17 × 10−10
PMMAMXenes 5 wt% 8.70 2.60 8.55 × 105 3.16 × 108 3.16 × 10−9
PMMAMXenes 8 wt% 8.50 2.70 1.36 × 106 6.08 × 108 1.65 × 10−9
PMMAMXenes 10 wt% 8.80 2.50 2.45 2.52 9.27 × 102 1.08 × 10−3
PMMAMXenes 15 wt% 8.60 2.45 1.97 2.01 7.37 × 102 1.35 × 10−3
Pure PMMA 20–50 *3.00–5.50 Undisclosed *1 × 1013 to 1 × 1014 *1 × 10−13 to 1 × 10−14

Note: * Values retrieved from previous work are for the comparison purpose [48,57].

At the lowest concentration of 2 wt% MXenes within the PMMA, the MXene flakes are fully enclosed by PMMA, in which the layered architecture is less significant, as evidenced in Figure 2(b). The MXenes are surrounded and dominated by PMMA entirely. A similar structural feature has also been observed in the thin film sample with 5 wt% MXenes (Figure 2(c)). The MXene flakes are now more significant as their distribution within the PMMA is more uniform. However, when the concentration of MXenes is further increased to 8 wt% and above, Figure 2(d) and (e) displays the inhomogeneous arrangement of MXenes within the PMMA, where the stack of MXene flakes is only visible in certain regions of the whole image. The degree of disorder in the nanocomposite starts to increase with the MXenes. Both components are not dispersed uniformly, and the PMMA is difficult to access the interspaces between the delaminated MXene flakes. In addition, with the increasing amount of added MXenes, they may not fully delaminate to provide accessibility to the host material. Based on Figure 3, AFM measurement reveals that the MXene sheets are single-layered structures, with a thickness of 15–20 nm. The MXene sheets have been delaminated into single layers and they are all over the surface of PMMA.

Figure 3 AFM image (top) and height profile (bottom) of the PMMA–15 wt% MXenes with an inset blue dotted line crossing a few MXene layers.
Figure 3

AFM image (top) and height profile (bottom) of the PMMA–15 wt% MXenes with an inset blue dotted line crossing a few MXene layers.

XRD was used to establish the presence of MXenes within the PMMA–MXenes nanocomposites and the interaction between the polymer matrix and MXenes. The resulting XRD patterns are shown in Figure 4. MXenes have notable peaks at 2θ = 5.6°, 17.6°, and 25.2°, which correspond well to the crystal planes (002), (004), and (008) of a few layered MXenes, respectively [38]. The sharp (002) peak with the highest intensity validates the ordered stacking of MXene layers in all nanocomposite samples, implying that despite variable MXene concentrations, all PMMA–MXene nanocomposites still contain the similar layered stacking of MXenes. The FESEM images also confirm this characteristic (Figure 2). When PMMA and MXenes are mixed together, there are no obvious changes in the crystallinity of MXenes within the nanocomposites [39]. The Bragg’s law is capable of associating the sharp (002) peak with the d-spacing MXenes. With increased polymer loading (decreasing concentration of MXenes), this (002) peak gradually shifts toward a lower angle, indicating a gradual increase in the interlayer spacing between the MXene sheets. This is because of the intercalation and confinement of PMMA, which is aided by the delamination of MXene sheets and eventually allows the polymer to easily access the interspaces between the MXene sheets [38,39].

Figure 4 XRD patterns of as-prepared MXenes and PMMA–MXenes nanocomposites.
Figure 4

XRD patterns of as-prepared MXenes and PMMA–MXenes nanocomposites.

Possible physicochemical interactions between PMMA and MXenes are studied by using FTIR measurement. Figure 5 displays FTIR spectra for all PMMA–MXenes nanocomposite thin film samples with different concentrations of MXenes at room temperature. It is evidenced that they show similar bands that have been observed in pure PMMA [15,40]. There is a sharp peak at 1,727 cm−1, which corresponds to the carbonyl group, C═O. Peaks at 3,000/2,950, 1,436/1,480, and 1,365 cm−1 are attributed to methyl ester C–H stretching vibrations, –CH3 symmetric stretching vibrations, C–H deformation, and –CH3 symmetrical bending vibration or deformation, respectively. In addition, the peaks at 1,268/1,241/1,147/988 cm−1 correspond to C–O stretching. All the aforementioned peak bands are assigned to pure PMMA. All samples also exhibit peaks at 1,064, 1,191, and 1,389 cm−1, which are associated with the –CH3 twisting, –CH3 wagging, and hydroxyl group (–OH), respectively [15]. The detection of the –OH group implies the successful incorporation of MXenes into the composites. Figure 5(a) clearly presents the similarity between pure PMMA and PMMA–MXenes nanocomposites indicating that no strong chemical interaction bond is formed between the host and filler [14,41]. However, based on the normalized FTIR spectra as shown in Figure 5(b), with an increase in the concentration of MXenes, the intensity of peaks gradually decreases, suggesting the occurrence of physical interaction between the host and filler [15,41].

Figure 5 FTIR spectra for all samples in different presentation modes. (a) FTIR spectra are stacked to each another. (b) FTIR spectra with normalized transmittance.
Figure 5

FTIR spectra for all samples in different presentation modes. (a) FTIR spectra are stacked to each another. (b) FTIR spectra with normalized transmittance.

3.2 Optical analysis

UV-Vis absorption test is conducted on the PMMA–MXene samples with different concentration of MXenes (2, 5, 8, 10, and 15 wt%). Figure 6 shows that the pure PMMA spectrum exhibits the lowest absorbance (high transmittance), which is expected because PMMA finds wide applications in a variety of optical devices, such as optical lenses, transparent window materials, waveguides, gratings, etc. [5,7]. However, the absorption capability of nanocomposites is greatly improved with the inclusion of MXenes in all samples [16,42,43], which increases the absorbance with the concentration of MXenes, as indicated by a vertical arrow. The electronic excitation within the carbonyl chromophores (C═O) contained in the PMMA structure causes a dominating peak in the region of 250–260 nm in all samples. This strong absorption band is associated with π–π* transition in the C═O system. The incorporation of MXenes into the PMMA induces a change in the band gap energy in the nanocomposites [16]. Another absorption edge is observed at about 375 nm, as encircled by the oval (Figure 6). It is contributed by the presence of titanium oxide (TiO2) in the MXenes [16,44]. The transition element Ti in MXenes readily oxidizes in the air to form TiO2, which has been proven in some past works [12,45].

Figure 6 The UV-Vis absorption spectra of all samples as a function of wavelength.
Figure 6

The UV-Vis absorption spectra of all samples as a function of wavelength.

An insignificant peak (highlighted by the rectangle in Figure 6) starts to appear at 482 nm for the samples with 5 wt% MXenes and above. This peak is attributed to the creation of intermolecular hydrogen bonds between the PMMA and MXenes. MXenes’ high hydrophilicity associated with surface terminations (–OH, –O, –F) could result in some interactions with PMMA [36,46]. In addition, MXenes display plasmon resonance by displaying another absorption band which is found at 852 nm, as shown within the rounded rectangle [12,47]. The visibility of both absorption peaks (482 and 852 nm) increases with the concentration of MXenes. The insufficient amount of MXenes in PMMA–MXenes 2 wt% sample results in the disappearance of these insignificant peaks. The overall absorbance in both the visible and UV light regions increases with MXenes’ concentration. The increasing amount of MXenes (filler) introduce more localized charge carrier levels within PMMA (host) that act as trapping sites, making more electronic transitions between the filler and host and consequently increase absorbance [43,47]. The TiO2 within the MXenes also renders good absorption capabilities by inducing vibrational-electronic transitions to the primary singlet excited state of the molecular structure of the nanocomposites. The unbound or free electrons in the TiO2 also amplify the incident electromagnetic wave, which consequently intensify the light absorbance as well [16,43,44].

To further validate the absorption capability of nanocomposite thin films, α is calculated by using equation (1) and is presented in Figure 7. All nanocomposite samples display increasing trend for α in the whole region of photon energy (E). The increase is more drastic in the range 1.4–4 eV, then α slightly increases with E, as shown in the range of 4–6.2 eV, regardless of the change in the concentration of MXenes. As compared to the pure PMMA, all nanocomposite thin film samples exhibit higher α values, ranging from 2.2 × 103 cm−1 up to 3.9 × 103 cm−1, as contributed by the addition of MXenes. Overall, the absorption capability of thin films increases with the concentration of MXenes [16,42,43]. The sample PMMA–MXenes 15 wt% achieves the highest α among all samples. However, only the PMMA–MXenes 8 wt% exhibits higher α compared to the PMMA–MXenes 10 wt%. The sample with 8 wt% MXenes has lower thickness than that of sample with 10 wt% MXenes. Apart from the filler (MXenes) content in nanocomposite, the thickness of thin film affects α [14,28,29,30]. All nanocomposite samples display a tiny peak at around 1.5 eV (encircled by the oval in Figure 4), which corresponds to the existence of MXenes within the PMMA. Two other peaks observed at about 2.6 and 3.3 eV are correlated with the intermolecular bonds between PMMA and MXenes and with the presence of TiO2 within the samples, respectively [12,16,44,45,47]. There is also an insignificant and broad hump located in 4–5 eV, as highlighted by the square, which implies that the addition of MXenes alters band gap energy of the nanocomposites [16]. The modification of α permits MXenes to play important role in functioning as a filler to optimize the optical properties of PMMA [42,43].

Figure 7 The absorption coefficient (α) of all samples as a function of photon energy (E).
Figure 7

The absorption coefficient (α) of all samples as a function of photon energy (E).

Figure 8 shows that all samples display decreasing k values with E. With the addition of MXenes, nanocomposite thin films possess higher k, as compared to the pure PMMA. The higher the concentration of MXenes added to PMMA, the greater the loss of electromagnetic wave due to better absorption capability, as what have been explained previously based on Figure 7. Similarly, the PMMA–MXenes 8 wt% has k which is slightly higher than that of PMMA–MXenes 10 wt% due to the thickness factor. The PMMA–MXenes 15 wt% exhibits the highest k among all samples, which indicates the smallest amount of time the light disappeared within the sample, since it has shown the highest α previously. The electric component of the electromagnetic wave is restrained from further propagating deeper into the nanocomposites by the TiO2 contained in MXenes. The upward trend in k value demonstrates that MXenes (filler) optically tuned the PMMA (host) [16,42,43].

Figure 8 The extinction coefficient (k) of all samples as a function of photon energy (E).
Figure 8

The extinction coefficient (k) of all samples as a function of photon energy (E).

The band gap (E g) for all nanocomposite samples is estimated by applying the previously calculated α values together with equation (5). Based on Tauc’s relationship and by using power probability of n = ½ to suppose that all nanocomposite thin films are direct allowed transition type, a suitable Tauc plot against E is constructed and presented in Figure 9 [31,33,34,48]. The E g is then computed and reported in Table 1 by projecting the relevant straight dotted line to cross the E-axis at (αE)2 = 0 [28,48].

Figure 9 Tauc plot for all samples as a function of photon energy (E).
Figure 9

Tauc plot for all samples as a function of photon energy (E).

Based on Figure 10, when MXenes are added, all nanocomposite thin film samples display much lower E g in the range of 2.4–3 eV, as compared to pure PMMA, which has an estimated E g of 4.2 eV (Figure 9). According to the literature, the obtained E g values for pure PMMA and PMMA composites are approximately 6 eV and 3.5–5.5 eV, respectively [48]. When the MXenes concentration is increased from 2 to 5 wt%, the E g decreases from 2.9 to 2.6 eV (Figure 9). However, increasing the MXenes concentration by 8 wt% increases the E g, and then it decreases with MXenes concentration all the way. Overall, the band gap of the resulting nanocomposites decreases as the amount of filler increases. The lower the E g value, the fewer energy electrons need to carry charges and move from the valence band to the conduction band, allowing current to conduct smoothly. Therefore, the addition of MXenes improve the electrical conductivity of nanocomposite thin films [19,48,49]. As the FTIR result (Figure 5b) has previously proven the existence of interaction between the host and filler, the formation of some networks between PMMA and MXenes based on a basis of charge transfer complex increase the electrical conductivity [50]. In addition, during the etching and delamination processes, the surface termination of the MXenes enables them to render metal-to-semiconductor transition. The surface termination significantly modifies the density of states of the surface transition metal of Ti at the Fermi level, thereby increasing the electronic conductivity of MXenes and ultimately offering tunable electrical conductivity [8,9,23,51].

Figure 10 The Tauc plot illustrates the band gap (E g) variation in nanocomposites as a function of MXenes concentration.
Figure 10

The Tauc plot illustrates the band gap (E g) variation in nanocomposites as a function of MXenes concentration.

3.3 Conductivity studies

The EIS for PMMA–MXenes 2, 5, and 8 wt% show a depressed semicircle in the high-frequency end, followed by a tilted spike in the low-frequency end, as shown in Figure 11. Instead of the ideal Debye relationship, their impedance trends exhibit deviated Debye-type behavior [46]. The irregular semicircle and the nearly straight line could be caused by the thin films’ irregular thickness and morphology. [35]. Due to the fact that most polymers can exhibit numerous ionic conductivity mechanisms, increasing the amount of MXenes causes the sample to exhibit more complex impedance behavior, as multiple relaxation times are involved [46]. To investigate the electrical property of thin film, the bulk resistance, R b , is extracted from the intersection of the plot associated with the low-frequency end of the semicircle and the high-frequency end of the straight line [35]. R b values of 5.05 × 106, 8.55 × 105, and 1.36 × 106 Ω were found in samples with 2, 5, and 8 wt% MXenes, respectively. Using equation (6), they obtained resistivities (ρ) of 1.93 × 109, 3.16 × 108, and 6.08 × 108 Ω m, which are lower than the pure PMMA resistivity of about 1 × 1014 Ω m [52,53]. The MXenes were used as a filler to significantly reduce the ρ to a considerable extent [54].

Figure 11 EIS were recorded at room temperature for all samples. An arrow indicates the magnified EIS of the samples seen in a relatively narrow range of Z Real components.
Figure 11

EIS were recorded at room temperature for all samples. An arrow indicates the magnified EIS of the samples seen in a relatively narrow range of Z Real components.

However, neither the 10 wt% MXenes nor the 15 wt% MXenes samples show any deviating Debye curves. They exhibit nearly vertical curves in a narrow range of Z Real, suggesting that these samples behave like perfect resistors, obeying Ohm’s law across the whole range of voltage and current values. [55,56]. During the impedance measurement, both the alternating current and voltage signals flow in phase through the samples. Regardless of frequency, their resulting resistance values are consistent, allowing the resistance to be derived from their respective Z Real component intercept values. Figure 11 and Table 1 show the equivalent R b values of PMMA–MXenes 10 and 15 wt%, which are 2.45 and 1.97 Ω, respectively. To validate these values, a voltage (V) against current (I) measurement is performed, and the acquired V and I values form a linear trend (Figure 12), which is fully compliant with the Ohm’s law. Therefore, the gradients of these V–I graphs are extracted to represent the resistance values (R). The corresponding R is highly correlated with the R b determined from the impedance spectra (Table 1).

Figure 12 Voltage–current (V–I) graphs for samples at room temperature.
Figure 12

Voltagecurrent (V–I) graphs for samples at room temperature.

For the sake of comparison and discussion, both ρ and σ values, as well as other pertinent parameters for all samples, are included in Table 1. As illustrated in Figure 11, both PMMA–MXenes 15 and 2 wt% reach the maximum and lowest values of 1.35 × 10−3 and 5.17 × 10−10 S m−1, respectively. The introduction of MXenes into PMMA greatly improves electrical conductivity of nanocomposite thin films by more than 3,000 times when compared to pure PMMA in past works, despite the fact that the samples’ thickness is not uniform. Apart from the intrinsic electrical properties of MXenes and their concentrations that increase the electronic conductivity, the ionic conductivity of nanocomposites is significantly dependent on the interaction between the charge carriers and the polymer matrix [23,36,50]. The presence of insignificant peak at 482 nm in UV-Vis spectra (Figure 6), as well as the diminished intensity of the peaks in FTIR spectra (Figure 5), may indicate the successful formation of certain interfaces between PMMA and MXenes, since the MXenes are highly soluble in aqueous solution with their surface being terminated with functional groups (–O, –F, –OH) [36,46]. These hydroxyl and oxy groups on the surfaces of MXenes interact with PMMA through hydrogen bonds [23]. This interaction results in an amplification effect caused by the space charge, which speeds the movement of ions and therefore the electrical conductivity. In addition, MXene flakes with large aspect ratios form a charge transfer percolation network that enhances the electrical conductivity of the nanocomposites. The formation of an interconnected ionic network creates long-range interfacial pathways within the nanocomposites and therefore, contributes to efficient ionic conductivity [23,50]. Overall, the nanocomposites display increasing σ with the amount of MXenes (Figure 13). Accumulation of MXenes stimulates the creation of the conductivity chain or network, which raises the number density of mobile ions, resulting in a dramatic increase in electrical conductivity, particularly when the MXenes concentration is increased from 8 to 10 % [36]. When the concentration is increased from 5 to 8 %, however, σ is slightly reduced with its E g that is slightly higher (Figure 10 and Table 1).

The obtained results of σ and E g are also highly correlated. The PMMA–MXenes 15 wt% exhibits the lowest E g (2.45 eV) yet the highest σ (1.35 × 10−3 S m−1) [19,49]. MXenes modify the electronic structure of PMMA by forming localized electronic states in the optical band gap of PMMA that overlap with the band system. These localized electronic states serve as trapping and recombination centers, which can affect E g [19,50]. MXenes containing TiO2 produce a greater number of delocalized π-electrons, lowering the E g between π and π* and increasing the optical π–π* transitions [16]. Additionally, the decrease in E g that occurs as a result of the increase in σ can be explained by the increased degree of disorder in the nanocomposites [19,58]. Further, the development of the localized electronic states adds new defect states into the PMMA (host), increasing the defect concentration inside the nanocomposites. According to the earlier morphological finding in Section 3.1, MXenes concentration increases the degree of disorder in nanocomposites.

Figure 13 The electrical conductivity (σ) of nanocomposites is shown against the concentration of MXenes at room temperature.
Figure 13

The electrical conductivity (σ) of nanocomposites is shown against the concentration of MXenes at room temperature.

4 Conclusion

A solution blending and casting technique is used to synthesize the PMMA–MXenes nanocomposite thin film. The nanocomposite thin film is composed of a multilayered and partially delaminated MXene structure enclosed in a polymer matrix. The nanocomposites become more disordered in direct proportion to the MXenes concentration. However, when MXenes are integrated into PMMA, their crystallinity remains unchanged. The thickness of the interspacing layer between the MXene sheets strongly depends on the intercalation and confinement of PMMA, which can be enhanced further through the delamination process. The MXenes can be fully delaminated into a single-layered structure with a thickness of 15–20 nm. As demonstrated by the calculated optical absorption and attenuation coefficients, MXenes’ absorption capabilities boost the light absorption capacity of nanocomposites. The electrical conductivity of the nanocomposites is increased by more than 3,000 times when compared to pure PMMA. The MXenes’ intrinsic electrical qualities, and their large aspect ratio flakes that form good interfaces with PMMA, result in a promising charge conduction percolation channel, and the alteration of PMMA’s electrical structure contribute to the electrical conductivity improvement. The band gap values determined from the Tauc plot correspond well with the conductivity data. A maximum of 1.35 × 10−3 S m−1 is obtained in PMMA–MXenes 15 wt%. The significant improvement in electrical conductivity, light absorption capabilities, and tunable band gap of the nanocomposites permits their potential usage in optoelectronic applications, including conductive electrodes (LCD and OLED), electrodes in field-effect and thin film transistors, and photonic devices.

Acknowledgment

The authors would like to thank the Research Center for Nano-Materials and Energy Technology (RCNMET), School of Engineering (SET), and Sunway University for their equipment support. The authors also would like to thank Nanotechnology & Catalysis Research Center (NANOCAT) for its financial support.

  1. Funding information: The work is financially supported by University of Malaya Research Grant (RU003-2021).

  2. Author contributions: KimHan Tan devised the whole work, performed experiments, and wrote and revised the whole manuscript. L Samylingam assisted in characterizations. Navid Aslfattahi prepared MXenes. Rahman Saidur and Mohd Rafie Johan reviewed and edited the manuscript. All authors authorized the current version of the work for submission.

  3. Conflict of interest: Authors declare that there are no conflicts.

  4. Ethical approval: The conducted research is not related to either human or animal use.

  5. Data availability statement: All data generated or analyzed during this study are included in this article.

References

[1] Riazi H, Nemani SK, Grady MC, Anasori B, Soroush M. Ti3C2 MXene–polymer nanocomposites and their applications. J Mater Chem A. 2021;9(13):8051–98.10.1039/D0TA08023CSuche in Google Scholar

[2] Dunklin JR, Bodinger C, Forcherio GT, Roper DK. Plasmonic extinction in gold nanoparticle-polymer films as film thickness and nanoparticle separation decrease below resonant wavelength. J Nanophotonics. 2017;11(1):016002.10.1117/1.JNP.11.016002Suche in Google Scholar

[3] Jimmy J, Kandasubramanian B. Mxene functionalized polymer composites: synthesis and applications. Eur Polym J. 2020;122:109367.10.1016/j.eurpolymj.2019.109367Suche in Google Scholar

[4] Thirumala Patil M, Lakshminarasimhan SN, Santhosh G. Optical and thermal studies of host poly (methyl methacrylate) (PMMA) based nanocomposites: a review. Mater Today: Proc. 2021;46:2564–71.10.1016/j.matpr.2021.01.840Suche in Google Scholar

[5] Righini GC, Krzak J, Lukowiak A, Macrelli G, Varas S, Ferrari M. From flexible electronics to flexible photonics: a brief overview. Optical Mater. 2021;115:111011.10.1016/j.optmat.2021.111011Suche in Google Scholar

[6] Zhang HQ, Jin Y, Qiu Y. The optical and electrical characteristics of PMMA film prepared by spin coating method. IOP Conf Ser Mater Sci Eng. 2015;87:012032.10.1088/1757-899X/87/1/012032Suche in Google Scholar

[7] Forte MA, Silva RM, Tavares CJ, Silva RF. Is poly(methyl methacrylate) (PMMA) a suitable substrate for ALD?: a review. Polymers. 2021;13:8.10.3390/polym13081346Suche in Google Scholar PubMed PubMed Central

[8] Hantanasirisakul K, Gogotsi YJAM. Electronic and optical properties of 2D transition metal carbides and nitrides (MXenes). Adv Mater. 2018;30(52):1804779.10.1002/adma.201804779Suche in Google Scholar PubMed

[9] VahidMohammadi A, Rosen J, Gogotsi Y. The world of two-dimensional carbides and nitrides (MXenes). Science. 2021;372(6547):eabf1581.10.1126/science.abf1581Suche in Google Scholar PubMed

[10] Naguib M, Barsoum MW, Gogotsi Y. Ten years of progress in the synthesis and development of MXenes. Adv Mater. 2021;33(39):2103393.10.1002/adma.202103393Suche in Google Scholar PubMed

[11] Shuck CE, Ventura-Martinez K, Goad A, Uzun S, Shekhirev M, Gogotsi Y. Safe synthesis of MAX and MXene: guidelines to reduce risk during synthesis. ACS Chem Health Saf. 2021;28(5):326–38.10.1021/acs.chas.1c00051Suche in Google Scholar

[12] Hantanasirisakul K, Zhao M-Q, Urbankowski P, Halim J, Anasori B, Kota S, et al. Fabrication of Ti3C2Tx MXene transparent thin films with tunable optoelectronic properties. Adv Electron Mater. 2016;2(6):1600050.10.1002/aelm.201600050Suche in Google Scholar

[13] Rajavel K, Luo S, Wan Y, Yu X, Hu Y, Zhu P, et al. 2D Ti3C2Tx MXene/polyvinylidene fluoride (PVDF) nanocomposites for attenuation of electromagnetic radiation with excellent heat dissipation. Compos Part A Appl Sci Manuf. 2020;129:105693.10.1016/j.compositesa.2019.105693Suche in Google Scholar

[14] Tan KH, Samylingam L, Aslfattahi N, Saidur R, Kadirgama K. Optical and conductivity studies of polyvinyl alcohol-MXene (PVA-MXene) nanocomposite thin films for electronic applications. Opt Laser Technol. 2021;136:106772.10.1016/j.optlastec.2020.106772Suche in Google Scholar

[15] Ul Haq Y, Murtaza I, Mazhar S, Ahmad N, Qarni AA, Ul Haq Z, et al. Investigation of improved dielectric and thermal properties of ternary nanocomposite PMMA/MXene/ZnO fabricated by in situ bulk polymerization. J Appl Polym Sci. 2020;137(40):49197.10.1002/app.49197Suche in Google Scholar

[16] Yahia IS, Mohammed MI, Nawar AM. Multifunction applications of TiO2/poly(vinyl alcohol) nanocomposites for laser attenuation applications. Phys B Condens Matter. 2019;556:48–60.10.1016/j.physb.2018.12.031Suche in Google Scholar

[17] Sobolčiak P, Ali A, Hassan MK, Helal MI, Tanvir A, Popelka A, et al. 2D Ti3C2Tx (MXene)-reinforced polyvinyl alcohol (PVA) nanofibers with enhanced mechanical and electrical properties. Plos One. 2017;12(8):e0183705.10.1371/journal.pone.0183705Suche in Google Scholar PubMed PubMed Central

[18] Mayerberger EA, Urbanek O, McDaniel RM, Street RM, Barsoum MW, Schauer CL. Preparation and characterization of polymer-Ti3C2Tx (MXene) composite nanofibers produced via electrospinning. J Appl Polym Sci. 2017;134(37):45295.10.1002/app.45295Suche in Google Scholar

[19] Sreekanth K, Siddaiah T, Gopal NO, Madhava Kumar Y, Ramu C. Optical and electrical conductivity studies of VO2+ doped polyvinyl pyrrolidone (PVP) polymer electrolytes. J Sci Adv Mater Devices. 2019;4(2):230–6.10.1016/j.jsamd.2019.06.002Suche in Google Scholar

[20] Sun R, Zhang H-B, Liu J, Xie X, Yang R, Li Y, et al. Highly conductive transition metal carbide/carbonitride(MXene)@polystyrene nanocomposites fabricated by electrostatic assembly for highly efficient electromagnetic interference shielding. Adv Funct Mater. 2017;27(45):1702807.10.1002/adfm.201702807Suche in Google Scholar

[21] Chen J, Chen K, Tong D, Huang Y, Zhang J, Xue J, et al. CO2 and temperature dual responsive “Smart” MXene phases. Chem Commun. 2015;51(2):314–7.10.1039/C4CC07220KSuche in Google Scholar

[22] Tu S, Jiang Q, Zhang X, Alshareef HN. Large dielectric constant enhancement in MXene percolative polymer composites. ACS Nano. 2018;12(4):3369–77.10.1021/acsnano.7b08895Suche in Google Scholar PubMed

[23] Chen X, Zhao Y, Li L, Wang Y, Wang J, Xiong J, et al. MXene/Polymer Nanocomposites: preparation, properties, and applications. Polym Rev. 2021;61(1):80–115.10.1080/15583724.2020.1729179Suche in Google Scholar

[24] Liu R, Miao M, Li Y, Zhang J, Cao S, Feng X. Ultrathin biomimetic polymeric Ti3C2Tx MXene composite films for electromagnetic interference shielding. ACS Appl Mater Interfaces. 2018;10(51):44787–95.10.1021/acsami.8b18347Suche in Google Scholar PubMed

[25] Cui C, Xiang C, Geng L, Lai X, Guo R, Zhang Y, et al. Flexible and ultrathin electrospun regenerate cellulose nanofibers and d-Ti3C2Tx (MXene) composite film for electromagnetic interference shielding. J Alloy Compd. 2019;788:1246–55.10.1016/j.jallcom.2019.02.294Suche in Google Scholar

[26] Zhan X, Si C, Zhou J, Sun Z. MXene and MXene-based composites: synthesis, properties and environment-related applications. Nanoscale Horiz. 2020;5(2):235–58.10.1039/C9NH00571DSuche in Google Scholar

[27] Qian A, Seo JY, Shi H, Lee JY, Chung C-H. Surface functional groups and electrochemical behavior in dimethyl sulfoxide-delaminated Ti3C2Tx MXene. ChemSusChem. 2018;11(21):3719–23.10.1002/cssc.201801759Suche in Google Scholar PubMed

[28] Sadeghi H, Dorranian D. Influence of size and morphology on the optical properties of carbon nanostructures. J Theoret Appl Phys. 2016;10(1):7–13.10.1007/s40094-015-0194-4Suche in Google Scholar

[29] Lee S-H, Jang SP. Extinction coefficient of aqueous nanofluids containing multi-walled carbon nanotubes. Int J Heat Mass Transfer. 2013;67:930–5.10.1016/j.ijheatmasstransfer.2013.08.094Suche in Google Scholar

[30] Gong J, Krishnan S. Chapter 2 – Mathematical modeling of dye-sensitized solar cells. In: Soroush M, Lau KKS, editors. Dye-sensitized solar cells. Academic Press; 2019. p. 51–81.10.1016/B978-0-12-814541-8.00002-1Suche in Google Scholar

[31] El-Denglawey A, Dongol M, El-Nahass MM. Photoinduced absorption edge shift of As20Se60Tl20 films. J Lumin. 2010;130(5):801–4.10.1016/j.jlumin.2009.11.036Suche in Google Scholar

[32] Suo B, Su X, Wu J, Chen D, Wang A, Guo Z. Poly (vinyl alcohol) thin film filled with CdSe–ZnS quantum dots: Fabrication, characterization and optical properties. Mater Chem Phys. 2010;119(1–2):237–42.10.1016/j.matchemphys.2009.08.054Suche in Google Scholar

[33] Chen J, Tang W, Xin L, Shi Q. Band gap characterization and photoluminescence properties of SiC nanowires. Appl Phys A. 2011;102(1):213–7.10.1007/s00339-010-5943-2Suche in Google Scholar

[34] Tauc J, Grigorovici R, Vancu A. Optical properties and electronic structure of amorphous germanium. Phys Status Solidi (b). 1966;15(2):627–37.10.1515/9783112492505-079Suche in Google Scholar

[35] Qian X, Gu N, Cheng Z, Yang X, Wang E, Dong S. Methods to study the ionic conductivity of polymeric electrolytes using a.c. impedance spectroscopy. J Solid State Electrochem. 2001;6(1):8–15.10.1007/s100080000190Suche in Google Scholar

[36] Ningaraju S, Ravikumar HB. Studies on electrical conductivity of PVA/graphite oxide nanocomposites: a free volume approach. J Polym Res. 2016;24(1):11.10.1007/s10965-016-1176-1Suche in Google Scholar

[37] Eslamian M, Zabihi F. Ultrasonic substrate vibration-assisted drop casting (SVADC) for the fabrication of photovoltaic solar cell arrays and thin-film devices. Nanoscale Res Lett. 2015;10(1):462.10.1186/s11671-015-1168-9Suche in Google Scholar PubMed PubMed Central

[38] Shekhirev M, Shuck CE, Sarycheva A, Gogotsi Y. Characterization of MXenes at every step, from their precursors to single flakes and assembled films. Prog Mater Sci. 2021;120:100757.10.1016/j.pmatsci.2020.100757Suche in Google Scholar

[39] Wan Y-J, Li X-M, Zhu P-L, Sun R, Wong C-P, Liao W-H. Lightweight, flexible MXene/polymer film with simultaneously excellent mechanical property and high-performance electromagnetic interference shielding. Compos Part A Appl Sci Manuf. 2020;130:105764.10.1016/j.compositesa.2020.105764Suche in Google Scholar

[40] Siddiqui MN, Redhwi HH, Vakalopoulou E, Tsagkalias I, Ioannidou MD, Achilias DS. Synthesis, characterization and reaction kinetics of PMMA/silver nanocomposites prepared via in situ radical polymerization. Eur Polym J. 2015;72:256–69.10.1016/j.eurpolymj.2015.09.019Suche in Google Scholar

[41] Tsagkalias IS, Manios TK, Achilias DS. Effect of graphene oxide on the reaction kinetics of methyl methacrylate in situ radical polymerization via the bulk or solution technique. Polymers. 2017;9:9.10.3390/polym9090432Suche in Google Scholar PubMed PubMed Central

[42] You Z, Liao Y, Li X, Fan J, Xiang Q. State-of-the-art recent progress in MXene-based photocatalysts: a comprehensive review. Nanoscale. 2021;13(21):9463–504.10.1039/D1NR02224ESuche in Google Scholar

[43] Li R, Zhang L, Shi L, Wang P. MXene Ti3C2: an effective 2D light-to-heat conversion material. ACS Nano. 2017;11(4):3752–9.10.1021/acsnano.6b08415Suche in Google Scholar PubMed

[44] Lin Z, Wang X, Liu J, Tian Z, Dai L, He B, et al. On the role of localized surface plasmon resonance in UV-Vis light irradiated Au/TiO2 photocatalysis systems: pros and cons. Nanoscale. 2015;7(9):4114–23.10.1039/C4NR06929CSuche in Google Scholar PubMed

[45] Iqbal A, Hong J, Ko TY, Koo CM. Improving oxidation stability of 2D MXenes: synthesis, storage media, and conditions. Nano Convergence. 2021;8(1):9.10.1186/s40580-021-00259-6Suche in Google Scholar PubMed PubMed Central

[46] Hemalatha KS, Sriprakash G, Ambika Prasad MVN, Damle R, Rukmani K. Temperature dependent dielectric and conductivity studies of polyvinyl alcohol-ZnO nanocomposite films by impedance spectroscopy. J Appl Phys. 2015;118(15):154103.10.1063/1.4933286Suche in Google Scholar

[47] Maleski K, Shuck CE, Fafarman AT, Gogotsi Y. The broad chromatic range of two-dimensional transition metal carbides. Adv Optical Mater. 2021;9(4):2001563.10.1002/adom.202001563Suche in Google Scholar

[48] Mergen ÖB, Arda E, Kara S, Pekcan Ö. Effects of GNP addition on optical properties and band gap energies of PMMA films. Polym Compos. 2019;40(5):1862–9.10.1002/pc.24948Suche in Google Scholar

[49] Hassanien AS, Akl AA. Effect of Se addition on optical and electrical properties of chalcogenide CdSSe thin films. Superlattices Microstruct. 2016;89:153–69.10.1016/j.spmi.2015.10.044Suche in Google Scholar

[50] Abdullah OG, Aziz SB, Omer KM, Salih YM. Reducing the optical band gap of polyvinyl alcohol (PVA) based nanocomposite. J Mater Sci Mater Electron. 2015;26(7):5303–9.10.1007/s10854-015-3067-3Suche in Google Scholar

[51] Jiang X, Kuklin AV, Baev A, Ge Y, Ågren H, Zhang H, et al. Two-dimensional MXenes: From morphological to optical, electric, and magnetic properties and applications. Phys Rep. 2020;848:1–58.10.1016/j.physrep.2019.12.006Suche in Google Scholar

[52] Anandraj J, Joshi GM, Pandey M. Study of polyvinylalcohol/polyionic organic semiconductor as thermistor. Advanced Materials Proceedings. 2017;2(4):228–30.10.5185/amp.2017/405Suche in Google Scholar

[53] El-Khodary A, Oraby AH, Abdelnaby MM. Characterization, electrical and magnetic properties of PVA films filled with FeCl3–MnCl2 mixed fillers. J Magnetism Magnetic Mater. 2008;320(11):1739–46.10.1016/j.jmmm.2008.01.030Suche in Google Scholar

[54] Alakanandana A, Subrahmanyam AR, Siva, Kumar J. Structural and electrical conductivity studies of pure PVA and PVA doped with Succinic acid polymer electrolyte system. Mater Today Proc. 2016;3(10, Part B):3680–8.10.1016/j.matpr.2016.11.013Suche in Google Scholar

[55] Kötz R, Hahn M, Gallay R. Temperature behavior and impedance fundamentals of supercapacitors. J Power Sources. 2006;154(2):550–5.10.1016/j.jpowsour.2005.10.048Suche in Google Scholar

[56] Careem MA, Noor ISM, Arof AK. Impedance spectroscopy in polymer electrolyte characterization. Polym Electrolytes Charact Tech Energy Appl. 2020;23–64.10.1002/9783527805457.ch2Suche in Google Scholar

[57] Zheng W, Wong S-C. Electrical conductivity and dielectric properties of PMMA/expanded graphite composites. Compos Sci Technol. 2003;63(2):225–35.10.1016/S0266-3538(02)00201-4Suche in Google Scholar

[58] Rozra J, Saini I, Sharma A, Chandak N, Aggarwal S, Dhiman R, et al. Cu nanoparticles induced structural, optical and electrical modification in PVA. Mater Chem Phys. 2012;134(2):1121–6.10.1016/j.matchemphys.2012.04.004Suche in Google Scholar
Received: 2022-05-30
Revised: 2022-08-27
Accepted: 2022-09-28
Published Online: 2022-11-28

© 2022 the author(s), published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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  40. Calculation of NaI(Tl) detector efficiency using 226Ra, 232Th, and 40K radioisotopes: Three-phase Monte Carlo simulation study
  41. Isolation and identification of unstable components from Caesalpinia sappan by high-speed counter-current chromatography combined with preparative high-performance liquid chromatography
  42. Quantification of biomarkers and evaluation of antioxidant, anti-inflammatory, and cytotoxicity properties of Dodonaea viscosa grown in Saudi Arabia using HPTLC technique
  43. Characterization of the elastic modulus of ceramic–metal composites with physical and mechanical properties by ultrasonic technique
  44. GC-MS analysis of Vespa velutina auraria Smith and its anti-inflammatory and antioxidant activities in vitro
  45. Texturing of nanocoatings for surface acoustic wave-based sensors for volatile organic compounds
  46. Insights into the molecular basis of some chalcone analogues as potential inhibitors of Leishmania donovani: An integrated in silico and in vitro study
  47. (1R,2S,5R)-5-Methyl-2-(propan-2-yl)cyclohexyl 4-amino-3-phenylbutanoate hydrochloride: Synthesis and anticonvulsant activity
  48. On the relative extraction rates of colour compounds and caffeine during brewing, an investigation of tea over time and temperature
  49. Characterization of egg shell powder-doped ceramic–metal composites
  50. Rapeseed oil-based hippurate amide nanocomposite coating material for anticorrosive and antibacterial applications
  51. Chemically modified Teucrium polium (Lamiaceae) plant act as an effective adsorbent tool for potassium permanganate (KMnO4) in wastewater remediation
  52. Efficiency analysis of photovoltaic systems installed in different geographical locations
  53. Risk prioritization model driven by success factor in the light of multicriteria decision making
  54. Theoretical investigations on the excited-state intramolecular proton transfer in the solvated 2-hydroxy-1-naphthaldehyde carbohydrazone
  55. Mechanical and gamma-ray shielding examinations of Bi2O3–PbO–CdO–B2O3 glass system
  56. Machine learning-based forecasting of potability of drinking water through adaptive boosting model
  57. The potential effect of the Rumex vesicarius water seeds extract treatment on mice before and during pregnancy on the serum enzymes and the histology of kidney and liver
  58. Impact of benzimidazole functional groups on the n-doping properties of benzimidazole derivatives
  59. Extraction of red pigment from Chinese jujube peel and the antioxidant activity of the pigment extracts
  60. Flexural strength and thermal properties of carbon black nanoparticle reinforced epoxy composites obtained from waste tires
  61. A focusing study on radioprotective and antioxidant effects of Annona muricata leaf extract in the circulation and liver tissue: Clinical and experimental studies
  62. Clinical comprehensive and experimental assessment of the radioprotective effect of Annona muricata leaf extract to prevent cellular damage in the ileum tissue
  63. Effect of WC content on ultrasonic properties, thermal and electrical conductivity of WC–Co–Ni–Cr composites
  64. Influence of various class cleaning agents for prosthesis on Co–Cr alloy surface
  65. The synthesis of nanocellulose-based nanocomposites for the effective removal of hexavalent chromium ions from aqueous solution
  66. Study on the influence of physical interlayers on the remaining oil production under different development modes
  67. Optimized linear regression control of DC motor under various disturbances
  68. Influence of different sample preparation strategies on hypothesis-driven shotgun proteomic analysis of human saliva
  69. Determination of flow distance of the fluid metal due to fluidity in ductile iron casting by artificial neural networks approach
  70. Investigation of mechanical activation effect on high-volume natural pozzolanic cements
  71. In vitro: Anti-coccidia activity of Calotropis procera leaf extract on Eimeria papillata oocysts sporulation and sporozoite
  72. Determination of oil composition of cowpea (Vigna unguiculata L.) seeds under influence of organic fertilizer forms
  73. Activated partial thromboplastin time maybe associated with the prognosis of papillary thyroid carcinoma
  74. Treatment of rat brain ischemia model by NSCs-polymer scaffold transplantation
  75. Lead and cadmium removal with native yeast from coastal wetlands
  76. Characterization of electroless Ni-coated Fe–Co composite using powder metallurgy
  77. Ferrate synthesis using NaOCl and its application for dye removal
  78. Antioxidant, antidiabetic, and anticholinesterase potential of Chenopodium murale L. extracts using in vitro and in vivo approaches
  79. Study on essential oil, antioxidant activity, anti-human prostate cancer effects, and induction of apoptosis by Equisetum arvense
  80. Experimental study on turning machine with permanent magnetic cutting tool
  81. Numerical simulation and mathematical modeling of the casting process for pearlitic spheroidal graphite cast iron
  82. Design, synthesis, and cytotoxicity evaluation of novel thiophene, pyrimidine, pyridazine, and pyridine: Griseofulvin heterocyclic extension derivatives
  83. Isolation and identification of promising antibiotic-producing bacteria
  84. Ultrasonic-induced reversible blood–brain barrier opening: Safety evaluation into the cellular level
  85. Evaluation of phytochemical and antioxidant potential of various extracts from traditionally used medicinal plants of Pakistan
  86. Effect of calcium lactate in standard diet on selected markers of oxidative stress and inflammation in ovariectomized rats
  87. Identification of crucial salivary proteins/genes and pathways involved in pathogenesis of temporomandibular disorders
  88. Zirconium-modified attapulgite was used for removing of Cr(vi) in aqueous solution
  89. The stress distribution of different types of restorative materials in primary molar
  90. Reducing surface heat loss in steam boilers
  91. Deformation behavior and formability of friction stir processed DP600 steel
  92. Synthesis and characterization of bismuth oxide/commercial activated carbon composite for battery anode
  93. Phytochemical analysis of Ziziphus jujube leaf at different foliar ages based on widely targeted metabolomics
  94. Effects of in ovo injection of black cumin (Nigella sativa) extract on hatching performance of broiler eggs
  95. Separation and evaluation of potential antioxidant, analgesic, and anti-inflammatory activities of limonene-rich essential oils from Citrus sinensis (L.)
  96. Bioactivity of a polyhydroxy gorgostane steroid from Xenia umbellata
  97. BiCAM-based automated scoring system for digital logic circuit diagrams
  98. Analysis of standard systems with solar monitoring systems
  99. Structural and spectroscopic properties of voriconazole and fluconazole – Experimental and theoretical studies
  100. New plant resistance inducers based on polyamines
  101. Experimental investigation of single-lap bolted and bolted/bonded (hybrid) joints of polymeric plates
  102. Investigation of inlet air pressure and evaporative cooling of four different cogeneration cycles
  103. Review Articles
  104. Comprehensive review on synthesis, physicochemical properties, and application of activated carbon from the Arecaceae plants for enhanced wastewater treatment
  105. Research progress on speciation analysis of arsenic in traditional Chinese medicine
  106. Recent modified air-assisted liquid–liquid microextraction applications for medicines and organic compounds in various samples: A review
  107. An insight on Vietnamese bio-waste materials as activated carbon precursors for multiple applications in environmental protection
  108. Antimicrobial activities of the extracts and secondary metabolites from Clausena genus – A review
  109. Bioremediation of organic/heavy metal contaminants by mixed cultures of microorganisms: A review
  110. Sonodynamic therapy for breast cancer: A literature review
  111. Recent progress of amino acid transporters as a novel antitumor target
  112. Aconitum coreanum Rapaics: Botany, traditional uses, phytochemistry, pharmacology, and toxicology
  113. Corrigendum
  114. Corrigendum to “Petrology and geochemistry of multiphase post-granitic dikes: A case study from the Gabal Serbal area, Southwestern Sinai, Egypt”
  115. Corrigendum to “Design of a Robust sliding mode controller for bioreactor cultures in overflow metabolism via an interdisciplinary approach”
  116. Corrigendum to “Statistical analysis on the radiological assessment and geochemical studies of granite rocks in the north of Um Taghir area, Eastern Desert, Egypt”
  117. Corrigendum to “Aroma components of tobacco powder from different producing areas based on gas chromatography ion mobility spectrometry”
  118. Corrigendum to “Mechanical properties, elastic moduli, transmission factors, and gamma-ray-shielding performances of Bi2O3–P2O5–B2O3–V2O5 quaternary glass system”
  119. Erratum
  120. Erratum to “Copper(ii) complexes supported by modified azo-based ligands: Nucleic acid binding and molecular docking studies”
  121. Special Issue on Applied Biochemistry and Biotechnology (ABB 2021)
  122. Study of solidification and stabilization of heavy metals by passivators in heavy metal-contaminated soil
  123. Human health risk assessment and distribution of VOCs in a chemical site, Weinan, China
  124. Preparation and characterization of Sparassis latifolia β-glucan microcapsules
  125. Special Issue on the Conference of Energy, Fuels, Environment 2020
  126. Improving the thermal performance of existing buildings in light of the requirements of the EU directive 2010/31/EU in Poland
  127. Special Issue on Ethnobotanical, Phytochemical and Biological Investigation of Medicinal Plants
  128. Study of plant resources with ethnomedicinal relevance from district Bagh, Azad Jammu and Kashmir, Pakistan
  129. Studies on the chemical composition of plants used in traditional medicine in Congo
  130. Special Issue on Applied Chemistry in Agriculture and Food Science
  131. Strip spraying technology for precise herbicide application in carrot fields
  132. Special Issue on Pharmacology and Metabolomics of Ethnobotanical and Herbal Medicine
  133. Phytochemical profiling, antibacterial and antioxidant properties of Crocus sativus flower: A comparison between tepals and stigmas
  134. Antioxidant and antimicrobial properties of polyphenolics from Withania adpressa (Coss.) Batt. against selected drug-resistant bacterial strains
  135. Integrating network pharmacology and molecular docking to explore the potential mechanism of Xinguan No. 3 in the treatment of COVID-19
  136. Chemical composition and in vitro and in vivo biological assortment of fixed oil extracted from Ficus benghalensis L.
  137. A review of the pharmacological activities and protective effects of Inonotus obliquus triterpenoids in kidney diseases
  138. Ethnopharmacological study of medicinal plants in Kastamonu province (Türkiye)
  139. Protective effects of asperuloside against cyclophosphamide-induced urotoxicity and hematotoxicity in rats
  140. Special Issue on Essential Oil, Extraction, Phytochemistry, Advances, and Application
  141. Identification of volatile compounds and antioxidant, antibacterial, and antifungal properties against drug-resistant microbes of essential oils from the leaves of Mentha rotundifolia var. apodysa Briq. (Lamiaceae)
  142. Phenolic contents, anticancer, antioxidant, and antimicrobial capacities of MeOH extract from the aerial parts of Trema orientalis plant
  143. Chemical composition and antimicrobial activity of essential oils from Mentha pulegium and Rosmarinus officinalis against multidrug-resistant microbes and their acute toxicity study
  144. Special Issue on Marine Environmental Sciences and Significance of the Multidisciplinary Approaches
  145. An insightful overview of the distribution pattern of polycyclic aromatic hydrocarbon in the marine sediments of the Red Sea
  146. Antifungal–antiproliferative norcycloartane-type triterpenes from the Red Sea green alga Tydemania expeditionis
  147. Solvent effect, dipole moment, and DFT studies of multi donor–acceptor type pyridine derivative
  148. An extensive assessment on the distribution pattern of organic contaminants in the aerosols samples in the Middle East
  149. Special Issue on 4th IC3PE
  150. Energetics of carboxylic acid–pyridine heterosynthon revisited: A computational study of intermolecular hydrogen bond domination on phenylacetic acid–nicotinamide cocrystals
  151. A review: Silver–zinc oxide nanoparticles – organoclay-reinforced chitosan bionanocomposites for food packaging
  152. Green synthesis of magnetic activated carbon from peanut shells functionalized with TiO2 photocatalyst for Batik liquid waste treatment
  153. Coagulation activity of liquid extraction of Leucaena leucocephala and Sesbania grandiflora on the removal of turbidity
  154. Hydrocracking optimization of palm oil over NiMoO4/activated carbon catalyst to produce biogasoline and kerosine
  155. Special Issue on Pharmacology and metabolomics of ethnobotanical and herbal medicine
  156. Cynarin inhibits PDGF-BB-induced proliferation and activation in hepatic stellate cells through PPARγ
  157. Special Issue on The 1st Malaysia International Conference on Nanotechnology & Catalysis (MICNC2021)
  158. Surfactant evaluation for enhanced oil recovery: Phase behavior and interfacial tension
  159. Topical Issue on phytochemicals, biological and toxicological analysis of aromatic medicinal plants
  160. Phytochemical analysis of leaves and stems of Physalis alkekengi L. (Solanaceae)
  161. Phytochemical and pharmacological profiling of Trewia nudiflora Linn. leaf extract deciphers therapeutic potentials against thrombosis, arthritis, helminths, and insects
  162. Pergularia tomentosa coupled with selenium nanoparticles salvaged lead acetate-induced redox imbalance, inflammation, apoptosis, and disruption of neurotransmission in rats’ brain
  163. Protective effect of Allium atroviolaceum-synthesized SeNPs on aluminum-induced brain damage in mice
  164. Mechanism study of Cordyceps sinensis alleviates renal ischemia–reperfusion injury
  165. Plant-derived bisbenzylisoquinoline alkaloid tetrandrine prevents human podocyte injury by regulating the miR-150-5p/NPHS1 axis
  166. Network pharmacology combined with molecular docking to explore the anti-osteoporosis mechanisms of β-ecdysone derived from medicinal plants
  167. Chinese medicinal plant Polygonum cuspidatum ameliorates silicosis via suppressing the Wnt/β-catenin pathway
  168. Special Issue on Advanced Nanomaterials for Energy, Environmental and Biological Applications - Part I
  169. Investigation of improved optical and conductivity properties of poly(methyl methacrylate)–MXenes (PMMA–MXenes) nanocomposite thin films for optoelectronic applications
  170. Special Issue on Applied Biochemistry and Biotechnology (ABB 2022)
  171. Model predictive control for precision irrigation of a Quinoa crop
https://doi.org/10.1515/chem-2022-0221
Schlagwörter für diesen Artikel
MXenes; nanocomposites; impedance; conductivity; optical
Creative Commons
BY 4.0

Artikel in diesem Heft

  1. Regular Articles
  2. Photocatalytic degradation of Rhodamine B in aqueous phase by bimetallic metal-organic framework M/Fe-MOF (M = Co, Cu, and Mg)
  3. Assessment of using electronic portal imaging device for analysing bolus material utilised in radiation therapy
  4. A detailed investigation on highly dense CuZr bulk metallic glasses for shielding purposes
  5. Simulation of gamma-ray shielding properties for materials of medical interest
  6. Environmental impact assesment regulation applications and their analysis in Turkey
  7. Sample age effect on parameters of dynamic nuclear polarization in certain difluorobenzen isomers/MC800 asphaltene suspensions
  8. Passenger demand forecasting for railway systems
  9. Design of a Robust sliding mode controller for bioreactor cultures in overflow metabolism via an interdisciplinary approach
  10. Gamma, neutron, and heavy charged ion shielding properties of Er3+-doped and Sm3+-doped zinc borate glasses
  11. Bridging chiral de-tert-butylcalix[4]arenes: Optical resolution based on column chromatography and structural characterization
  12. Petrology and geochemistry of multiphase post-granitic dikes: A case study from the Gabal Serbal area, Southwestern Sinai, Egypt
  13. Comparison of the yield and purity of plasma exosomes extracted by ultracentrifugation, precipitation, and membrane-based approaches
  14. Bioactive triterpenoids from Indonesian medicinal plant Syzygium aqueum
  15. Investigation of the effects of machining parameters on surface integrity in micromachining
  16. The mesoporous aluminosilicate application as support for bifunctional catalysts for n-hexadecane hydroconversion
  17. Gamma-ray shielding properties of Nd2O3-added iron–boron–phosphate-based composites
  18. Numerical investigation on perforated sheet metals under tension loading
  19. Statistical analysis on the radiological assessment and geochemical studies of granite rocks in the north of Um Taghir area, Eastern Desert, Egypt
  20. Two new polypodane-type bicyclic triterpenoids from mastic
  21. Structural, physical, and mechanical properties of the TiO2 added hydroxyapatite composites
  22. Tribological properties and characterization of borided Co–Mg alloys
  23. Studies on Anemone nemorosa L. extracts; polyphenols profile, antioxidant activity, and effects on Caco-2 cells by in vitro and in silico studies
  24. Mechanical properties, elastic moduli, transmission factors, and gamma-ray-shielding performances of Bi2O3–P2O5–B2O3–V2O5 quaternary glass system
  25. Cyclic connectivity index of bipolar fuzzy incidence graph
  26. The role of passage numbers of donor cells in the development of Arabian Oryx – Cow interspecific somatic cell nuclear transfer embryos
  27. Mechanical property evaluation of tellurite–germanate glasses and comparison of their radiation-shielding characteristics using EPICS2017 to other glass systems
  28. Molecular screening of ionic liquids for CO2 absorption and molecular dynamic simulation
  29. Microwave-assisted preparation of Ag/Fe magnetic biochar from clivia leaves for adsorbing daptomycin antibiotics
  30. Iminodisuccinic acid enhances antioxidant and mineral element accumulation in young leaves of Ziziphus jujuba
  31. Cytotoxic activity of guaiane-type sesquiterpene lactone (deoxycynaropicrin) isolated from the leaves of Centaurothamnus maximus
  32. Effects of welding parameters on the angular distortion of welded steel plates
  33. Simulation of a reactor considering the Stamicarbon, Snamprogetti, and Toyo patents for obtaining urea
  34. Effect of different ramie (Boehmeria nivea L. Gaud) cultivars on the adsorption of heavy metal ions cadmium and lead in the remediation of contaminated farmland soils
  35. Impact of a live bacterial-based direct-fed microbial (DFM) postpartum and weaning system on performance, mortality, and health of Najdi lambs
  36. Anti-tumor effect of liposomes containing extracted Murrayafoline A against liver cancer cells in 2D and 3D cultured models
  37. Physicochemical properties and some mineral concentration of milk samples from different animals and altitudes
  38. Copper(ii) complexes supported by modified azo-based ligands: Nucleic acid binding and molecular docking studies
  39. Diagnostic and therapeutic radioisotopes in nuclear medicine: Determination of gamma-ray transmission factors and safety competencies of high-dense and transparent glassy shields
  40. Calculation of NaI(Tl) detector efficiency using 226Ra, 232Th, and 40K radioisotopes: Three-phase Monte Carlo simulation study
  41. Isolation and identification of unstable components from Caesalpinia sappan by high-speed counter-current chromatography combined with preparative high-performance liquid chromatography
  42. Quantification of biomarkers and evaluation of antioxidant, anti-inflammatory, and cytotoxicity properties of Dodonaea viscosa grown in Saudi Arabia using HPTLC technique
  43. Characterization of the elastic modulus of ceramic–metal composites with physical and mechanical properties by ultrasonic technique
  44. GC-MS analysis of Vespa velutina auraria Smith and its anti-inflammatory and antioxidant activities in vitro
  45. Texturing of nanocoatings for surface acoustic wave-based sensors for volatile organic compounds
  46. Insights into the molecular basis of some chalcone analogues as potential inhibitors of Leishmania donovani: An integrated in silico and in vitro study
  47. (1R,2S,5R)-5-Methyl-2-(propan-2-yl)cyclohexyl 4-amino-3-phenylbutanoate hydrochloride: Synthesis and anticonvulsant activity
  48. On the relative extraction rates of colour compounds and caffeine during brewing, an investigation of tea over time and temperature
  49. Characterization of egg shell powder-doped ceramic–metal composites
  50. Rapeseed oil-based hippurate amide nanocomposite coating material for anticorrosive and antibacterial applications
  51. Chemically modified Teucrium polium (Lamiaceae) plant act as an effective adsorbent tool for potassium permanganate (KMnO4) in wastewater remediation
  52. Efficiency analysis of photovoltaic systems installed in different geographical locations
  53. Risk prioritization model driven by success factor in the light of multicriteria decision making
  54. Theoretical investigations on the excited-state intramolecular proton transfer in the solvated 2-hydroxy-1-naphthaldehyde carbohydrazone
  55. Mechanical and gamma-ray shielding examinations of Bi2O3–PbO–CdO–B2O3 glass system
  56. Machine learning-based forecasting of potability of drinking water through adaptive boosting model
  57. The potential effect of the Rumex vesicarius water seeds extract treatment on mice before and during pregnancy on the serum enzymes and the histology of kidney and liver
  58. Impact of benzimidazole functional groups on the n-doping properties of benzimidazole derivatives
  59. Extraction of red pigment from Chinese jujube peel and the antioxidant activity of the pigment extracts
  60. Flexural strength and thermal properties of carbon black nanoparticle reinforced epoxy composites obtained from waste tires
  61. A focusing study on radioprotective and antioxidant effects of Annona muricata leaf extract in the circulation and liver tissue: Clinical and experimental studies
  62. Clinical comprehensive and experimental assessment of the radioprotective effect of Annona muricata leaf extract to prevent cellular damage in the ileum tissue
  63. Effect of WC content on ultrasonic properties, thermal and electrical conductivity of WC–Co–Ni–Cr composites
  64. Influence of various class cleaning agents for prosthesis on Co–Cr alloy surface
  65. The synthesis of nanocellulose-based nanocomposites for the effective removal of hexavalent chromium ions from aqueous solution
  66. Study on the influence of physical interlayers on the remaining oil production under different development modes
  67. Optimized linear regression control of DC motor under various disturbances
  68. Influence of different sample preparation strategies on hypothesis-driven shotgun proteomic analysis of human saliva
  69. Determination of flow distance of the fluid metal due to fluidity in ductile iron casting by artificial neural networks approach
  70. Investigation of mechanical activation effect on high-volume natural pozzolanic cements
  71. In vitro: Anti-coccidia activity of Calotropis procera leaf extract on Eimeria papillata oocysts sporulation and sporozoite
  72. Determination of oil composition of cowpea (Vigna unguiculata L.) seeds under influence of organic fertilizer forms
  73. Activated partial thromboplastin time maybe associated with the prognosis of papillary thyroid carcinoma
  74. Treatment of rat brain ischemia model by NSCs-polymer scaffold transplantation
  75. Lead and cadmium removal with native yeast from coastal wetlands
  76. Characterization of electroless Ni-coated Fe–Co composite using powder metallurgy
  77. Ferrate synthesis using NaOCl and its application for dye removal
  78. Antioxidant, antidiabetic, and anticholinesterase potential of Chenopodium murale L. extracts using in vitro and in vivo approaches
  79. Study on essential oil, antioxidant activity, anti-human prostate cancer effects, and induction of apoptosis by Equisetum arvense
  80. Experimental study on turning machine with permanent magnetic cutting tool
  81. Numerical simulation and mathematical modeling of the casting process for pearlitic spheroidal graphite cast iron
  82. Design, synthesis, and cytotoxicity evaluation of novel thiophene, pyrimidine, pyridazine, and pyridine: Griseofulvin heterocyclic extension derivatives
  83. Isolation and identification of promising antibiotic-producing bacteria
  84. Ultrasonic-induced reversible blood–brain barrier opening: Safety evaluation into the cellular level
  85. Evaluation of phytochemical and antioxidant potential of various extracts from traditionally used medicinal plants of Pakistan
  86. Effect of calcium lactate in standard diet on selected markers of oxidative stress and inflammation in ovariectomized rats
  87. Identification of crucial salivary proteins/genes and pathways involved in pathogenesis of temporomandibular disorders
  88. Zirconium-modified attapulgite was used for removing of Cr(vi) in aqueous solution
  89. The stress distribution of different types of restorative materials in primary molar
  90. Reducing surface heat loss in steam boilers
  91. Deformation behavior and formability of friction stir processed DP600 steel
  92. Synthesis and characterization of bismuth oxide/commercial activated carbon composite for battery anode
  93. Phytochemical analysis of Ziziphus jujube leaf at different foliar ages based on widely targeted metabolomics
  94. Effects of in ovo injection of black cumin (Nigella sativa) extract on hatching performance of broiler eggs
  95. Separation and evaluation of potential antioxidant, analgesic, and anti-inflammatory activities of limonene-rich essential oils from Citrus sinensis (L.)
  96. Bioactivity of a polyhydroxy gorgostane steroid from Xenia umbellata
  97. BiCAM-based automated scoring system for digital logic circuit diagrams
  98. Analysis of standard systems with solar monitoring systems
  99. Structural and spectroscopic properties of voriconazole and fluconazole – Experimental and theoretical studies
  100. New plant resistance inducers based on polyamines
  101. Experimental investigation of single-lap bolted and bolted/bonded (hybrid) joints of polymeric plates
  102. Investigation of inlet air pressure and evaporative cooling of four different cogeneration cycles
  103. Review Articles
  104. Comprehensive review on synthesis, physicochemical properties, and application of activated carbon from the Arecaceae plants for enhanced wastewater treatment
  105. Research progress on speciation analysis of arsenic in traditional Chinese medicine
  106. Recent modified air-assisted liquid–liquid microextraction applications for medicines and organic compounds in various samples: A review
  107. An insight on Vietnamese bio-waste materials as activated carbon precursors for multiple applications in environmental protection
  108. Antimicrobial activities of the extracts and secondary metabolites from Clausena genus – A review
  109. Bioremediation of organic/heavy metal contaminants by mixed cultures of microorganisms: A review
  110. Sonodynamic therapy for breast cancer: A literature review
  111. Recent progress of amino acid transporters as a novel antitumor target
  112. Aconitum coreanum Rapaics: Botany, traditional uses, phytochemistry, pharmacology, and toxicology
  113. Corrigendum
  114. Corrigendum to “Petrology and geochemistry of multiphase post-granitic dikes: A case study from the Gabal Serbal area, Southwestern Sinai, Egypt”
  115. Corrigendum to “Design of a Robust sliding mode controller for bioreactor cultures in overflow metabolism via an interdisciplinary approach”
  116. Corrigendum to “Statistical analysis on the radiological assessment and geochemical studies of granite rocks in the north of Um Taghir area, Eastern Desert, Egypt”
  117. Corrigendum to “Aroma components of tobacco powder from different producing areas based on gas chromatography ion mobility spectrometry”
  118. Corrigendum to “Mechanical properties, elastic moduli, transmission factors, and gamma-ray-shielding performances of Bi2O3–P2O5–B2O3–V2O5 quaternary glass system”
  119. Erratum
  120. Erratum to “Copper(ii) complexes supported by modified azo-based ligands: Nucleic acid binding and molecular docking studies”
  121. Special Issue on Applied Biochemistry and Biotechnology (ABB 2021)
  122. Study of solidification and stabilization of heavy metals by passivators in heavy metal-contaminated soil
  123. Human health risk assessment and distribution of VOCs in a chemical site, Weinan, China
  124. Preparation and characterization of Sparassis latifolia β-glucan microcapsules
  125. Special Issue on the Conference of Energy, Fuels, Environment 2020
  126. Improving the thermal performance of existing buildings in light of the requirements of the EU directive 2010/31/EU in Poland
  127. Special Issue on Ethnobotanical, Phytochemical and Biological Investigation of Medicinal Plants
  128. Study of plant resources with ethnomedicinal relevance from district Bagh, Azad Jammu and Kashmir, Pakistan
  129. Studies on the chemical composition of plants used in traditional medicine in Congo
  130. Special Issue on Applied Chemistry in Agriculture and Food Science
  131. Strip spraying technology for precise herbicide application in carrot fields
  132. Special Issue on Pharmacology and Metabolomics of Ethnobotanical and Herbal Medicine
  133. Phytochemical profiling, antibacterial and antioxidant properties of Crocus sativus flower: A comparison between tepals and stigmas
  134. Antioxidant and antimicrobial properties of polyphenolics from Withania adpressa (Coss.) Batt. against selected drug-resistant bacterial strains
  135. Integrating network pharmacology and molecular docking to explore the potential mechanism of Xinguan No. 3 in the treatment of COVID-19
  136. Chemical composition and in vitro and in vivo biological assortment of fixed oil extracted from Ficus benghalensis L.
  137. A review of the pharmacological activities and protective effects of Inonotus obliquus triterpenoids in kidney diseases
  138. Ethnopharmacological study of medicinal plants in Kastamonu province (Türkiye)
  139. Protective effects of asperuloside against cyclophosphamide-induced urotoxicity and hematotoxicity in rats
  140. Special Issue on Essential Oil, Extraction, Phytochemistry, Advances, and Application
  141. Identification of volatile compounds and antioxidant, antibacterial, and antifungal properties against drug-resistant microbes of essential oils from the leaves of Mentha rotundifolia var. apodysa Briq. (Lamiaceae)
  142. Phenolic contents, anticancer, antioxidant, and antimicrobial capacities of MeOH extract from the aerial parts of Trema orientalis plant
  143. Chemical composition and antimicrobial activity of essential oils from Mentha pulegium and Rosmarinus officinalis against multidrug-resistant microbes and their acute toxicity study
  144. Special Issue on Marine Environmental Sciences and Significance of the Multidisciplinary Approaches
  145. An insightful overview of the distribution pattern of polycyclic aromatic hydrocarbon in the marine sediments of the Red Sea
  146. Antifungal–antiproliferative norcycloartane-type triterpenes from the Red Sea green alga Tydemania expeditionis
  147. Solvent effect, dipole moment, and DFT studies of multi donor–acceptor type pyridine derivative
  148. An extensive assessment on the distribution pattern of organic contaminants in the aerosols samples in the Middle East
  149. Special Issue on 4th IC3PE
  150. Energetics of carboxylic acid–pyridine heterosynthon revisited: A computational study of intermolecular hydrogen bond domination on phenylacetic acid–nicotinamide cocrystals
  151. A review: Silver–zinc oxide nanoparticles – organoclay-reinforced chitosan bionanocomposites for food packaging
  152. Green synthesis of magnetic activated carbon from peanut shells functionalized with TiO2 photocatalyst for Batik liquid waste treatment
  153. Coagulation activity of liquid extraction of Leucaena leucocephala and Sesbania grandiflora on the removal of turbidity
  154. Hydrocracking optimization of palm oil over NiMoO4/activated carbon catalyst to produce biogasoline and kerosine
  155. Special Issue on Pharmacology and metabolomics of ethnobotanical and herbal medicine
  156. Cynarin inhibits PDGF-BB-induced proliferation and activation in hepatic stellate cells through PPARγ
  157. Special Issue on The 1st Malaysia International Conference on Nanotechnology & Catalysis (MICNC2021)
  158. Surfactant evaluation for enhanced oil recovery: Phase behavior and interfacial tension
  159. Topical Issue on phytochemicals, biological and toxicological analysis of aromatic medicinal plants
  160. Phytochemical analysis of leaves and stems of Physalis alkekengi L. (Solanaceae)
  161. Phytochemical and pharmacological profiling of Trewia nudiflora Linn. leaf extract deciphers therapeutic potentials against thrombosis, arthritis, helminths, and insects
  162. Pergularia tomentosa coupled with selenium nanoparticles salvaged lead acetate-induced redox imbalance, inflammation, apoptosis, and disruption of neurotransmission in rats’ brain
  163. Protective effect of Allium atroviolaceum-synthesized SeNPs on aluminum-induced brain damage in mice
  164. Mechanism study of Cordyceps sinensis alleviates renal ischemia–reperfusion injury
  165. Plant-derived bisbenzylisoquinoline alkaloid tetrandrine prevents human podocyte injury by regulating the miR-150-5p/NPHS1 axis
  166. Network pharmacology combined with molecular docking to explore the anti-osteoporosis mechanisms of β-ecdysone derived from medicinal plants
  167. Chinese medicinal plant Polygonum cuspidatum ameliorates silicosis via suppressing the Wnt/β-catenin pathway
  168. Special Issue on Advanced Nanomaterials for Energy, Environmental and Biological Applications - Part I
  169. Investigation of improved optical and conductivity properties of poly(methyl methacrylate)–MXenes (PMMA–MXenes) nanocomposite thin films for optoelectronic applications
  170. Special Issue on Applied Biochemistry and Biotechnology (ABB 2022)
  171. Model predictive control for precision irrigation of a Quinoa crop
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Heruntergeladen am 13.9.2025 von https://www.degruyterbrill.com/document/doi/10.1515/chem-2022-0221/html
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