DFT and QSAR studies of PTFE/ZnO/SiO2 nanocomposite

Scientific Reports volume 13, Article number: 9696 (2023) Cite this article

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Polytetrafluoroethylene (PTFE) is one of the most significant fluoropolymers, and one of the most recent initiatives is to increase its performance by using metal oxides (MOs). Consequently, the surface modifications of PTFE with two metal oxides (MOs), SiO2 and ZnO, individually and as a mixture of the two MOs, were modeled using density functional theory (DFT). The B3LYPL/LANL2DZ model was used in the studies conducted to follow up the changes in electronic properties. The total dipole moment (TDM) and HOMO/LUMO band gap energy (∆E) of PTFE, which were 0.000 Debye and 8.517 eV respectively, were enhanced to 13.008 Debye and 0.690 eV in the case of PTFE/4ZnO/4SiO2. Moreover, with increasing nano filler (PTFE/8ZnO/8SiO2), TDM changed to 10.605 Debye and ∆E decreased to 0.273 eV leading to further improvement in the electronic properties. The molecular electrostatic potential (MESP) and quantitative structure activity relationship (QSAR) studies revealed that surface modification of PTFE with ZnO and SiO2 increased its electrical and thermal stability. The improved PTFE/ZnO/SiO2 composite can, therefore, be used as a self-cleaning layer for astronaut suits based on the findings of relatively high mobility, minimal reactivity to the surrounding environment, and thermal stability.

Polyethylene naphthalate (PEN), polyethylene terephthalate (PET), and polytetrafluoroethylene (PTFE) are among the well-known polymers owing to their corrosion resistance and electrical characteristics, as well as their low coefficient of friction, high temperature resistance, and cost efficiency1. Super hydrophobic materials such as fluoropolymers have become an extraordinary advantage in a number of applications, including self-cleaning, anti-icing, anti-corrosion, and protective properties such as high efficiency2,3. Smart textiles are also considered a new trend based on fluoropolymers with nanomaterials that might be used to improve textiles such as space suits and gloves, medical applications such as surgical garments, and usage in smart hospitals4,5. PTFE is a polymer matrix with a low surface energy and is chemically and thermally stable6. Smart materials innovation might be employed in space applications like spacesuits and storage by modifying materials to react to changes in ambient temperature or even body temperature7,8,9. PTFE properties such as anticorrosive properties are becoming increasingly significant, particularly in the aerospace industry. The significance arises from its benefits, which are critical for protecting materials from cracking and/or corrosion in the harsh aerospace environment. Consequently, utilizing an anti-corrosion substance to adequately protect and prevent astronaut suits from rust and corrosion is a novel approach10,11,12. The effective manufacturing of a wide range of sensors is enabled by the use of PTFE as a substrate for the growth of ZnO nanotubes, as well as its mechanical, physical, and chemical characteristics13. Nano silica is a type of ceramic material that has several unique properties, including high hardness, corrosion resistance, and outstanding electrical insulation14. All of these properties combine to make SiO2 and PTFE a unique material that is ideal for a wide range of technical applications15. In addition, combining SiO2 with semiconductor oxide materials such as ZnO16, TiO217, Fe2O318, and CuO19 improves the self-cleaning, anti-corrosion, anti-reflective, and magnetic characteristics of nanocomposite materials.

PTFE/SiO2 composite has a superhydrophobic surface when compared to PTFE membranes20. PTFE/SiO2 nanofibers have shown to be a reliable invention for excellent thermal and chemical stability21. Doping PTFE with SiO2 reduces PTFE porosity deformation while simultaneously increasing the material's tensile strength and endurance. As the quantity of SiO2 in the PTFE/SiO2 composite increased, so did the mechanical characteristics22. The tribological efficiency of PTFE/SiO2/Epoxy composites was also studied23. The effect of Al2O3 nanoplatelets on the PTFE matrix was observed to increase thermal conductivity, thermal stability, and enhance the mechanical properties with significantly enhanced electrical properties24. Furthermore, the electrical characteristics of the PANI/PTFE/GO25 and PTFE/CuO/G26 hybrid composites have shown an improvement to be employed in the fabrication of electrochemical instruments. The ZnO/SiO2/PTFE film over glass was made with anti-icing properties, corrosion resistance, and insulation properties, thus acting as an anti-icing surface27. Furthermore, some derivatives of PTFE, such as Teflon FEP, are used as thermal control layers for the Hubble Space Telescope (HST)28,29,30. Teflon FEP suffers from corrosion due to the space environment in the low Earth orbit (LEO)31, thus exposing the components in space to damage and corrosion32,33.

Consequently, improving PTFE and its derivatives has been a valuable point of study for space applications34,35.

Some physical parameters such as TDM, HOMO/LUMO band gap energy (∆E), and MESP are regarded as efficient predictors of electrical properties as well as the reactivity of the studied interactions36,37,38,39,40. Furthermore, QSAR provides important information on molecular behaviors, by evaluating the chemical, biological, and physical activities of molecules used in numerous applications41,42,43,44. By examining the hydrophobicity of a given structure and its behavior with its surroundings, DFT calculations using various physical parameters are commonly used to confirm superhydrophobic and exceptional performance in anti-corrosion, anti-icing, and self-cleaning45,46.

Based on the described features of PTFE and its nanocomposites, the current work is conducted to investigate the physicochemical properties such as anti-corrosion and self-cleaning of surface modified PTFE utilizing ZnO and SiO2 individually and combined. DFT calculations were performed using the B3LYP/LANL2DZ model to track changes in TDM, ∆E and mapping MESP, all of which representing changes in electronic characteristics. Electronic property information associated with QSAR descriptors were utilized to evaluate electronic characteristics, as well as thermal, physical, and chemical stability for potential usage as corrosion-inhibiting layers in astronaut suits.

PTFE model molecule interacted with two nano-MOs, ZnO and SiO2, separately and as a mixture were calculated using the GAUSSIAN 09 software (Gaussian, Inc.: Wallingford, CT, USA)47 at the Molecular Spectroscopy and Modeling Unit, National Research Centre (NRC), Egypt. DFT:B3LYP/LANL2DZ was used to optimize the proposed models48,49,50. Electronic properties were studied, including TDM, ΔE and MESP. Furthermore, SCIGRESS 3.0 software51 was used to study the chemical and thermal stability for all the model structures. QSAR parameters were calculated for model structures using MO-G at PM6 level of theory52.

A model of molecules simulating PTFE coated with MOs to promote hydrophobicity, anticorrosion, and self-cleaning qualities53. MOs including ZnO and SiO2 have been suggested as coating layers because of their anticorrosion and self-cleaning properties54,55. Consequently, the model of the smallest set of PTFE chemical units, representing a PTFE polymer chain, is designed to interact with ZnO and SiO2 both individually and combined. The interaction of PTFE with MOs takes place via the oxygen atom of the MO26,56. Because PTFE interacts chemically via its active sides, and since it has four equal active sides according to the chemical formula C2F4; therefore, any fluorine (F-) atom can interact with other chemical structures. As indicated in Fig. 1a,b, the model of the smallest unit representing the two MOs (ZnO and SiO2) and the PTFE polymer chain, was made up of four units of C2F4 that were designed to interact with the suggested two MOs. First, the PTFE chain was designed to interact with four units of ZnO and four units of SiO2, separately, coated on one side, as shown in Fig. 1c,d, respectively. After that, the PTFE chain is designed to interact with a combination of four units of ZnO and four units of SiO2 covered layer by layer as shown in Fig. 1e. Figure 1f depicts the PTFE chain's model structure as it interacts with a combination of four units of SiO2 and four units of ZnO covered layer by layer on its surface. Figure 1g depicts the final model structure for the PTFE chain in interaction with a single mixed layer of four ZnO and four SiO2 units. Increasing the quantity of nanoparticles on the polymer's surface has a significant impact on the electrical properties of the polymer's matrix57. Following that, the PTFE chain is next expected to be coated from both sides, as previously done with four units of ZnO and four units of SiO2 individually and combined, as shown in Fig. 2. The electrical characteristics of PTFE/MOs were then examined for the proposed interaction mechanisms by studying the calculated TDM, ΔE and MESP maps.

Optimized structure for PTFE and PTFE interaction with 4 ZnO, 4 SiO2 and a combination between the two MOs as (a) MOs (ZnO and SiO2), (b) PTFE, (c) PTFE/4ZnO, (d) PTFE/4SiO2, (e) PTFE/4ZnO/4SiO2, (f) PTFE/4SiO2/4ZnO and (g) PTFE/(4ZnO&4SiO2).

Optimized structure for PTFE and PTFE interaction with 8 ZnO, 8 SiO2 and a combination between the two MOs as (a) PTFE/8ZnO, (b) PTFE/8SiO2, (c) PTFE/8ZnO/8 SiO2, (d) PTFE/8 SiO2/8ZnO and (e) PTFE/(8ZnO&8 SiO2).

Figure 3 illustrates the HOMO/LUMO orbital distribution of PTFE and its interactions with 4ZnO, 4SiO2, and their hybrids. The HOMO/LUMO orbital distribution of the four PTFE chains is demonstrated in Fig. 3a to be spread across the chain. When PTFE interacted with ZnO and SiO2 on one side, the HOMO/LUMO orbitals were rearranged as in Fig. 3b–f for all interaction cases and localized around the MO atoms. HOMO/LUMO orbital distribution reflects the effect of MO on orbital distribution, which in turn reflects on band gap energy changes. TDM and ΔE were also determined for the different forms of interactions. TDM improved from 0.000 for pure PTFE to 16.235, 1.849, 13.008, 17.432 and 11.583 Debye for PTFE/4ZnO, PTFE/4SiO2, PTFE/4ZnO/4SiO2, PTFE/4SiO2/4ZnO and PTFE/(4ZnO&4SiO2), respectively, as listed in Table 1. Also, the calculated ΔE was reduced from 8.517 eV for pure PTFE to 1.535, 4.302, 0.690, 1.345, and 0.958 eV for PTFE/4ZnO, PTFE/4SiO2, PTFE/4ZnO/4SiO2, PTFE/4SiO2/4ZnO, and PTFE/(4ZnO&4SiO2), respectively. The lowest ΔE was recorded for the PTFE/4ZnO/4SiO2 structure, which is an indication for the most probable and stable structure of interaction that could occur for PTFE with the proposed MOs. It is well known that the increase in the reactivity of chemical systems is correlated with their higher calculated TDM and lower calculated ∆E58.

DFT:B3LYP/LANL2DZ calculated HOMO/LUMO orbital distribution of PTFE and PTFE interaction with 4ZnO, 4 SiO2 and a combination between the two MOs as (a) PTFE, (b) PTFE/4ZnO, (c) PTFE/4SiO2, (d) PTFE/4ZnO/4SiO2, (e) PTFE/4SiO2/4ZnO and (f) PTFE/(4ZnO&4SiO2).

Figure 4 shows the calculated HOMO/LUMO orbital distribution of PTFE interaction with 8 ZnO, 8 SiO2 and a combination of the two MOs. In these cases of interactions, as shown by HOMO/LUMO orbitals rearranged and localized around the MO on one side only, at the top and/or down the PTFE chain (at the top in Fig. 4a,b,d,e but down in the 4c case).The TDM and ΔE were determined for all the studied structures and are listed in Table 2. As shown in the table, TDM improved from 0.000 corresponding to pure PTFE to 32.934, 0.867, 7.844, 10.605 and 6.963 Debye for PTFE/8ZnO, PTFE/8SiO2, PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO, and PTFE/(8ZnO&8SiO2), respectively. While ΔE was observed to decrease from 8.517 eV for pure PTFE to 0.163, 3.253, 0.273, 0.860, and 0.368 eV for PTFE/8ZnO, PTFE/8SiO2, PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO, and PTFE/(8ZnO&8SiO2), respectively. The highest value of TDM and the lowest value of ΔE were reported for PTFE/8ZnO and PTFE/8ZnO/8SiO2 as an indication of the interactions that enhanced the electrical characteristics of the PTFE the most. From all the results, the most enhanced PTFE structure interacted with 4 unit's MOs was that of PTFE/4ZnO/4SiO2. By increasing nanoparticles to 8 units, the most enhanced structure was that for PTFE/8ZnO and PTFE/8ZnO/8SiO2. This means that the electronic behavior of the PTFE polymer is modified with increasing the number of units of MOs.

DFT:B3LYP/LANL2DZ calculated HOMO/LUMO orbital distribution of PTFE interaction with 8ZnO, 8SiO2 and a combination between the two MOs as (a) PTFE/8ZnO, (b) PTFE/8SiO2, (c) PTFE/8ZnO/8SiO2, (d) PTFE/8SiO2/8ZnO and (e) PTFE/(8ZnO&8 SiO2).

Generally, as TDM and ΔE for the interaction of PTFE with MOs are enhanced by increasing the number of MOs units, one can say that as the quantity of nanoparticles increases, the electrical properties of the suggested model structure improve.

The MESP map displays the distributions of the nearby charges, nucleus, and density of electrons at a particular position, represented with color variation as Red > Orange > Yellow > Green > Blue. The colour difference represented as red on the MESP surface refers to the richest charge area, the colour difference represented as blue refers to the poorest charge region, and the colour difference described as green represents zero electrostatic potential. The strongest potential is commonly found in red regions, whereas the weakest potential is found in blue regions59. MESP mapping was calculated for all studied structures at the same level of theory. Figure 5 shows the MESP for PTFE/4ZnO, PTFE/4SiO2, PTFE/4ZnO/4SiO2, PTFE/4SiO2/4ZnO, PTFE/(4ZnO&4SiO2), PTFE/8ZnO, PTFE/8SiO2, PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO and PTFE/(8ZnO&8SiO2), which displayed a map for the interaction status of nucleophilicity.

DFT:B3LYP/LANL2DZ calculated MESP for PTFE and PTFE interaction with ZnO, SiO2 and a combination between the two MOs as (a) PTFE, ZnO and SiO2, (b) PTFE/4ZnO, (c) PTFE/4SiO2, (d) PTFE/4ZnO/4SiO2, (e) PTFE/4SiO2/4ZnO, (f) PTFE/(4ZnO&4 SiO2), (g) PTFE/8ZnO, (h) PTFE/8SiO2, (i) PTFE/8ZnO/8 SiO2, (j) PTFE/8 SiO2/8ZnO and (k) PTFE/(8ZnO&8 SiO2).

Figure 5a shows the MESP map for all considered PTFE, ZnO and SiO2 interactions colored with intermediate colors between orange and yellow, with a plane for the PTFE chain and perpendicular in the case of MOs, which represents less electrostatic repulsion. The MESP results revealed that these structures were exceptionally stable, with the MESP surface appearing in yellow, and there was still no chance of interfering with others, and representing more chemical equilibrium. Figure 5b–k demonstrate the interaction of PTFE with MOs. The red colour spread on the up and down terminals of the polymer, indicating that PTFE's reactivity increased, and MOs enhanced PTFE's active sides. When PTFE interacted with 4SiO2, 4ZnO/4SiO2, 4SiO2/4ZnO, (4ZnO&4SiO2), 8SiO2, 8ZnO/8SiO2, 8SiO2/8ZnO, and (8ZnO&8SiO2), low-potential red regions were localized mainly around the oxygen atom of MO. Whereas when PTFE interacted with 4ZnO and 8ZnO, the red regions were spread across the polymer and increased on the other side of it. These results of MESP are in good agreement with the results of TDM and ΔE. As a result, PTFE's electrical properties improved, and it may now be employed in a variety of fields of applications, such as a corrosion-inhibiting layer for astronaut suits.

Table 3 defines QSAR descriptors trying to describe PTFE relationships with MOs as PTFE/4ZnO, PTFE/4SiO2, PTFE/4ZnO/4SiO2, PTFE/4SiO2/4ZnO, PTFE/(4ZnO&4SiO2), PTFE/8ZnO, PTFE/8SiO2, PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO and PTFE/(8ZnO&8SiO2). Descriptors are summarized as total energy (TE) as Kcal/mol, heat formation (HF) as Kcal/mol, ionization potential (IP) as eV, log P, polarizability as A3, molar refractive (MR) and molecular weight (MR) as au. Firstly, TE is stated to describe the stability of the system, and that reducing TE values takes the structure toward stability60. TE for PTFE was − 17,005.449 kcal/mol. In case of PTFE interacted with 4 units of MOs, TE changed for PTFE/4ZnO, PTFE/4SiO2, PTFE/4ZnO/4SiO2, PTFE/4SiO2/4ZnO and PTFE/(4ZnO&4SiO2) to − 18,409.137, − 20,012.627, − 10,891.274, − 931.899 and − 932.368 kcal/mol respectively. While the TE for PTFE/8ZnO, PTFE/8SiO2, PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO and PTFE/(8ZnO&8SiO2) were changed to − 11,544.339, − 23,034.521, − 25,976.165, − 2414.112, and − 25,973.368 kcal/mol respectively. From the calculated TE, PTFE/8ZnO/8SiO2 found to be the most stable and most probable structure. As well, HF is a significant thermal descriptor that defines the energy produced in the form of heat, as the atoms that exist at potentially infinite distances are linked and form a molecule61, even though HF may be clarified through the difference observed in the enthalpy during the formation of a single mole of a substance from its components. This occurs in its natural and full balance under the atmospheric characteristics of a particular temperature. For PTFE, HF was equal to − 1570.772 kcal/mol. In the case of PTFE interaction with MOs, the calculated HF for PTFE/4ZnO, PTFE/4SiO2, PTFE/4ZnO/4SiO2, PTFE/4SiO2/4ZnO, and PTFE/(4ZnO&4SiO2) were changed to − 1826.101, − 1963.831, − 2457.839, − 2598.762, and − 2266.677 kcal/mol. While in the case of PTFE/8ZnO, PTFE/8SiO2, PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO and PTFE/(8ZnO&8SiO2), HF changed to be equal to − 1871.705, − 2597.869, − 3128.116, − 2372.734, and − 3300.601 kcal/mol, respectively. Accordingly, the most probable structure to be formed, which needed a low energy value for formation, was PTFE/8ZnO/8SiO2 and PTFE/(8ZnO&8SiO2).

Another important descriptor is IP, which is defined as the energy required for the material to be ionized. The IP described by Dewar and Morita using the following equation: IP = a + bq + cq, that a, b is the variational parameter defined as a2 + b2 = 1, charge of an atom in a molecule (q), and electron density of an atom in a molecule (C)62,63. IP was calculated for all PTFE models of interaction. The importance of IP value is that it reflects the reactivity of the studied structures. The IP value is inversely proportional to the compound's reactivity, which means that the reactivity of a certain chemical compound increases as the IP value decreases64. The IP value recorded for PTFE was equal to − 12.980 eV. When PTFE interacted with 4 MOs, the IP changed to − 9.417, − 9.446, − 8.953, − 8.746 and − 10.573 eV for PTFE/4ZnO, PTFE/4SiO2, PTFE/4ZnO/4SiO2, PTFE/4SiO2/4ZnO and PTFE/(4ZnO&4SiO2), respectively. In the case of PTFE interacted with 8 MOs, IP changed to − 9.737, − 11.648, − 8.733, − 8.420 and − 10.392 eV for PTFE/8ZnO, PTFE/8SiO2, PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO, and PTFE/(8ZnO&8SiO2), respectively. According to the obtained data, there was no significant change in IP value. The PTFE/8ZnO/8SiO2 structure had the lowest reactive structure with the surrounding environment and the most thermally enhanced structure. The chemical structure was described by the logarithm of the partition coefficient (log P). Accordingly, the log p value for a compound is the logarithm (base 10) of the partition coefficient (p), which is defined as the ratio of the compounds' organic to aqueous phase concentration as in the equation65

It calculates the solubility of the substance even in an organic solution or in aqueous solvents. Positive log P values define the hydrophobic structures while negative values indicate hydrophilic structures66. All proposed models recorded a positive log P, which is an indication that the structures are hydrophobic and have not affected the surrounding environment. The lowest value of log P reflects a more polar and increase in hydrophobicity of the compound, which confirms the ability to act as a self-cleaning material. Self-cleaning surfaces have sparked significant interest in industrial applications, particularly in the aerospace industry. Self-cleaning super hydrophobic coatings, such as silicones, fluorocarbons, organic materials, and inorganic materials, are sensitive to the accumulation of ice, water, and other contaminants, as well as having a hard, wear-resistant, and phobic coating for an aerodynamic surface to improve de-icing properties via low-pressure plasma vapour deposition technologies. So, enhancing the hydrophobicity of the studying material makes it a promising material to be used as a self-cleaning surface, which is an important application in the aerospace field67,68. The lowest values of log P were recorded for PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO and PTFE/(8ZnO&8SiO2). Consequently, polarizability is a basic property that determines how the chemical formula can be polarized in response to varying forces. Representing the responsiveness of the structural factors affecting the volume, the molar refractor is a descriptor which can specify the overall polarization of the mole69. The greater the molar refractor, the greater the stability of the structures, which were recorded for PTFE/8ZnO/8SiO2, PTFE/8SiO2/8ZnO, and PTFE/(8ZnO&8SiO2).

In summary, the obtained results regarding the most expected interaction between PTFE and MOs, suggested a coating of ZnO with SiO2 on PTFE, particularly PTFE/8ZnO/8SiO2 layer by layer. PTFE/8ZnO/8SiO2 is the most probable way of interaction based on its physical, chemical, and thermal stability. These enhancements serve as a corrosion-inhibiting and self-cleaning layer for astronaut suits owing to its lower response with the surroundings and its higher polarity and hydrophobic nature.

DFT calculations of PTFE chains modified with 4 and 8 units of nano-MOs including ZnO, SiO2 individually and as a hybrid were subjected to enhanced chemical, physical, and thermal stability. The B3LYPL/LANL2DZ was used to evaluate TDM, ΔE and MESP for PTFE polymer and its interaction with suggested MOs model structures. For the studied structures, QSAR descriptors were calculated using MO-G at the PM6 level of theory to investigate electronic properties as well as thermal, physical, and chemical stability. The TDM and ΔE results for the interaction of PTFE with MOs indicated that the electronic properties of PTFE were improved by increasing the number of MOs units. Furthermore, introducing the two MOs layer by layer improves and keeps the PTFE polymer chain stable. Electronic property calculations showed that the most enhanced PTFE structure, as interacted with 4 units of MOs, was that for PTFE/4ZnO/4SiO2. For the interaction of PTFE with 8 units of MOs, PTFE/8ZnO/8SiO2 layer by layer presented the best electronic properties results. The MESP maps also confirmed that the studied structure PTFE/8ZnO/8SiO2 shows enhancement and redistribution of the charge on the polymer surface. The results of MESP are in good agreement with the results of TDM and ΔE. Furthermore, QSAR data indicated that coating PTFE as PTFE/8ZnO/8SiO2 layer by layer improved electronic and thermal stability, and hydrophobicity properties. Correlating the results, it can be concluded that the modified PTFE with ZnO and SiO2 layer by layer has innovative features such as thermal, chemical and physical stability with little sensitivity to surrounding materials, which might be employed as an anti-corrosion and self-cleaning layer for astronaut suits.

The datasets used and/or analyzed during the current study available from the corresponding author on reasonable request.

Shabannia, R. & Abu Hassan, H. Controllable vertically aligned ZnO nanorods on flexible polyethylene naphthalate (PEN) substrate using chemical bath deposition synthesis. Appl. Phys. A 114, 579–584 (2014).

Article ADS CAS Google Scholar

Teng, H. Overview of the development of the fluoropolymer industry. Appl. Sci. 2, 496–512 (2012).

Article Google Scholar

Otitoju, T. A. et al. Advanced ceramic components: Materials, fabrication, and applications. J. Ind. Eng. Chem. 85, 34–65 (2020).

Article Google Scholar

Tony, M. A. Zeolite-based adsorbent from alum sludge residue for textile wastewater treatment. Int. J. Environ. Sci. Technol. 17, 2485–2498 (2010).

Article Google Scholar

Mondal, S. Phase change materials for smart textiles—An overview. Appl. Therm. Eng. 28, 1536–1550 (2008).

Article CAS Google Scholar

Bedia, E. L., Murakami, S., Kitade, T. & Kohjiya, S. Structural development and mechanical properties of polyethylene naphthalate/polyethylene terephthalate blends during uniaxial drawing. Polymer 42, 7299–7305 (2001).

Article CAS Google Scholar

Tony, M. A. Recent frontiers in solar energy storage via nanoparticles enhanced phase change materials: Succinct review on basics, applications, and their environmental aspects. Energy Storage. 3, e238 (2021).

Article CAS Google Scholar

Boda, M. A., Phand, R. V. & Kotali, A. C. Various applications of phase change materials: Thermal energy storing materials. Int. J. Emerg. Res. Manag. 6, 167–171 (2017).

Google Scholar

Iqbal, K. et al. Phase change materials, their synthesis and application in textiles—A review. J. Text. Inst. 110, 625–638 (2019).

Article Google Scholar

Everts, S. Saving space suits: Conservators try to stop the degradation of NASA’s outer space outfits. Chem. Eng. News Arch. 89, 40–41 (2011).

Article Google Scholar

Wassmer, W. The Materials Used in Space Suits. https://www.azom.com/article.aspx?ArticleID=12007 (2017).

Tarquini, S., Antonini, C., Amirfazli, A., Marengo, M. & Palacios, J. Investigation of ice shedding properties of superhydrophobic coatings on helicopter blades. Cold Reg. Sci. Technol. 100, 50–58 (2014).

Article Google Scholar

Agrawal, N., Munjal, S., Ansari, M. Z. & Khare, N. Superhydrophobic palmitic acid modified ZnO nanoparticles. Ceram. Int. 43, 14271–14276 (2017).

Article CAS Google Scholar

Plirdpring, T. et al. Preparation of PTFE-coated SiO2 nanorod films for self-cleaning application. In AIP Conference Proceedings, AIP Publishing LLC, Vol. 2279, 120005 (2020).

Rosales, A., Ortiz-Frade, L., Medina-Ramirez, I. E., Godínez, L. A. & Esquivel, K. Self-cleaning of SiO2–TiO2 coating: Effect of sonochemical synthetic parameters on the morphological, mechanical, and photocatalytic properties of the films. Ultrason. Sonochem. 73, 105483 (2021).

Article CAS PubMed PubMed Central Google Scholar

Lai, D., Kong, G. & Che, C. Synthesis and corrosion behavior of ZnO/SiO2 nanorod-sub microtube superhydrophobic coating on zinc substrate. Surf. Coat. Technol. 315, 509–518 (2017).

Article CAS Google Scholar

Wahyuni, S. & Prasetya, A. T. Enhanced the hydrophobic surface and the photo-activity of TiO2–SiO2 composites. IOP Conf. Ser. Mater. Sci. Eng. 172, 012056 (2017).

Article Google Scholar

Ortega, D. et al. γ-Fe2O3/SiO2 nanocomposites for magneto-optical applications: Nanostructural and magnetic properties. J. Non-Cryst. Solids 352, 2801–2810 (2006).

Article ADS CAS Google Scholar

Salim, M. A. et al. Effect of NH3 on structural and optical properties of SiO2–CuO core–shell nanostructure. Appl. Mech. 466, 813–818 (2014).

Google Scholar

Liang, Y. et al. Super-hydrophobic self-cleaning bead-like SiO2@PTFE nanofiber membranes for waterproof-breathable applications. Appl. Surf. Sci. 442, 54–64 (2018).

Article ADS CAS Google Scholar

Zhu, X., Feng, S., Zhao, S., Membr, J. & Xing, W. Perfluorinated superhydrophobic and oleophobic SiO2@PTFE nanofiber membrane with hierarchical nanostructures for oily fume purification. J. Membr. Sci. 594, 117473 (2020).

Article Google Scholar

Chen, X. M., Liu, K. W. & Yang, Q. F. Study on prepartion and mechanical properties of PTFE/nano-SiO2 composites. J. Chem. Res. Appl. 19, 831 (2007).

CAS Google Scholar

Shen, J. T., Top, M., Pei, Y. T. & De Hosson, J. T. M. Wear and friction performance of PTFE filled epoxy composites with a high concentration of SiO2 particles. Wear 322, 171–180 (2015).

Article Google Scholar

Chao, M. et al. Improved thermal conductivity and mechanical property of PTFE reinforced with Al2O3. NANO 14, 1950064 (2019).

Article Google Scholar

Badry, R. et al. Study of the electronic properties of graphene oxide/(PANi/Teflon). Biointerface Res. Appl. Chem. 10, 6926–6935 (2020).

Article CAS Google Scholar

Hegazy, M. A. et al. Effect of CuO and graphene on PTFE microfibers: Experimental and modeling approaches. Polymers 14, 1069 (2022).

Article CAS PubMed PubMed Central Google Scholar

Ruijin, L., Chao, L., Yuan, Y., Duan, Y. & Zhuang, A. Anti-icing performance of ZnO/SiO2/PTFE sandwich-nanostructure superhydrophobic film on glass prepared via RF magnetron sputtering. Mater. Lett. 206, 109–112 (2017).

Article Google Scholar

Moser, M., Semprimoschnig, C. O. A., Van Eesbeek, M. R. J. & Pippan, R. Surface and bulk degradation of Teflon FEP retrieved from the Hubble space telescope solar arrays. High Perform. Polym. 20, 429–446 (2008).

Article CAS Google Scholar

Dever, J. A. et al. Environmental exposure conditions for Teflon fluorinated ethylene propylene on the Hubble space telescope. High Perform. Polym. 12, 125–139 (2000).

Article CAS Google Scholar

De Groh, K. K. & Martin, M. Thermal contributions to the degradation of ground laboratory and space-irradiated Teflon. J. Spacecr. Rocket. 41, 366–372 (2004).

Article Google Scholar

Minton, T. K. et al. Protecting polymers in space with atomic layer deposition coatings. ACS Appl. Mater. Interfaces 2, 2515–2520 (2010).

Article CAS PubMed Google Scholar

Yeong, Y. H. & Gupta, M. C. Hot embossed micro-textured thin superhydrophobic Teflon FEP sheets for low ice adhesion. Surf. Coat. Technol. 313, 17–23 (2017).

Article CAS Google Scholar

Jucius, D. et al. Hot embossing of PTFE: Towards superhydrophobic surfaces. Appl. Surf. Sci. 257, 2353–2360 (2011).

Article ADS CAS Google Scholar

Jucius, D., Guobienė, A. & Grigaliūnas, V. Surface texturing of polytetrafluoroethylene by hot embossing. Appl. Surf. Sci. 256, 2164–2169 (2010).

Article ADS CAS Google Scholar

Bhagat, S. D. & Gupta, M. C. Superhydrophobic microtextured polycarbonate surfaces. Surf. Coat. Technol. 270, 117–122 (2015).

Article CAS Google Scholar

Abdelsalam, H., Elhaes, H. & Ibrahim, M. A. Tuning electronic properties in graphene quantum dots by chemical functionalization: Density functional theory calculations. Chem. Phys. Lett. 695, 138–148 (2018).

Article ADS CAS Google Scholar

Ezzat, H. et al. Mapping the molecular electrostatic potential of carbon nanotubes. Biointerface Res. Appl. Chem. 8, 3539–3542 (2018).

CAS Google Scholar

Badry, R. et al. Effect of Li, Na, K, Be, Mg and Ca on the electronic properties, geometrical parameters of carboxylic acids. Biointerface Res. Appl. Chem. 8, 3657–3660 (2018).

CAS Google Scholar

Ibrahim, M. Molecular modeling and FTIR study for K, Na, Ca and Mg coordination with organic acid. J. Comput. Theor. Nanosci. 6, 682–685 (2009).

Article CAS Google Scholar

Ibrahim, M. & Mahmoud, A.-A. Computational notes on the reactivity of some functional groups. J. Comput. Theor. Nanosci. 6, 1523–1526 (2009).

Article CAS Google Scholar

Alghunaim, N. S., Omar, A., Elhaes, H. & Ibrahim, M. Effect of ZnO and TiO2 on the reactivity of some polymers. J. Comput. Theor. Nanosci. 14, 2838–2843 (2017).

Article CAS Google Scholar

Abdel-Karim, A., Ismail, S. H., Bayoumy, A. M., Ibrahim, M. & Mohamed, G. G. Antifouling PES/Cu@Fe3O4 mixed matrix membranes: Quantitative structure–activity relationship (QSAR) modeling and wastewater treatment potentiality. Chem. Eng. J. 407, 126501 (2021).

Article CAS Google Scholar

Saleh, N., Mostafa, A. A., Omar, A., Elhaes, H. & Ibrahim, M. Molecular modeling analyses of modified polyvinylalchol/hydroxyapatite composite. J. Comput. Theor. Nanosci. 14, 2298–2301 (2017).

Article CAS Google Scholar

Saleh, N. A., Elfiky, A. A., Ezat, A. A., Elshemey, W. M. & Ibrahim, M. The electronic and QSAR properties of modified telaprevir compounds as HCV NS3 protease inhibitors. J. Comput. Theor. Nanosci. 11, 544–548 (2014).

Article CAS Google Scholar

Cao, X. et al. Preparation of superhydrophobic nanoplate iron oxide surface on a carbon steel for anti-wetting applications. Mater. Des. 211, 110169 (2021).

Article CAS Google Scholar

Milošev, I. et al. Electrochemical, surface-analytical, and computational DFT study of alkaline etched aluminum modified by carboxylic acids for corrosion protection and hydrophobicity. J. Electrochem. Soc. 166, C3131 (2019).

Article Google Scholar

Frisch, M. J. et al. Gaussian 09, Revision C.01 (Gaussian, Inc., 2010).

Google Scholar

Becke, A. D. Density-functional thermochemistry. III. The role of exact exchange. J. Chem. Phys. 98, 5648–5652 (1993).

Article ADS CAS Google Scholar

Lee, C., Yang, W. & Parr, R. G. Development of the Colic–Salvetti correlation-energy formula into a functional of the electron density. Phys. Rev. B 37, 785 (1988).

Article ADS CAS Google Scholar

Vosko, S. H., Wilk, L. & Nusair, M. Accurate spin-dependent electron liquid correlation energies for local spin density calculations: A critical analysis. J. Phys. 58, 1200–1211 (1980).

ADS CAS Google Scholar

Stewart, J. J. P. SCIGRESS, Version 2.9.0 (Fujitsu Limited, 2009).

Google Scholar

Stewart, J. J. P. Optimization of parameters for semiempirical methods V: Modification of NDDO approximations and application to 70 elements. Mol. Mod. 13, 1173–1213 (2007).

Article CAS Google Scholar

Fihri, A., Bovero, E., Al-Shahrani, A., Al-Ghamdi, A. & Alabedi, G. Recent progress in superhydrophobic coatings used for steel protection: A review. Colloids Surf. A Physicochem. Eng. Asp. 520, 378–390 (2017).

Article CAS Google Scholar

Zhang, M., Yu, J. & Wang, J. Liquid-infused surfaces based on ZnO/Co3O4/SiO2 with omniphobicity and durable anti-corrosion properties. Surf. Coat. Technol. 407, 126772 (2021).

Article CAS Google Scholar

Dalawai, S. P. et al. Recent advances in durability of superhydrophobic self-cleaning technology: A critical review. Prog. Org. Coat. 138, 105381 (2020).

Article CAS Google Scholar

Ezzat, H. A., Hegazy, M. A., Nada, N. A. & Ibrahim, M. A. Effect of nano metal oxides on the electronic properties of cellulose, chitosan and sodium alginate. Biointerface Res. Appl. Chem. 9, 4143–4149 (2019).

Article CAS Google Scholar

Taha, T. A., Hendawy, N., El-Rabaie, S., Esmat, A. & El-Mansy, M. K. Effect of NiO NPs doping on the structure and optical properties of PVC polymer films. Polym. Bull. 76, 4769–4784 (2019).

Article CAS Google Scholar

Politzer, P., Laurence, P. R. & Jayasuriya, K. Molecular electrostatic potentials: An effective tool for the elucidation of biochemical phenomena. Environ. Health Perspect. 61, 191–202 (1985).

Article CAS PubMed PubMed Central Google Scholar

Murray, J. S. & Sen, K. (eds) Molecular Electrostatic Potentials: Concepts and Applications (Elsevier, 1996).

Google Scholar

Karelson, M., Lobanov, V. S. & Katritzky, A. R. Quantum-chemical descriptors in QSAR/QSPR studies. Chem. Rev. 96, 1027–1044 (1996).

Article CAS PubMed Google Scholar

Pasha, F. A., Cho, S. J., Beg, Y. & Tripathi, Y. B. Quantum chemical QSAR study of flavones and their radical-scavenging activity. Med. Chem. Res. 16, 408–417 (2007).

Article CAS Google Scholar

Dewar, M. J. & Morita, T. Ground states of conjugated molecules. XII. Improved calculations for compounds containing nitrogen or oxygen. J. Am. Chem. Soc. 91, 796–802 (1969).

Article CAS Google Scholar

Srivastava, H. K., Pasha, F. A. & Singh, P. P. Atomic softness-based QSAR study of testosterone. Int. J. Quantum Chem. 103, 237–245 (2005).

Article ADS CAS Google Scholar

Leo, A., Hansch, C. & Elkins, D. Partition coefficients and their uses. Chem. Rev. 71, 525–616 (1971).

Article CAS Google Scholar

Khan, M. T. H. Recent Trends on QSAR in the Pharmaeutical Perceptions (Bentham Science Publishers, 2012).

Book Google Scholar

Ghose, A. K., Pritchett, A. & Crippen, G. M. Atomic physicochemical parameters for 3-dimensional structure directed quantitative structure–activity relationships 3. Modeling hydrophobic interactions. J. Comput. Chem. 9, 80–90 (1988).

Article CAS Google Scholar

Behera, A. Self-cleaning materials. In Advanced Materials (Springer, 2022).

Wang, F., Xie, T., Junfei, O., Xue, M. & Li, W. Cement based superhydrophobic coating with excellent robustness and solar reflective ability. J. Alloys Compd. 823, 153702 (2020).

Article CAS Google Scholar

Viswanadhan, V. N., Ghose, A. K., Revankar, G. R. & Robins, R. K. Atomic physicochemical parameters for 3 dimensional structure directed quantitative structure–activity relationships 4. Additional parameters for hydrophobic and dispersive interactions and their application for an automated superposition of certain naturally-occurring nucleoside antibiotics. J. Chem. Inform. Comput. Sci. 29, 163–172 (1989).

Article CAS Google Scholar

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Space Lab, Solar and Space Research Department, National Research Institute of Astronomy and Geophysics (NRIAG), Helwan, Cairo, 11421, Egypt

Hend A. Ezzat, Maroof A. Hegazy & Rasha Ghoneim

Nanoscience Laboratory for Environmental and Bio-Medical Applications (NLEBA), Semiconductor Lab., Metallurgical Lab.1., Physics Department, Faculty of Education, Ain Shams University, Roxy, Cairo, 11757, Egypt

Heba Y. Zahran & Ibrahim S. Yahia

Physics Department, Faculty of Women for Arts, Science and Education, Ain Shams University, Cairo, 11757, Egypt

Hanan Elhaes

Molecular Spectroscopy and Modeling Unit, Spectroscopy Department, National Research Centre, 33 El-Bohouth St., Dokki, Giza, 12622, Egypt

Ahmed Refaat & Medhat A. Ibrahim

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Dr. M.A.H. wrote the result and discussion, Dr. R.G. wrote the introduction of the manuscript, Dr. H.A.E. calculated the model structures, submit the paper for publication Prof. I.S.Y. and Prof. H.Y.Z., revised the manuscript, Prof. H.E. contribute to the result and discussion writing, Dr. A.R. revise the paper and participating in the discussion section and Prof. M.A.I. assign the problem, control the overall manuscript then revised it.

Correspondence to Hend A. Ezzat or Medhat A. Ibrahim.

The authors declare no competing interests.

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Ezzat, H.A., Hegazy, M.A., Ghoneim, R. et al. DFT and QSAR studies of PTFE/ZnO/SiO2 nanocomposite. Sci Rep 13, 9696 (2023). https://doi.org/10.1038/s41598-022-19490-0

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Received: 26 June 2022

Accepted: 30 August 2022

Published: 15 June 2023

DOI: https://doi.org/10.1038/s41598-022-19490-0

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