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Oct 24, 2023

Facile fabrication of a novel self

Scientific Reports volume 13,

Scientific Reports volume 13, Article number: 1826 (2023) Cite this article

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To improve flame retardancy of wood, a novel high-water-retention and self-healing polyvinyl alcohol/phytic acid/MXene hydrogel coating was developed through facile one-pot heating and freeze–thaw cycle methods, and then painted on wood surface. The coating exhibit excellent self-healing property and significantly enhanced water-retention property (water content ≥ 90 wt%), due to the increased hydrogen bonds within the coating system with the presence of MXene nanosheets. Compared to pristine wood, the flame retardancy of coated wood is greatly improved, such as passed V0 rating in UL-94 test, increasing time to ignition (TTI, from 32 to 69 s), and decreased heat release rate and total heat release by 41.6% and 36.14%. The cooling effect and large thermal capacity of high-water-retention hydrogel, and physical barrier effects for flammable gas products, heat and oxygen by MXene nanosheets and the compact char layer formed during combustion play key roles in the flame retardancy enhancements of the wood. High thermal stability of MXene nanosheets is another beneficial factor. The detailed flame-retardant and self-healing mechanisms were proposed.

As a green, renewable and lightweight building material, wood has always attracted people's attention1,2,3,4,5. However, its intrinsic high flammability brings about fire hazards which tends to cause huge economic losses and casualties6,7,8,9. Various methods have been developed to improve fire safety of wood, among which, flame-retardant coating is the most striking strategy as it could be easily applicable on wood10,11,12,13. For example, Pedro et al. proposed a fireproof coating based on lignin, tannins and inorganic nanoparticles, which significantly reduced the linear combustion speed by 50% compared with pure wood14. Chu et al. used phosphate ester-polyethylene glycol as fireproof coatings to endow wood with excellent flame retardancy, decreasing the heat release rate (HRR) and total heat release (THR) by 82.4% and 84.3%15. However, the materials used are not green enough and the preparation process of the fireproof coating is rather complicated in these works, which limits its widely application, so an easy-to-process fireproof coating method is required.

As a green and easy-to-preparation material, hydrogel, with high content of water and nontoxic features, has be proved an ideal candidate for flame-retardant coating16,17,18,19,20. High content water means most heat can be absorbed with the evaporation of water. Nontoxic features ensure no toxic volatiles released during decomposition. These two reasons make hydrogel the outstanding flame-retardant coating material. Hung et al. synthesized a green, tough and highly efficient flame-retardant rigid polyurethane foam (RPUF) based on polyacrylic-polydopamine double network hydrogel through UV-curing21. Zhang et al. prepared self-healing, recyclable, and degradable fire-retardant gelatin-based biogel coating via two steps stirring method for green buildings22. In our previous work, we have designed a flame-retardant wood based on polyvinyl alcohol/phytic acid (PVA/PA) hydrogel and explored the effect of PA on the flame retardancy and adhesion in PVA hydrogel. Though the hydrogel coating can endow wood with flame retardancy, self-healing ability and high water-retention need to be realized for the targets of long-time use and better flame retardant ability.

Self-healing property can be realized by physical and chemical approaches including diffusion and flow, shape-memory effects, heterogeneous self-healing systems, covalent-bond reformation and reshuffling, hydrogen-bond interaction, Metal coordination bond action and dynamics of supramolecular chemistry or combinations thereof23,24,25. Among these, hydrogen bond is the easiest method to be realized. As a typical dynamic noncovalent bonds, the import of hydrogen bonds endows hydrogel excellent self-healing property without other source and enhance water-retention capacity of hydrogel26,27,28,29,30. MXene, a 2D inorganic nanomaterial with plenty of functional groups (–OH, –F and so on) terminally31,32,33,34,35, can form many hydrogen bonds with PVA and PA and promote gelation degree of PVA as crosslinking agent to enhance the mechanical properties of hydrogel, which greatly contributes the self-healing and high water-retention properties36. Moreover, the high thermal stability and nanosheet structure of MXene can further enhance the flame retardancy of hydrogel. Lin et al. added MXene into chitosan hydrogel coating applied on RPUF, significantly decreased the HRR and THR by 57.2% and 65.5%37, showing the excellent flame-retardant property of MXene.

Thus, to address that, a flame-retardant wood based on self-healing, high water-retention and flame retardancy PVA/PA/MXene hydrogel coating was prepared via a facile method in this work. The hydrogel coating was obtained via one-pot method and a freeze–thaw cycle and applied on wood by blading. Tensile test was used to detect the mechanical properties of M-hydrogel, and self-healing and water-retention properties were conducted to see the long service life of hydrogel coating. UL-94, open fire tests and cone calorimetry tests (CCT) were performed to explore the flame retardancy of M-hydrogel-coated woods. The M-hydrogel coating endows wood with outstanding flame retardancy. The property enhancement mechanisms have been given in detail.

PVA (Mw∼145,000) was obtained from Aladdin Biochemical Technology Co., Ltd. (Shanghai, China). PA solution (50 wt%, in water) was purchased from Sinopharm Chemical Reagent Co., Ltd. LiF (lithium fluoride) was got from Macklin Biochemical Co., Ltd. (Shanghai, China). HCl (hydrochloric acid, 36.0–38.0 wt%, in water) was provide by Guangzhou Chemical Reagent Factory (Guangzhou China). Ca(OH)2 (calcium hydroxide, 95.0 wt%) was gained from Fuchen Chemical Reagent CO., Ltd. (Tianjin, China). MAX (Ti3Al2C2) powder (~ mesh 400) was supplied by Kai Xi Ceramic Materials Co., Ltd. (Yantai, China). The materials mentioned above were used as received without further purification.

MXene nanosheets were synthesized by the etching and delaminating method. The etching solution was prepared by adding 4 g of LiF to 60 ml HCl and 20 ml DI water, followed by stirring for 30 min. Then 4 g MAX was slowly added into the solution and the stirring time lasted about 24 h. The acidic suspension was washed with DI water until a pH value over 5 via centrifugation at 3500 rpm (5 min per cycle) for about 3 times. Next, the DI water was replaced by alcohol and the suspension was ultrasonicated for 2 h and centrifuged at 10,000 rpm for 10 min. Subsequently, the alcohol was replaced by DI water and ultrasonicated for 20 min. Lastly, the supernatant was collected via centrifugation at 3500 rpm for 5 min and freeze-dried to get the MXene powder.

M-hydrogel and M-hydrogel-coated wood was prepared as the following way: First, DI water was added in 15 ml PA until the weight reached 30 g. Then, PVA and MXene powder was mixed in PA solution with one-pot method and the mixture was stirred for 2 h at 95 °C to get the pre-hydrogel. Finally, M-hydrogel was provided after a freeze–thaw cycle of pre-hydrogel and M-hydrogel-coated wood was obtained with pre-hydrogel coated on wood via blading followed by a freeze–thaw cycle. The component details are listed in Table 1.

The morphology of M-hydrogel-coated wood and uncoated wood was characterized by Scanning Electron Microscope (SEM, Merlin, Germany Zeiss) equipped with energy dispersive X-ray (EDX) system. X-ray Photoelectron Spectroscopy (XPS, Kratos Axis Ulra DLD, Britain) was used to analyze chemical composition of the hydrogel samples. The functional groups of M-hydrogels and MXene were detected by Fourier Transform Infrared Spectrometer (FTIR Spectrometer, VERTEX 70, Bruker German). X-ray diffraction (XRD, D8 ADVANCE, Bruker) was performed to evaluate the crustal structure of MXene. The thermal stability of hydrogel samples was evaluated via thermogravimetric analyzer (TGA, NETZSCH STA 449F3 Germany) with a heating rate of 10 ℃ min-1 under N2 flow of 60 mL min−1 from 30 to 800 °C.

The stress–strain curves were obtained by a universal electronic tensile machine with a tension speed of 300 mm min−1 (Shimadzu, Japan), the size of dumbbell tape hydrogel samples is 30 × 5 × 3 mm3. The samples of stress–strain and adhesion test were performed at least five times. Cross-hatching test was performed to evaluate the adhesion of M-hydrogel coating according to ASTM Designation: D 3359–97.

To evaluate the self-healing property of M-hydrogel, the sample was cut into two pieces and put together with the fracture surface contacted. Some water was sprayed on the crack and then the sample placed in the ambient environment overnight. The water-retention test was performed in room environment with temperature at 25 °C and RH at 60%. The swelling property was examined by immersing samples into DI water and weighting every hour.

UL-94 (CFZ-2 Analytical Instrument company, Jiangning, China) was used to evaluate the flame retardancy of all samples, the size is 125 × 13 × 3 mm3, according to ASTM D 3801. Open fire test was performed for hydrogel-coated wood and uncoated wood by exposing samples (50 × 50 × 3 mm3) directly to propane torch flame (≈ 2000 °C) for 20 s. The length of propane torch was controlled about 5 cm and the angle between the sample and flame was fixed at 90°. The CCT test was performed on a cone calorimeter (FTT, UK) at a heat flux of 50 kW m−2 with samples dimension of 100 × 100 × 3 mm3, according to ISO 5660-1. The distance between the surface of samples and the cone was 60 mm. For heat resistance test, infrared camera was used to record the temperature raising speed of hydrogel-coated and uncoated samples.

MXene was obtained by etching Al layer from MAX and then delaminated via sonicating (Fig. S1). The diffraction peak at 6.8° in XRD result (Fig. S2) and vibration peaks at 3450 cm−1, 1368 cm−1 (–OH), 550 cm−1 (Ti–O) in FTIR result (Fig. S3) demonstrate the successful preparation of MXene38. The synthesis process of M-hydrogel can be divided into two parts: (I) PVA, PA, and MXene were mixed in DI water and the mixture was stirred at 95 °C for 2 h to make pre-hydrogel. (II) Then M-hydrogel could be obtained after the pre-hydrogel frozen in refrigerator overnight and thawed in room temperature. In our previous work, it has been proved PA could enhance mechanical performances of hydrogel by promoting gelation degree39. MXene here could make the same contribution as gelation agent which formed more hydrogen bond. To get the M-hydrogel-coated wood, the pre-hydrogel was applied on the surface of wood via blading and the thickness was controlled at 300 µm, then the wood with coating experienced a freeze–thaw cycle to gain M-hydrogel-coated wood (Fig. 1a). The component in hydrogel (PVA, PA, MXene) can formed hydrogen bonds with cellulose of wood, which insure the adhesion between M-hydrogel and wood. All samples are named Mx-hydrogel, in which x represents the content of MXene. The component details of different samples can be seen in Table 1.

The synthetic process and characterization of M-hydrogel, M-hydrogel-coated and uncoated wood. (a) The illustration of hydrogel and hydrogel-coated wood preparation procedures. (b) FTIR spectra and (c) XPS of M0 and M0.3 hydrogel. SEM image of the surface of (d) pure wood, (e) M0 hydrogel-coated wood, (f) M0.3 hydrogel-coated wood and (g) the cross-section structure of M0.3 hydrogel-coated wood. (h) EDX of M0.3 hydrogel.

The effect on hydrogel with the introduction of MXene was explored by FTIR spectra (Fig. 1b) and XPS (Fig. 1c). It can be seen a distinct characteristic peak in M0 and M0.3 at 962 cm−1 and 983 cm−1, which should be assigned to vibration peak of PA40. Compared with M0, there are new adsorption peaks appeared at 786 cm−1 and 668 cm−1 in M0.3. These two characteristic peaks may be due to deformation vibrations when the hydroxyl groups (–OH) contained in PVA and PA interact with the functional group of MXene under the formation of hydrogen bond41. XPS shows that except for P (135 eV), C (284 eV), O (532 eV), the characteristic elements of Ti (450 eV) and F (686 eV) arise in M0.3 sample resulting from MXene component. Also, as is shown in Fig. 1h, the results of EDX of M0.3 hydrogel confirms that the ingredients are mixed evenly. All tests above prove the M-hydrogel is synthesized successfully. SEM images reveal the morphology of M-hydrogel-coated and uncoated wood. The surface of pure wood is rough and many strip cracks could be seen because of the plenty of wood fibers (Fig. 1d). It is noting that appearance of M-hydrogel-coated wood is smooth, and all cracks are sealed which would make a positive contribution to flame retardancy (Fig. 1e,f). The cross-section image in Fig. 1g shows the coating combined with wood closely at the thickness of 300 µm. It can not only ensure the flame retardancy, but also do no harm to the mechanical property of wood.

The mechanical properties of M-hydrogel were evaluated by tensile tests. As is shown in Fig. 2a, with the higher content of MXene, the stress and strain of M-hydrogel increase significantly. The stress and strain of M0, M0.1, M0.2, M0.3 hydrogel could reach 0.076, 0.084, 0.105, 0.124 MPa and 150%, 220%, 280%, 310%, respectively. The enhancement in stress–strain curves of M-hydrogel can be ascribed to more hydrogen bonds and stronger polymer chain entanglement with the importation of MXene42. The functional groups in MXene can form hydrogen bonds with PVA and PA, resulting in more hydrogen bonds in M-hydrogel. Besides, MXene can act as gelation agent in M-hydrogel to heighten the entanglement of PVA chains. The two reasons are the main factors contributing to strengthen of M-hydrogel. The tensile elastic modulus and yield stress of M0, M0.1, M0.2, M0.3 hydrogel are 0.048, 0.047, 0.038, 0.036 MPa and 0.017, 0.018, 0.020, 0.023 MPa (Fig. 2b). Lower tensile elastic and higher tensile yield stress modulus means less stiffness of M-hydrogel and it can endure bigger deformation, which are coherent with the results of stress–strain curves. Furthermore, the M0.3 hydrogel could be twisted, knotted, and resist the weight of 500 g which reflect the excellent mechanical properties of M0.3 hydrogel (Figs. S4, S5). As a flame-retardant coating, adhesion is another important aspect to think over. We performed cross-hatching test to investigate adhesion of M0.3 hydrogel coating on wood. From Fig. 2c, there is evenly none coating falling off after the tape test. The result exhibits wonderful adhesion of M0.3 hydrogel coating on wood.

The mechanical properties, self-healing, water-retention, and swelling ratio of M-hydrogel. (a) The stress–strain curves of M-hydrogel and the physical photo is inserted. (b) Tensile elastic modulus and tensile yield stress of M-hydrogel. (c) Cross-hatching test of M0.3 hydrogel-coated wood. (d) The schematic illustration of self-healing principle of M-hydrogel. (e) Water retention of M-hydrogel, W0 and W represent the original and current weight of hydrogels. (f) Swelling ratio of M-hydrogel and (g) the photographs of M-hydrogel under different immersing time.

It should be considered that when crack appears, it would have adverse effect on the flame retardancy as dense coating is essential for fireproofing, so self-healing is important. To explore the self-healing principle of M-hydrogel, we cut a cuboid M0.3 hydrogel into two blocks, then the fracture section was contacted closely, and some water was sprayed. Finally, the two blocks of hydrogel self-healed into a whole hydrogel overnight in ambient environment (Fig. S6). The schematic illustration of M-hydrogel self-healing principle is demonstrated in Fig. 2d. When the hydrogel was cut into two pieces, the hydrogen bonds among hydrogel were destroyed. However, as dynamic and reversible non-covalent bonds, hydrogen bonds could be rebuilt when the fracture section contacted with water spraying, which ensure the self-healing property of M-hydrogel43.

As a fireproof coating, water is crucial for M-hydrogel in flame retardancy. Conventional hydrogels lost its water easily due to evaporation44. In our previous work, we have proved that PV could improve the water retention of PVA hydrogel significantly by bring more hydrogen bonds between PVA and PA45. Here MXene was added under the same reason. It is gratifying that all M-hydrogel samples holds it weight over 90% after 15 days under the occasion of 25 °C and relative humidity of 60% (Fig. 2e). The comparison of water maintenance of this work with other hydrogel coating was listed (Table S1) to verify the excellent water capacity of PVA/PA/MXene hydrogel. Further experiments were conducted to investigate the water adsorption capacity of M-hydrogels. The results in Fig. 2f exhibit that with the increasing content of MXene, water capacity of M-hydrogel also increases. The swelling ratio of M0, M0.1, M0.2, M0.3 hydrogel can reach 26.16%, 28.39%, 29.16% and 31.08%, respectively. This phenomenon should be assigned to more hydrogen bonds interaction owing to more MXene and the functional groups in MXene (–F, –OH) endows the M0.3 hydrogel stronger water adsorption capacity46. The photographs of M0 and M0.3 hydrogel under different water adsorption are listed in Fig. 2g. When immersed in water for the same time, M0.3 hydrogel is bigger than M0 hydrogel. Other M-hydrogel water capacity image are shown in Fig. S7. All M-hydrogels immersed in water exhibit the same phenomenon, which is coincident with results in Fig. 2f.

UL-94 tests performed to evaluate the flame-retardant rating of M-hydrogel-coated and uncoated wood and the t1, t2 is listed in Table 2. During the test, pure wood (Fig. 3a) was ignited after the first 10 s burning and cannot self-distinguished until burn out, showing its intrinsic flammability and fire hazard and the rating should be ranked to V2. Obviously, all M-hydrogel-coated wood did not be ignited even after the second burn for 10 s as shown in Fig. 3b–e, which demonstrate the excellent flame retardancy of M-hydrogel coatings. The photos of M-hydrogel-coated and uncoated wood after UL-94 test can be seen in Fig. S8. The related data of all M-hydrogel-coated wood in t1 and t2 are 0 s listed in Table 2, stating all M-hydrogel-coated wood can reach V0 rating.

Combustion behavior of M-hydrogel-coated and uncoated samples. The photographs of UL-94 test of (a) wood, (b) M0, (c) M01, (d) M0.2 and (e) M0.3 hydrogel-coated wood. (f) The image of open fire test process. (g) The photos of pure wood and M-hydrogel-coated wood in open fire test. (h) The SEM images of char layer of (h) pure wood, (i) M0, and (j) M0.3 hydrogel-coated wood after open fire test.

Open fire tests were conducted to see the effect of fireproof coating intuitively. The samples fixed in clamp were controlled at 5 cm distance from the flame gun (Fig. 3f). In Fig. 3g, after 20 s ignition, there is more intense flame on the surface of pure wood compared with M-hydrogel-coated wood (M0.1 and M0.2 hydrogel -coated samples can be seen in Fig. S9). It is because when the temperature reaches a certain point, the internal moisture of wood evaporates completely, then the surface material begins to gradually decompose carbonized, producing combustible gases and forming a stable flame combustion. But the M-hydrogel coatings contain more water which could effectively delay the process and no damage can be seen from M0 and M0.3 hydrogel-coated wood. Also, the char layer formed by hydrogel coatings are denser than pure wood at 40 s. The SEM images are applied to further evaluate the structure of char layer. It is clearly that the char layer of pure wood (Fig. 3h) is loose and demonstrate fibrous dispersion showing poor heat resistance ability. Significantly, the char layer of M0 hydrogel coating (Fig. 3i) is dense and smooth with sheet layer structure. Though cracks still can be seen, it shows a better heat and O2 resistance capability. As for M0.3 hydrogel-coated wood, the char layer is the densest and expansion structure appeared, exhibiting the best heat and O2 resistance effect in open tests and best fireproof function (Fig. 3j). This is because lamellar structure of MXene can act as good physical barrier and the char layer is faveolate which shows the best heat resistance capacity among the samples. Moreover, the M-hydrogel fireproof coating could be extended application. When used on RPUF, it exhibits excellent flame retardancy, too (Fig. S10).

CCT test was performed to further evaluate the fire safety of M-hydrogel coating and the main parameters are listed in Table 2. According to the results, the time to ignition (TTI) of pure wood is 32 s while M-hydrogel coated wood of M0, M0.1, M0.2 and M0.3 are prolonged to 64 s, 74 s, 66 s and 69 s, respectively (Fig. 4c). The results show the function of water contained in hydrogel coatings to limit the fire spread from surface to inside of wood. It is further proofed in results of heat release rate (HRR) and total heat release (THR) in Fig. 4a,b. There are two peaks in HRR curves of pure wood. When the temperature reaches about 250 °C, the combustion gases of H2 and CH4 generated along with carbonization of wood surface. These gases are ignited at ignition temperature under heat resource and then fire appears inside resulting in the first peak. When the fire spread to surface of the char layer, no combustion gases decomposed from wood and fuel is applied from volatile matter inside wood. At this circumstance, burning flame changes into flameless combustion and the second peak appears. Compared with pure wood, there are also two peaks in HRR curves of M0 hydrogel-coated wood, but the appearance time of the two peaks is later than pure wood. It is due to M0 hydrogel coating could insulate O2 from contact with wood under heating condition. It is worth noting that there is only one peak appears in HRR curves of M0.1, M0.2 and M0.3 hydrogel-coated wood. This may be attributed to the denser char layer formed with introduction of MXene which significantly increases the heat resistance ability of hydrogel coating, resulting in the burning flame and flameless combustion phenomenon occurs at the same time. Besides, the appearance time of peak heat release rate (pHRR) and total heat release (THR) of pure wood and M0, M0.1, M0.2 and M0.3 hydrogel-coated wood are 70, 75, 90, 95, 95 s and 23.96, 16.41, 14.65, 14.72, 15.30 MJ/m2, respectively. The results exhibit better fireproof ability of hydrogel coating with the introduction of MXene. It worth noting that with the increase content of MXene, there are slight increase in HRR and THR. It maybe because more MXene bring more C element which results in the increase in HRR and THR. But the little increase can be ignored as it still lower than M0 hydrogel-coated wood in HRR and THR. To compare the flame-retardancy performance of this work with other work, we listed a table to show the excellent fireproof capacity of the M-hydrogel coating in the field of flame-retardant wood (Table S2).

Thermal stability and fire-retardant mechanism of M-hydrogel coatings. CCT results of M-hydrogel-coated and uncoated wood. (a) HRR, (b) THR, (c) TTI. (d) Heat- transfer results of pure wood, M0 and M0.3 hydrogel-coated wood. (e, f) TG and DTG curves of M0 and M0.3 hydrogels. (g) The schematic illustration of flame-retardant mechanisms of M-hydrogel coatings.

As a critical property, the heat resistance ability of M-hydrogel is evaluated by infrared camera. The M-hydrogel-coated side of the samples is exposed to an open fire, while the temperature of back-side is recorded by an infrared camera and the results can be seen in Fig. 4d. For pure wood, the temperature of back-side rises to 150 ℃ quickly while M0 and M0.3 hydrogel-coated wood show an excellent heat resistance capacitation. At about 100 °C, the temperature rising of M0 and M0.3 hydrogel-coated wood appears a significant postpone. This is because the water evaporation in hydrogel coating brings most heat. In addition, the temperature of M0.3 hydrogel-coated wood stays under 100 °C from 100 to 175 s, which can be assigned to the denser char layer formed by M0.3 hydrogel coating resisting more heat.

Thermogravimetric analysis (TGA) and differential thermal gravity (DTG) results are supplied to explore the thermal property in Fig. 4e,f and the related data are listed in Table 3. T10% appears at 130.56 and 125.86 °C of M0 and M0.3 hydrogels. The decomposition process of M0 and M0.3 hydrogel can be divided into 5 parts. TI and TII at 130.12, 162.25 and 130.68, 158.33 °C of M0 and M0.3 hydrogel can be ascribed to the dehydration of hydroxyl of PVA and PA. TIII and TIV at 310.28, 435.42 and 258.35, 327.06 °C of M0 and M0.3 hydrogel can be assigned to the decomposition of side chain and main chain of PVA. TV arises at 644.41 and 678.45 °C of M0 and M0.3 hydrogel can be explained as the decomposition process of phytate groups in PA47. When temperature reaches 800 °C, the mass left of M0 and M0.3 hydrogel is 26.96% and 30.58%, which demonstrates the enhancement of thermal stability in hydrogel with the introduction of MXene.

Based on all results of the experiments above, the flame-retardant mechanisms can be attributed as following (Fig. 4g): (I) Cooling effect due to the large heat capacity and enthalpy of water evaporation. (II) PA as a phosphorus-based flame retardant, promotes the dehydration of wood into carbon and prolong the red-hot combustion process of wood. (III) Denser and harder char layer due to the introduction of MXene, which insulates most O2 and heat spread.

A PVA/PA/MXene hydrogel fireproof coating was developed and applied on wood via facile one-pot heating and freeze–thaw cycle method. The coating demonstrates excellent self-healing property (without other source) and high water-retention (water content ≥ 90%) due to the increased hydrogen bonds with the introduction of MXene. Besides, the PVA/PA/MXene hydrogel-coated wood shows improved flame retardancy such as reached V0 rating in UL-94 test, increasing TTI (from 32 to 69 s), and decreased HRR and THR by 41.6% and 31.64% in CCT tests, respectively. Multiple flame-retardant mechanisms of (I): cooling effect and large thermal capacity of high content of water within hydrogel; (II) the promotion of char layer formation due to PA (phosphorus-based flame retardant); (III) the compact char layer formed during combustion due to MXene enhances the physical barrier effect for flammable gas, heat and oxygen, the flame-retardant mechanisms above ensures the fire safety of wood. Furthermore, the fireproof coating could be applied on other engineering materials (RPUF), showing its wide application in structure materials with the requirement of fire safety.

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

Östman, B. National fire regulations for the use of wood in buildings–worldwide review 2020. Wood Mat. Sci. Eng. 17, 2–5 (2021).

Article Google Scholar

Sun, X., He, M. & Li, Z. Novel engineered wood and bamboo composites for structural applications: State-of-art of manufacturing technology and mechanical performance evaluation. Constr. Build. Mater. 249, 118751 (2020).

Article Google Scholar

Lazarevic, D., Kautto, P. & Antikainen, R. Finland's wood-frame multi-storey construction innovation system: Analysing motors of creative destruction. For. Policy Econ. 110, 101861 (2020).

Article Google Scholar

Cabral, M. R. & Blanchet, P. A state of the art of the overall energy efficiency of wood buildings-an overview and future possibilities. Materials (Basel) 14, 1848 (2021).

Article ADS CAS Google Scholar

Churkina, G. et al. Buildings as a global carbon sink. Nat. Sustain. 3, 269–276 (2020).

Article Google Scholar

Sesseng, C., Reitan, N. K., Storesund, K., Mikalsen, R. F. & Hagen, B. C. Effect of particle granularity on smoldering fire in wood chips made from wood waste: An experimental study. Fire Mater. 44, 540–556 (2020).

Article CAS Google Scholar

Boran Torun, S., Donmez Cavdar, A. & Ozdemir, T. The synergistic effect of intumescent coating containing titanium dioxide and antimony trioxide onto spruce and alder wood species. J. Build. Eng. 31, 101407 (2020).

Article Google Scholar

Lin, C.-F. et al. Leach-resistant fire-retardant treated furfurylated wood by incorporating guanyl-urea phosphate. Wood Mat. Sci. Eng. 16, 429–431 (2021).

Article CAS Google Scholar

Soula, M., Samyn, F., Duquesne, S. & Landry, V. Innovative polyelectrolyte treatment to flame-retard wood. Polymers (Basel) 13, 2884 (2021).

Article CAS Google Scholar

Hu, X. & Sun, Z. Nano CaAlCO3-layered double hydroxide-doped intumescent fire-retardant coating for mitigating wood fire hazards. J. Build. Eng. 44, 102987 (2021).

Article Google Scholar

Zhou, L. & Fu, Y. Flame-retardant wood composites based on immobilizing with chitosan/sodium phytate/nano-TiO2–ZnO coatings via layer-by-layer self-assembly. Coatings 10, 296 (2020).

Article CAS Google Scholar

Ma, G., Wang, X., Cai, W., Ma, C., Wang, X., Zhu, Y., Kan, Y., Xing, W., Hu, Y., Preparation and study on nitrogen- and phosphorus- containing fire resistant coatings for wood by UV-cured methods. Front. Mater. 9 (2022).

Soula, M. et al. Effect of a thin organosilicon layer prepared by atmospheric pressure plasma on wood flame retardancy. Plasma Process. Polym. 19, 2200051 (2022).

Article CAS Google Scholar

de Hoyos-Martínez, P. L., Issaoui, H., Herrera, R., Labidi, J. & Charrier-El Bouhtoury, F. Wood fireproofing coatings based on biobased phenolic resins. ACS Sustain. Chem. Eng. 9, 1729–1740 (2021).

Article Google Scholar

Chu, T., Gao, Y., Yi, L., Fan, C., Yan, L., Ding, C., Liu, C., Huang, Q., Wang, Z., Highly fire-retardant optical wood enabled by transparent fireproof coatings. Adv. Compos. Hybrid Mater. (2022).

Jiao, Q. et al. Zwitterionic hydrogel with high transparency, ultrastretchability, and remarkable freezing resistance for wearable strain sensors. Biomacromol 22, 1220–1230 (2021).

Article CAS Google Scholar

Qin, Z. et al. Carbon nanotubes/hydrophobically associated hydrogels as ultrastretchable, highly sensitive, stable strain, and pressure sensors. ACS Appl. Mater. Interfaces 12, 4944–4953 (2020).

Article CAS Google Scholar

Han, S. et al. Dual conductive network hydrogel for a highly conductive, self-healing, anti-freezing, and non-drying strain sensor. ACS Appl. Polym. Mater. 2, 996–1005 (2020).

Article CAS Google Scholar

Li, S., Cong, Y. & Fu, J. Tissue adhesive hydrogel bioelectronics. J. Mater. Chem. B 9, 4423–4443 (2021).

Article CAS Google Scholar

Liu, J., Qu, S., Suo, Z. & Yang, W. Functional hydrogel coatings. Natl. Sci. Rev. 8, nwaa254 (2021).

Article CAS Google Scholar

Huang, Y. et al. Green, tough and highly efficient flame-retardant rigid polyurethane foam enabled by double network hydrogel coatings. Soft Matter 17, 10555–10565 (2021).

Article ADS CAS Google Scholar

Zhang, L., Huang, Y., Sun, P., Hai, Y. & Jiang, S. A self-healing, recyclable, and degradable fire-retardant gelatin-based biogel coating for green buildings. Soft Matter 17, 5231–5239 (2021).

Article ADS CAS Google Scholar

Li, C. H. & Zuo, J. L. Self-healing polymers based on coordination bonds. Adv. Mater. 32, e1903762 (2020).

Google Scholar

Guo, H., Han, Y., Zhao, W., Yang, J. & Zhang, L. Universally autonomous self-healing elastomer with high stretchability. Nat. Commun. 11, 2037 (2020).

Article ADS CAS Google Scholar

Wang, S. & Urban, M. W. Self-healing polymers. Nat. Rev. Mater. 5, 562–583 (2020).

Article ADS CAS Google Scholar

Wen, N. et al. Recent advancements in self-healing materials: Mechanicals, performances and features. React. Funct. Polym. 168, 105041 (2021).

Article CAS Google Scholar

Chen, L., Shao, J., Yu, Q. & Wang, S. High-strength, anti-fatigue, stretchable self-healing polyvinyl alcohol hydrogel based on borate bonds and hydrogen bonds. J. Dispers. Sci. Technol. 43, 690–703 (2020).

Article Google Scholar

Ou, Y. & Tian, M. Advances in multifunctional chitosan-based self-healing hydrogels for biomedical applications. J. Mater. Chem. B 9, 7955–7971 (2021).

Article CAS Google Scholar

Zhang, A. et al. Effect of mechanical properties on the self-healing behavior of waterborne polyurethane coatings. J. Appl. Polym. Sci. 139, 52364 (2022).

Article CAS Google Scholar

Zhang, W. et al. Recent achievements in self-healing materials based on ionic liquids: a review. J. Mater. Sci. 55, 13543–13558 (2020).

Article ADS CAS Google Scholar

Gao, L. et al. MXene/polymer membranes: Synthesis, properties, and emerging applications. Chem. Mater. 32, 1703–1747 (2020).

Article CAS Google Scholar

Li, K. et al. 3D MXene architectures for efficient energy storage and conversion. Adv. Funct. Mater. 30, 2000842 (2020).

Article CAS Google Scholar

Liu, A. et al. Recent progress in MXene-based materials: Potential high-performance electrocatalysts. Adv. Funct. Mater. 30, 2003437 (2020).

Article CAS Google Scholar

Zhong, Q., Li, Y. & Zhang, G. Two-dimensional MXene-based and MXene-derived photocatalysts: Recent developments and perspectives. Chem. Eng. J. 409, 128099 (2021).

Article CAS Google Scholar

Shekhirev, M., Shuck, C. E., Sarycheva, A. & Gogotsi, Y. Characterization of MXenes at every step, from their precursors to single flakes and assembled films. Prog. Mater. Sci. 120, 100757 (2021).

Article CAS Google Scholar

Feng, Y. et al. Muscle-inspired mxene conductive hydrogels with anisotropy and low-temperature tolerance for wearable flexible sensors and arrays. Adv. Funct. Mater. 31, 2105264 (2021).

Article CAS Google Scholar

Lin, B. et al. MXene/chitosan nanocoating for flexible polyurethane foam towards remarkable fire hazards reductions. J. Hazard Mater. 381, 120952 (2020).

Article CAS Google Scholar

Fan, X., Ding, Y., Liu, Y., Liang, J. & Chen, Y. Plasmonic Ti3C2Tx MXene enables highly efficient photothermal conversion for healable and transparent wearable device. ACS Nano 13, 8124–8134 (2019).

Article CAS Google Scholar

Zhang, S. et al. One-step preparation of a highly stretchable, conductive, and transparent poly(vinyl alcohol)-phytic acid hydrogel for casual writing circuits. ACS Appl. Mater. Interfaces 11, 32441–32448 (2019).

Article CAS Google Scholar

Chen, A., Zhu, L. & Arai, Y. Solution NMR investigation of phytic acid adsorption mechanisms at the calcite-water interface. Sci. Total Environ. 840, 156700 (2022).

Article ADS CAS Google Scholar

Huang, X., Wang, J. & Wang, L. Esterification modification and characterization of polyvinyl alcohol anion exchange membrane for direct methanol fuel cell. J. Polym. Res. 29, 1–16 (2022).

Article CAS Google Scholar

Guo, C. et al. Boosted pi-Li cation effect in the stabilized small organic molecule electrode via hydrogen bonding with MXene. ACS Appl. Mater. Interfaces 14, 29974–29985 (2022).

Article CAS Google Scholar

Luo, X. et al. A flexible multifunctional triboelectric nanogenerator based on MXene/PVA hydrogel. Adv. Funct. Mater. 31, 2104928 (2021).

Article CAS Google Scholar

Mredha, M. T. I., Le, H. H., Cui, J. & Jeon, I. Double-hydrophobic-coating through quenching for hydrogels with strong resistance to both drying and swelling. Adv. Sci. (Weinh) 7, 1903145 (2020).

Article CAS Google Scholar

Zhao, X. et al. Influence of phytic acid on flame retardancy and adhesion performance enhancement of poly (vinyl alcohol) hydrogel coating to wood substrate. Prog. Org. Coat. 161, 106453 (2021).

Article CAS Google Scholar

Zhang, P., Yang, X. J., Li, P., Zhao, Y. & Niu, Q. J. Fabrication of novel MXene (Ti3C2)/polyacrylamide nanocomposite hydrogels with enhanced mechanical and drug release properties. Soft Matter 16, 162–169 (2020).

Article ADS CAS Google Scholar

Huang, Y. et al. Biodegradable microspheres made of conductive polyorganophosphazene showing antioxidant capacity for improved bone regeneration. Chem. Eng. J. 397, 125352 (2020).

Article CAS Google Scholar

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This work was supported by the National Natural Science Foundation of China (22175066), the Natural Science Foundation of Guangdong Province (Grant No. 2019A1515011044), the Opening Fund of State Key Laboratory of Fire Science (SKLFS; Grant No. HZ2021-KF14), the Guangdong-Guangxi joint Fund (Grant No. 2021A1515410003), and the Scientific Research Startup Fund for Shenzhen High-Caliber Personnel of SZPT (No. 6022310043K).

These authors contributed equally: Xiaojiong Zhao and Min Tian.

Institute of Safety Science and Engineering, School of Mechanical and Automotive Engineering, South China University of Technology, Wushan Road 381, Guangzhou, 510641, People's Republic of China

Xiaojiong Zhao, Min Tian & Saihua Jiang

Guangdong Provincial Key Laboratory of Technique and Equipment for Macromolecular Advanced Manufacturing, South China University of Technology, Guangzhou, 510641, People's Republic of China

Xiaojiong Zhao & Saihua Jiang

State Key Laboratory of Fire Science, University of Science and Technology of China, Jinzhai Road 96, Hefei, 230026, People's Republic of China

Saihua Jiang

Research Institute of New Energy Vehicle Technology, Shenzhen Polytechnic, Shenzhen, 518055, Guangdong, People's Republic of China

Ruichao Wei

School of Automobile and Transportation, Shenzhen Polytechnic, Shenzhen, 518055, Guangdong, People's Republic of China

Ruichao Wei

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X.Z.: Conceptualization, Methodology, Investigation, Writing—original draft, Writing—review and editing.M.T.: Conceptualization, Methodology, Investigation, Writing—original draft, Writing—review and editing.S.J.: Supervision, Funding acquisition, Resources, Writing—review and editing.R.W.: Supervision, Funding acquisition, Resources.All authors reviewed the manuscript.

Correspondence to Ruichao Wei or Saihua Jiang.

The authors declare no competing interests.

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Zhao, X., Tian, M., Wei, R. et al. Facile fabrication of a novel self-healing and flame-retardant hydrogel/MXene coating for wood. Sci Rep 13, 1826 (2023). https://doi.org/10.1038/s41598-023-28228-5

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Received: 03 November 2022

Accepted: 16 January 2023

Published: 01 February 2023

DOI: https://doi.org/10.1038/s41598-023-28228-5

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