Harnessing MOF-derived homogeneous hierarchical nickel phyllosilicate for epoxy composites: breaking the dilemma between flame retardancy and mechanical and tribological properties via co-deploying polyphosphazene and DOPO

Jinian Yang; Jie Dong; Bingyi Li; Weilong Chen; Hanxin Yang; Dehan Chen; Shibin Nie

doi:10.1007/s11705-026-2662-6

ENG. Chem. Eng. ›› 2026, Vol. 20 ›› Issue (6) :41 DOI: 10.1007/s11705-026-2662-6

RESEARCH ARTICLE

Harnessing MOF-derived homogeneous hierarchical nickel phyllosilicate for epoxy composites: breaking the dilemma between flame retardancy and mechanical and tribological properties via co-deploying polyphosphazene and DOPO

Author information +

History +

PDF (9838KB)

Abstract

Epoxy resin (EP) is a widely utilized thermosetting resin in structural and functional materials; however, achieving a delicate balance between flame retardancy and stress-sensitive properties remains a significant challenge. Herein, a multifunctional flame-retardant strategy was rationally designed by incorporating polyphosphazene-decorated hierarchical nickel phyllosilicate (NiPS@PZN) as a reinforcing and wear-resistant filler while 9,10-dihydro-9-oxa-10-phospaphenanthrene-10-oxide (DOPO) as a flame-retardant synergist. Results demonstrate that the synergistic incorporation of NiPS@PZN and DOPO (1:1 mass ratio) at a total loading of 6% endows the EP composites with a UL-94 V-0 rating and elevates the limited oxygen index to 26.6%. This hybrid system also suppresses the total heat release, total smoke production, and carbon dioxide production by 10.4%, 23.2%, and 26.8%, respectively. The formation of a continuous and dense char layer confirms a dual-phase flame-retardant mechanism involving both condensed and gaseous phases. Moreover, the synergistic effect of NiPS@PZN and DOPO facilitates the concurrent optimization of mechanical and tribological properties, remarkably increasing the tensile strength to 103.5 MPa and achieving a minimum wear rate of 1.78 × 10⁻⁵ mm³·N^–1·m^–1. This study offers a viable pathway for the rational design of multifunctional additives and the fabrication of high-performance composites.

Graphical abstract

Keywords

homogeneous hierarchical nickel phyllosilicate / co-deployment effect / flame retardancy / mechanical property / wear resistance

Cite this article

Download citation ▾

Jinian Yang, Jie Dong, Bingyi Li, Weilong Chen, Hanxin Yang, Dehan Chen, Shibin Nie. Harnessing MOF-derived homogeneous hierarchical nickel phyllosilicate for epoxy composites: breaking the dilemma between flame retardancy and mechanical and tribological properties via co-deploying polyphosphazene and DOPO. ENG. Chem. Eng., 2026, 20(6): 41 DOI:10.1007/s11705-026-2662-6

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Sasidharan S , Anand A . Epoxy-based hybrid structural composites with nanofillers: a review. Industrial & Engineering Chemistry Research, 2020, 59(28): 12617–12631

[2]	Huo S , Song P , Yu B , Ran S , Chevali V S , Liu L , Fang Z , Wang H . Phosphorus-containing flame retardant epoxy thermosets: recent advances and future perspectives. Progress in Polymer Science, 2021, 114: 101366

[3]	Chang L , Zhang Z . Tribological properties of epoxy nanocomposites. Part II: a combinative effect of short carbon fibre with nano-TiO₂. Wear, 2006, 260(7): 869–878

[4]	Lv Q , Huang J Q , Chen M J , Zhao J , Tan Y , Chen L , Wang Y Z . An effective flame retardant and smoke suppression oligomer for epoxy resin. Industrial & Engineering Chemistry Research, 2013, 52(27): 9397–9404

[5]	Kandola B K , Magnoni F , Ebdon J R . Flame retardants for epoxy resins: application-related challenges and solutions. Journal of Vinyl and Additive Technology, 2022, 28(1): 17–49

[6]	Zhou C , Wang X , Wang J , Pan Z , Zhou H . Epoxy resin modified with chitosan derivatives and DOPO: improved flame retardancy, mechanical properties, and transparency. Polymer Degradation & Stability, 2022, 199: 109931

[7]	Mathews L D , Capricho J C , Peerzada M , Salim N V , Parameswaranpillai J , Hameed N . Recent progress and multifunctional applications of fire-retardant epoxy resins. Materials Today Communications, 2022, 33: 104702

[8]	Zaghloul M M Y , Zaghloul M M Y , Fuseini M . Recent progress in epoxy nanocomposites: corrosion, structural, flame retardancy, and applications—a comprehensive review. Polymers for Advanced Technologies, 2023, 34(11): 3438–3472

[9]	Rao W , Tao J , Yang F , Wu T , Yu C , Zhao H B . Growth of copper organophosphate nanosheets on graphene oxide to improve fire safety and mechanical strength of epoxy resins. Chemosphere, 2023, 311: 137047

[10]	Gong K , Yin L , Shi C , Qian X , Zhou K . Dual char-forming strategy driven MXene-based fire-proofing epoxy resin coupled with good toughness. Journal of Colloid and Interface Science, 2023, 640: 434–444

[11]	Zou B , Qiu S , Qian Z , Wang J , Xing W . Phosphorus/nitrogen-codoped molybdenum disulfide/cobalt borate nanostructures for flame-retardant and tribological applications. ACS Applied Nano Materials, 2021, 4(10): 10495–10504

[12]

Xu Y , Dai G , Nie S , Yang J , Liu S , Zhang H , Dong X . Nickel-based metal-organic framework-derived whisker-shaped nickel phyllosilicate toward efficiently enhanced mechanical, flammable, and tribological properties of epoxy nanocomposites. Frontiers of Chemical Science and Engineering, 2022, 16(10): 1493–1504

[13]	Yang J , Feng X , Nie S , Xu Y , Li Z . Self-sacrificial templating synthesis of flower-like nickel phyllosilicates and its application as high-performance reinforcements in epoxy nanocomposites. Frontiers of Chemical Science and Engineering, 2022, 16(4): 484–497

[14]	Dong J , Yang J , Jin P , Nie S . Facile synthesizing the homogeneous hierarchical nanosheets of nickel phyllosilicate to enhance the wear resistance, mechanical response, and thermal stability of epoxy composites. Journal of Materials Research and Technology, 2023, 26: 6857–6876

[15]	Xu Y , Nie S , Dai G , Yang J , Dong X , Feng X . Effect of phosphorus-modified nickel phyllosilicates on the thermal stability, flame retardancy, and mechanical property of epoxy composites. Journal of Polymer Research, 2022, 29(1): 10

[16]	Sui Y , Sima H , Shao W , Zhang C . Novel bioderived cross-linked polyphosphazene microspheres decorated with FeCo-layered double hydroxide as an all-in-one intumescent flame retardant for epoxy resin. Composites Part B: Engineering, 2022, 229: 109463

[17]	Liu S , Fang Z , Yan H , Chevali V S , Wang H . Synergistic flame retardancy effect of graphene nanosheets and traditional retardants on epoxy resin. Composites Part A: Applied Science and Manufacturing, 2016, 89: 26–32

[18]	Jiang H , Xie Y , Zhu R , Luo Y , Sheng X , Xie D , Mei Y . Construction of polyphosphazene-functionalized Ti₃C₂T_x with high efficient flame retardancy for epoxy and its synergetic mechanisms. Chemical Engineering Journal, 2023, 456: 141049

[19]	Soni V , Dahiya J B . Synthesis and characterization of a novel P/N containing flame retardant and its effect on flame-retardancy, thermal, and mechanical properties of epoxy/clay nanocomposites. High Performance Polymers, 2023, 35(7): 740–749

[20]	Yang Q , Jia Y , Zhou X , Zhang H . Mechanically reinforced flame-retardant epoxy resins by layered double hydroxide in situ decorated carbon nanotubes. ACS Applied Polymer Materials, 2022, 4(9): 6731–6741

[21]	Nie S , Zhao Z , Zhai W , Yang J , Zhang H , Zhao D , Wang J . Interfacial property optimization through the co-deployment of MOF-derived nickel phyllosilicate and DOPO: effective reinforcement and flame retardancy of epoxy resin. Composites Part B: Engineering, 2025, 289: 111947

[22]	Burattin P , Che M , Louis C . Characterization of the Ni(II) phase formed on silica upon deposition precipitation. Journal of Physical Chemistry B, 1997, 101(36): 7060–7074

[23]	Fukushima Y , Tani M . Synthesis of 2:1 type 3-(methacryloxy) propyl magnesium (nickel) phyllosilicate. Bulletin of the Chemical Society of Japan, 1996, 69(12): 3667–3671

[24]	Mizutani T , Fukushima Y , Okada A , Kamigaito O . Synthesis of nickel and magnesium phyllosilicates with 1:1 and 2:1 layer structures. Bulletin of the Chemical Society of Japan, 1990, 63(7): 2094–2098

[25]	Sivaiah M V , Petit S , Barrault J , Batiot-Dupeyrat C , Valange S . CO₂ reforming of CH₄ over Ni-containing phyllosilicates as catalyst precursors. Catalysis Today, 2010, 157(1): 397–403

[26]	Zhang Y , Cui J , Wang L , Yu H , Li F , Yang B , Guo J , Mu B , Tian L . Cross-linked Salen-based polyphosphazenes (Salen-PZNs) enhancing the fire resistance of epoxy resin composites. Journal of Applied Polymer Science, 2021, 138(4): 49727

[27]	Ohtsuka K , Koga J , Suda M , Ono M . Fabrication of metal-layer (nickel) silicate microcomposite particles by a surface-nucleated precipitation route. Journal of the American Ceramic Society, 1989, 72(10): 1924–1930

[28]	Tian X Y , Xu S , Wu K , Zeng H Y , Hu J , Guo Y H . Fabrication of an novel NiCo-based bimetallic hydroxide encapsulated with polyphosphazene with simultaneously improved the flame retardancy and smoke suppression for polypropylene. Journal of Applied Polymer Science, 2022, 139(10): 51771

[29]	Kang H J , Lee T G , Kim H , Park J W , Hwang H J , Hwang H , Jang K S , Kim H J , Huh Y S , Im W B . et al. Thick free-standing electrode based on carbon-carbon nitride microspheres with large mesopores for high-energy-density lithium-sulfur batteries. Carbon Energy, 2021, 3(3): 410–423

[30]	Lehmann T , Wolff T , Hamel C , Veit P , Garke B , Seidel-Morgenstern A . Physico-chemical characterization of Ni/MCM-41 synthesized by a template ion exchange approach. Microporous and Mesoporous Materials, 2012, 151: 113–125

[31]	Xiao N , Lu X H , Yan W J , Wen M X , Sun W , Xu J L , Sun Y H , Sun Q . Self-template synthesis of hollow nano-spherical nickel silicate/nickel sulfide composite and its application for lithium-sulfur battery. Materials Letters, 2021, 300: 130215

[32]	Zhang X Q , Li W C , He B , Yan D , Xu S , Cao Y , Lu A H . Ultrathin phyllosilicate nanosheets as anode materials with superior rate performance for lithium ion batteries. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2018, 6(4): 1397–1402

[33]	Qiu S , Zhou Y , Zhou X , Zhang T , Wang C , Yuen R K K , Hu W , Hu Y . Air-stable polyphosphazene-functionalized few-layer black phosphorene for flame retardancy of epoxy resins. Small, 2019, 15(10): 1805175

[34]	Salmeia K A , Gaan S . An overview of some recent advances in DOPO-derivatives: chemistry and flame retardant applications. Polymer Degradation & Stability, 2015, 113: 119–134

[35]	Wang Y , Zhang J . Influences of specimen size and heating mode on the ignitability of polymeric materials in typical small-scale fire test conditions. Fire and Materials, 2012, 36(3): 231–240

[36]	Nie S , Jin D , Xu Y , Han C , Dong X , Yang J N . Effect of a flower-like nickel phyllosilicate-containing iron on the thermal stability and flame retardancy of epoxy resin. Journal of Materials Research and Technology, 2020, 9(5): 10189–10197

[37]	Jiang L , Nie S , Yang J , Dong J . Synthesis and application of Setaria viridis-like heterostructures using nickel phyllosilicate decorating polyaniline nanorods: toward the robust and wear-resisting epoxy-based composites. Polymer Composites, 2023, 44(12): 8541–8558

[38]	Yang J N , Li Z Y , Feng X S , Nie S B . Construction of a binary architecture of flower-like nickel phyllosilicate@zinc sulfide towards the robust, wear-resistant, and thermal-stable epoxy nanocomposites. Polymer Degradation & Stability, 2023, 207: 110224

[39]	Che Y , Sun Z , Zhan R , Wang S , Zhou S , Huang J . Effects of graphene oxide sheets-zirconia spheres nanohybrids on mechanical, thermal, and tribological performances of epoxy composites. Ceramics International, 2018, 44(15): 18067–18077

[40]	Zhou K , Liu J , Shi Y , Jiang S , Wang D , Hu Y , Gui Z . MoS₂ nanolayers grown on carbon nanotubes: an advanced reinforcement for epoxy composites. ACS Applied Materials & Interfaces, 2015, 7(11): 6070–6081

[41]	Gui C X , Hao S M , Liu Y , Qu J , Yang C , Yu Y , Wang Q Q , Yu Z Z . Carbon nanotube@layered nickel silicate coaxial nanocables as excellent anode materials for lithium and sodium storage. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2015, 3(32): 16551–16559

[42]	Perret B , Schartel B , Stöß K , Ciesielski M , Diederichs J , Döring M , Krämer J , Altstädt V . Novel DOPO-based flame retardants in high-performance carbon fibre epoxy composites for aviation. European Polymer Journal, 2011, 47(5): 1081–1089

[43]	Braun U , Schartel B , Knoll U , Artner J , Ciesielski M , Döring M , Perez R , Sandler J K W , Altstädt V , Hoffmann T . et al. Influence of the oxidation state of phosphorus on the decomposition and fire behaviour of flame-retarded epoxy resin composites. Polymer, 2006, 47(26): 8495–8508

[44]	Liu N , Luo F , Wu H , Liu Y , Zhang C , Chen J . One-step ionic-liquid-assisted electrochemical synthesis of ionic-liquid-functionalized graphene sheets directly from graphite. Advanced Functional Materials, 2008, 18(10): 1518–1525

[45]	Kim H , Abdala A A , Macosko C W . Graphene/polymer nanocomposites. Macromolecules, 2010, 43(16): 6515–6530

[46]	Minh H N , Chinh N T , Thanh Van T T , Hoang T . Ternary nanocomposites based on epoxy, modified silica, and tetrabutyl titanate: morphology, characteristics, and kinetics of the curing process. Journal of Applied Polymer Science, 2019, 136(18): 47412

[47]	Yang J N , Li Z Y , Xu Y X , Nie S B , Liu Y . Effect of nickel phyllosilicate on the morphological structure, thermal properties, and wear resistance of epoxy nanocomposites. Journal of Polymer Research, 2020, 27(9): 274

[48]	Luo Y , Cai J , Li L , Lin X , Xiao L , Hou L . Multi-DOPO-based derivative for enhancing flame retardancy and mechanical properties of epoxy resin. Progress in Organic Coatings, 2023, 184: 107862

[49]	Yang B , Zhao P , Guo Y , Mao X , Li T , Cui J , Guo J , Mu B , Tian L . A smart DOPO-containing decoration armed on Salen-polyphosphazene toward high-efficient flame retardancy for epoxy thermoset. Journal of Vinyl and Additive Technology, 2022, 28(1): 211–225

[50]

Yu B , Xing W , Guo W , Qiu S , Wang X , Lo S , Hu Y . Thermal exfoliation of hexagonal boron nitride for effective enhancements on thermal stability, flame retardancy, and smoke suppression of epoxy resin nanocomposites via sol-gel process. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2016, 4(19): 7330–7340

[51]	Yu M , Zhang T , Li J , Tan J , Zhang M , Zhou Y , Zhu X . Facile synthesis of eugenol-based phosphorus/silicon-containing flame retardant and its performance on fire retardancy of epoxy resin. ACS Applied Polymer Materials, 2022, 4(3): 1794–1804

[52]	Wu Q , Zhang Q , Zhao L , Li S N , Wu L B , Jiang J X , Tang L C . A novel and facile strategy for highly flame retardant polymer foam composite materials: transforming silicone resin coating into silica self-extinguishing layer. Journal of Hazardous Materials, 2017, 336: 222–231

[53]	Wang R , Chen Y , Liu Y , Ma M , Hou Y , Chen X , Ma Y , Huang W . Synthesis of sugar gourd-like metal organic framework-derived hollow nanocages nickel molybdate@cobalt-nickel layered double hydroxide for flame retardant polyurea. Journal of Colloid and Interface Science, 2022, 616: 234–245

[54]	Wang H , Li S , Zhu Z , Yin X , Wang L , Weng Y , Wang X . A novel DOPO-based flame retardant containing benzimidazolone structure with high charring ability towards low flammability and smoke epoxy resins. Polymer Degradation & Stability, 2021, 183: 109426

[55]	Cao J , Duan H , Zou J , Zhang J , Ma H . A bio-based phosphorus-containing co-curing agent towards excellent flame retardance and mechanical properties of epoxy resin. Polymer Degradation & Stability, 2021, 187: 109548

[56]	Lee H E , Kim D , You A , Park M H , Kim M , Kim C . Transition metal-catalyzed α-position carbon-carbon bond formations of carbonyl derivatives. Catalysts, 2020, 10(8): 861

[57]	Cuesta A , Dhamelincourt P , Laureyns J , Martínez-Alonso A , Tascón J M D . Raman microprobe studies on carbon materials. Carbon, 1994, 32(8): 1523–1532

[58]	Shen Z Q , Chen L , Lin L , Deng C L , Zhao J , Wang Y Z . Synergistic effect of layered nanofillers in intumescent flame-retardant epdm: montmorillonite versus layered double hydroxides. Industrial & Engineering Chemistry Research, 2013, 52(25): 8454–8463

[59]	Bao Q , Liu Y , He R , Wang Q . The effect of strawberry-like nickel-decorated flame retardant for enhancing the fire safety and smoke suppression of epoxy resin. Polymer Degradation & Stability, 2021, 193: 109740

[60]	Deng C L , Du S L , Zhao J , Shen Z Q , Deng C , Wang Y Z . An intumescent flame retardant polypropylene system with simultaneously improved flame retardancy and water resistance. Polymer Degradation & Stability, 2014, 108: 97–107

[61]	Ferrari A C , Rodil S E , Robertson J . Interpretation of infrared and Raman spectra of amorphous carbon nitrides. Physical Review B: Condensed Matter, 2003, 67(15): 155306

[62]	Cai W , Li Z , Pan Y , Feng X , Han L , Cui T , Hu Y , Hu W . A novel approach simultaneously imparting well-hydrophobicity and photothermal conversion effect to polymer materials: solar-promoted absorption of organic solvents and oils. Journal of Hazardous Materials, 2022, 437: 129446

[63]	He Q , Song L , Hu Y , Zhou S . Synergistic effects of polyhedral oligomeric silsesquioxane (POSS) and oligomeric bisphenyl A bis(diphenyl phosphate) (BDP) on thermal and flame retardant properties of polycarbonate. Journal of Materials Science, 2009, 44(5): 1308–1316

[64]	Hou K , Gong K , Gao F , Yin L . Facile strategy to synthesize MXene@LDH nanohybrids for boosting the flame retardancy and smoke suppression properties of epoxy. Composites Part A: Applied Science and Manufacturing, 2022, 157: 106912

[65]	Cho S Y , Allcock H R . Novel highly fluorinated perfluorocyclobutane-based phosphazene polymers for photonic applications. Chemistry of Materials, 2007, 19(25): 6338–6344

[66]

Wei W C , Deng C , Huang S C , Wei Y X , Wang Y Z . Nickel-schiff base decorated graphene for simultaneously enhancing the electroconductivity, fire resistance, and mechanical properties of a polyurethane elastomer. Journal of Materials Chemistry A: Materials for Energy and Sustainability, 2018, 6(18): 8643–8654

[67]	Chen X , Lin X , Ye W , Xu B , Wang D Y . Polyelectrolyte as highly efficient flame retardant to epoxy: synthesis, characterization, and mechanism. Polymer Degradation & Stability, 2022, 206: 110181

[68]	Ren X , Zou B , Zhou Y , Zhao Z , Qiu S , Song L . Construction of few-layered black phosphorus/graphite-like carbon nitride binary hybrid nanostructure for reducing the fire hazards of epoxy resin. Journal of Colloid and Interface Science, 2021, 586: 692–707

[69]

Qiu S , Xing W , Feng X , Yu B , Mu X , Yuen R K K , Hu Y . Self-standing cuprous oxide nanoparticles on silica@ polyphosphazene nanospheres: 3D nanostructure for enhancing the flame retardancy and toxic effluents elimination of epoxy resins via synergistic catalytic effect. Chemical Engineering Journal, 2017, 309: 802–814

[70]	Xu M J , Xu G R , Leng Y , Li B . Synthesis of a novel flame retardant based on cyclotriphosphazene and DOPO groups and its application in epoxy resins. Polymer Degradation & Stability, 2016, 123: 105–114

[71]

Wang S , Wu W , Chen Q , Ding Z , Li S , Zhang A , Tang T , Liu J , Okoye P U . Preparation of DOPO-derived magnesium phosphate whisker and its synergistic effect with ammonium polyphosphate on the flame retardancy and mechanical property of epoxy resin. Journal of Applied Polymer Science, 2023, 140(6): e53430

[72]	Li P , Wang J , Wang C , Xu C , Ni A . The flame retardant and mechanical properties of the epoxy modified by an efficient DOPO-based flame retardant. Polymers, 2024, 16(5): 631

[73]	Yang J , Yang H , Xu X , Xu Y , Chen D , Chen W , Wang Z , Nie S . Hydrangea-inspired multi-scale hybrids: rational in situ assembly of nickel phyllosilicates on polyphosphazene microspheres to fabricate highly robust, toughened, and wear-resistant epoxy composites. Polymer Composites, 2026,

[74]	Gupta S , Hammann T , Johnson R , Riyad M F . Tribological behavior of novel Ti₃SiC₂ (natural nanolaminates)-reinforced epoxy composites during dry sliding. Tribology Transactions, 2015, 58(3): 560–566

[75]	Hong J , Liu C H , Deng X , Jiang T , Gan L , Huang J . Enhanced tribological properties in core-shell structured SiO₂@GO hybrid fillers for epoxy nanocomposites. RSC Advances, 2016, 6(92): 89221–89230

[76]	Chen W , Yang J , Zhang F , Liu J , Nie S , Wang Z , Liu L . Significance of structurally inherited nickel/cobalt bimetallic phyllosilicates for enhancing the mechanical, thermal, and dry-sliding properties of epoxy composites. Construction & Building Materials, 2025, 472: 140898