Sandwich composites are widely used in civil, transportation, aerospace, and defense applications due to their lightweight facesheet-core architectures, which minimize blast-induced deformation while maintaining high energy absorption capacity. Conventional metallic and synthetic protective systems provide high strength but often increase structural weight and environmental burden. This systematic literature review synthesizes studies indexed in Scopus and Web of Science published from 2016 to 2025 on blast-resistant sandwich composites, focusing on design strategies, parametric studies, and the potential of natural fibers. The review employed the PRISMA framework for study screening and bibliometric mapping to identify dominant research clusters and design trends. The synthesis shows that blast mitigation is governed not by material strength alone, but by the coupled effects of core collapse, facesheet integrity, and energy dissipation. Core geometry, graded configurations, foam filling, hybrid laminates, and topology-optimized designs can improve back-face deflection control and damage tolerance when matched to the relevant blast regime. Natural fiber-based composites offer potential for sustainable protective systems, particularly in hybrid or secondary facesheet configurations under low-to-moderate impulse conditions. However, their application remains limited by material variability, insufficient high strain rate data, and inconsistent test metrics. Standardized benchmarks, normalized performance indicators, and regime-aware design strategies are needed.
GülcanOGünaydınKTamerA. The effect of geometrical parameters on blast resistance of sandwich panels—a review. Funct Compos Struct2023; 5: 022001.
2.
LiXLiZGuoZ, et al.A parametric study on sandwich structures with star-shaped honeycomb core under blast loads. J Phys Conf Ser2024; 2891: 042016.
3.
PatelMPatelS. A comparative blast mitigation performance evaluation of metallic sandwich panels with honeycomb, corrugated, auxetic, and foam cores. Int J Struct Stab Dyn2025; 25: 2550186.
4.
GünaydınKGülcanO. Air blast response of sandwich structures with auxetic cores under in-plane and axial loadings. Res Eng Struct Mater2023; 9: 617–630.
5.
KumarAChandaAKAngraS. Numerical modelling of a composite sandwich structure having non metallic honeycomb core. Evergreen2021; 8: 759–767.
6.
AbadaMIbrahimA. Metallic ribbon-core sandwich panels subjected to air blast loading. Appl Sci2020; 10: 4500.
7.
WangHLeiJChenJ, et al.Comparative study on the dynamic response of an out-of-plane gradient bionic sandwich circular plate under two types of impact loading. Front Mater2024; 11: 1–13.
8.
ElamashSMShawkyAAliMA, et al.A comparative study on blast resistance of traditional/developed lightweight protective layers. Iop Conf Ser Earth Environ Sci2025; 1530: 012022.
9.
WicaksonoSFitriyahLJusufA, et al.Low-velocity impact damage of foam-core sandwich T-joints: numerical study. Procedia Struct Integr2024; 52: 438–454.
10.
HuaYAkulaPKGuL. Experimental and numerical investigation of carbon fiber sandwich panels subjected to blast loading. Compos Part B Eng2014; 56: 456–463.
11.
PulunganDAFahrezziMGSibaraniKI, et al.Investigation of the anisotropy and crushing responses of 3D printed structures. J Phys Conf Ser2026; 3186: 012008.
12.
EryılmazO. Investigation of the water–based ink hold onto the thermoplastic composites reinforced with sisal fibers. J Text Sci Fash Technol2020; 5: 2.
13.
MochaneMJMagagulaSISefadiJS, et al.A review on green composites based on natural fiber-reinforced polybutylene succinate (PBS). Polymers (Basel)2021; 13: 1200.
14.
RohitKDixitS. A review - future aspect of natural fiber reinforced composite. Polym Renew Resour2016; 7: 43–59.
15.
QinYSummerscalesJGraham-JonesJ, et al.Monomer selection for in situ polymerization infusion manufacture of natural-fiber reinforced thermoplastic-matrix marine composites. Polymers (Basel)2020; 12: 2928.
16.
GSJSPKNishanthS, et al.Experimental investigation on banana fiber reinforced phenol formaldehyde composite for automotive application. Int Res J Adv Sci Hub2020; 2: 94–99.
17.
CastroBDDFotouhiMVieiraLMG, et al.Mechanical behaviour of a green composite from biopolymers reinforced with sisal fibres. J Polym Environ2020; 29: 429–440.
18.
SulongABYaZRadzuanNAM, et al.Mechanical properties of kenaf fiber and nano-clay on poly (lactic) acid (PLA) composites: a review. J Kejuruter2025; 37: 695–719.
19.
GkoloniNGolonisCHKostopoulosV. Integration of LCA and LCC for decision making in biocomposite production. Iop Conf Ser Earth Environ Sci2022; 1123: 012071.
20.
XuPZhaoNChangY, et al.Experimental and numerical study on dynamic response of foam-nickel sandwich panels under near-field blast loading. Materials (Basel)2023; 16: 5640.
21.
GabrielSKlempererCJVYuenSCK, et al.Towards an understanding of the effect of adding a foam core on the blast performance of glass fibre reinforced epoxy laminate panels. Materials (Basel)2021; 14: 7118.
22.
KordeSShirbhatePAGoelMD. Investigation of adhesive debonding in paper honeycomb sandwich panel under blast load. Asps Conf Proc2022; 1: 77–81.
23.
LiangMLiXLinY, et al.Theoretical analysis of blast protection of graded metal foam-cored sandwich cylinders/rings. Materials (Basel)2020; 13: 3903.
24.
SoleimaniSMGhareebNShakerNH. Modeling, simulation and optimization of steel sandwich panels under blast loading. Am J Eng Appl Sci2018; 11: 1130–1140.
25.
AnsoriDTAPrabowoARMuttaqieT, et al.Investigation of honeycomb sandwich panel structure using aluminum alloy (AL6XN) material under blast loading. Civ Eng J2022; 8: 1046–1068.
26.
PratomoANSantosaSPGunawanL, et al.Design optimization and structural integrity simulation of aluminum foam sandwich construction for armored vehicle protection. Compos Struct2021; 276: 114461.
27.
ChengYZhouTWangH, et al.Numerical investigation on the dynamic response of foam-filled corrugated core sandwich panels subjected to air blast loading. J Sandw Struct Mater2017; 21: 838–864.
28.
Pernas-SánchezJArtero-GuerreroJAVarasD, et al.Cork core sandwich plates for blast protection. Appl Sci2020; 10: 5180.
29.
SahooSSSwainAKSawantVA. Computational analysis and optimization of foam-filled honeycomb core sandwich structure under air blast loading. J Sandw Struct Mater2025; 27: 962–996.
30.
SumalaMKrishnaBMTezeswiTP. Structural performance of EPS core based cementitious sandwich panel under Various loading conditions. J Phys Conf Ser2024; 2779: 012073.
31.
DaiKJiangTZhaoM, et al.Numerical analysis on the dynamic response of PVC foam/polyurea composite sandwich panels under the close air blast loading. Polymers2024; 16: 810.
32.
LiLZhangFLiJ, et al.Computational analysis of sandwich panels with graded foam cores subjected to combined blast and fragment impact loading. Materials (Basel)2023; 16: 4371.
33.
PatelSPatelM. The efficient design of hybrid and metallic sandwich structures under air blast loading. J Sandw Struct Mater2022; 24: 1706–1725.
34.
PatelMPatelSBhoiNK, et al.Topology optimization of the thin-walled honeycomb core at fixed mass and volume occupancy for enhancing the sandwich panel’s air blast mitigation performance. Mech Adv Mater Struct2025: 1–19. DOI: https://doi.org/10.1080/15376494.2025.2545426.
35.
PatelMPatelS. Blast mitigation analysis of novel designed sandwich structures using novel approaches. Mech Adv Mater Struct2024; 31: 7195–7217.
36.
JingLLiuKSuX, et al.Experimental and numerical study of square sandwich panels with layered-gradient foam cores to air-blast loading. Thin-Walled Struct2021; 161: 107445.
37.
YanZLiuYYanJ, et al.Blast performance of 3D-printed auxetic honeycomb sandwich beams. Thin-Walled Struct2023; 193: 111257.
38.
PatelMPatelSAhmadS. Blast analysis of efficient honeycomb sandwich structures with CFRP/steel FML skins. Int J Impact Eng2023; 178: 104609.
39.
KellyMAroraHWorleyA, et al.Sandwich panel cores for blast applications: materials and graded density. Exp Mech2016; 56: 523–544.
40.
ChenGZhangPDengN, et al.Paper tube-guided blast response of sandwich panels with auxetic re-entrant and regular hexagonal honeycomb cores – an experimental study. Eng Struct2022; 253: 113790.
41.
JiangZRongJChenZ, et al.Deformation mechanisms and energy absorption characteristics of 3D-printed negative poisson’s ratio sandwich structures subjected to underwater impulsive loading. Int J Impact Eng2025; 203: 105355.
42.
KalubadanageDRemennikovANgoT, et al.Close-in blast resistance of large-scale auxetic re-entrant honeycomb sandwich panels. J Sandw Struct Mater2021; 23: 4016–4053.
43.
AlAhmedYSHassanNMBahrounZ. Significance of sandwich panel’s core and design on its impact resistance under blast load. J Compos Sci2023; 7: 44.
44.
ZhuPRongJWangS, et al.Dynamic response of polymethacrylimide foam sandwich structures with different core layers under water impact loading. Def Technol2025; 49: 203–222.
45.
WangXYuR-PZhangQ-C, et al.Dynamic response of clamped sandwich beams with fluid-filled corrugated cores. Int J Impact Eng2020; 139: 103533.
46.
LiuYYuHWuJ, et al.Dynamic response of square sandwich panels with stagger-layered honeycomb cores under intensive near-field air blast loading. Thin-Walled Struct2024; 196: 111515.
47.
PatelMPatelS. Dynamic response optimization of the multistage sandwich structures imperiled to explosive loading. Proc Inst Mech Eng Part J Mater Des Appl2024; 238: 1999–2017.
48.
SawantRPatelS. Blast resistance of two-stage sandwich panels with homogeneous and hybrid core configurations under high-intensity loading. Int J Struct Stab Dyn2026: 2750205. DOI: https://doi.org/10.1142/S0219455427502051.
49.
ChenCWangXHouH, et al.Effect of strength matching on failure characteristics of polyurea coated thin metal plates under localized air blast loading: experiment and numerical analysis. Thin-Walled Struct2020; 154: 106819.
50.
WangWWangYYangJ, et al.Investigation on air blast resistance of POZD-coated composite steel plates: experiment and numerical analysis. Compos Part B Eng2022; 237: 109858.
51.
ChenGZhangPLiuJ, et al.Experimental and numerical analyses on the dynamic response of aluminum foam core sandwich panels subjected to localized air blast loading. Mar Struct2019; 65: 343–361.
52.
ChenGChengYZhangP, et al.Blast resistance of metallic double arrowhead honeycomb sandwich panels with different core configurations under the paper tube-guided air blast loading. Int J Mech Sci2021; 201: 106457.
53.
StudzińskiRSumelkaWMalendowskiM, et al.Sandwich panel subjected to blast wave impact and accelerated fragments. Eksploat Niezawodn – Maint Reliab2024; 26: 183698.
54.
HuangWLuLFanZ, et al.Underwater impulsive resistance of the foam reinforced composite lattice sandwich structure. Thin-Walled Struct2021; 166: 108120.
55.
WangWZhouHMaoJ, et al.Study on the protective performance of metakaolin-based foam geopolymer (MKFG) as a sacrificial cladding under internal blast mitigation. Int J Impact Eng2024; 189: 104969.
56.
LiHJShenCJLuG, et al.Response of cylindrical tubes subjected to internal blast loading. Eng Struct2022; 272: 115004.
57.
LianZMaT. Mathematical control of space-based kinetic energy weapons based on partial differential equations and evaluation of their destructive effects. Math Probl Eng2022; 2022: 1–11.
58.
LiZLeiDHuangZ. Honeycomb sandwich panels for centrifugal underwater explosion model tests. Int J Mech Sci2025; 303: 110635.
59.
ChenZZongZLiJ, et al.Experimental and numerical study on damage behavior of air-backed steel-concrete-steel composite panels subjected to underwater contact explosion. Eng Struct2024; 318: 118744.
60.
YinCLiuJJinZ. Experimental and numerical study of the near-field underwater explosion of a circular plate coated by rigid polyurethane foam. Ocean Eng2022; 252: 111248.
61.
XiangXLuGLiZ, et al.Dynamic response of monolithic and sandwich structures subjected to impulsive and impact loadings. Adv Struct Eng2018; 21: 1134–1147.
62.
ChenZRongJWeiZ, et al.Dynamic response of hemispherical-shell sandwich structures subjected to underwater impulsive loading. Thin-Walled Struct2024; 205: 112550.
63.
HuXYanKWuH, et al.Dynamic response of cylindrical sandwich panels with coaxial and concentric honeycombs under blast loads. Eng Struct2025; 343: 120942.
64.
HeXHuangZChenZ, et al.Dynamic response of CFRP-lattice sandwich structures subjected to underwater shock wave loading. Thin-Walled Struct2022; 181: 109537.
65.
NiCLuoCQiangL, et al.Dynamic response of ceramic-reinforced metallic corrugated sandwich structures under combined blast-fragment loading. Eng Struct2025; 343: 121095.
66.
QiangLZhangRZhaoC, et al.Dynamic performance of ultralight corrugated sandwich plate with FML face-sheets impacted by FSP-foam composite projectile. Thin-Walled Struct2023; 188: 110875.
67.
PatelMPatelS. Design and analysis of lightweight stiffened honeycomb metallic sandwich panels under high-intensity air blast. Proc Inst Mech Eng Part J Mater Des Appl2024; 238: 22–38.
68.
LiangXWangZWangR. Deformation model and performance optimization research of composite blast resistant wall subjected to blast loading. J Loss Prev Process Ind2017; 49: 326–341.
69.
WeiYZhangCYuanY, et al.Blast response of additive manufactured Ti–6Al–4V sandwich panels. Int J Impact Eng2023; 176: 104553.
70.
XiaZWangXFanH, et al.Blast resistance of metallic tube-core sandwich panels. Int J Impact Eng2016; 97: 10–28.
71.
LuoFZhangSYangD. Anti-Explosion performance of composite blast wall with an auxetic Re-entrant honeycomb core for offshore platforms. J Mar Sci Eng2020; 8: 182.
72.
ChenHYanKShenX, et al.Tortoise-back-reinforced elliptical-embedded honeycomb composite structure: experimental and numerical analysis of responses under blast loading. Compos Struct2025; 373: 119656.
73.
RuaJJBuchelyMFMonteiroSN, et al.Structure-property relations of a natural composite: bamboo guadua angustifolia, under impact and flexural loads. J Compos Mater2021; 55: 2953–2966.
74.
ZhangKWangFYangB, et al.Mechanical response and failure mechanisms of natural bamboo fiber reinforced poly-benzoxazine composite subjected to split-hopkinson tensile bar loading. Polymers (Basel)2022; 14: 1450.
75.
AhmedSAliM. Use of agriculture waste as short discrete fibers and glass-fiber-reinforced-polymer rebars in concrete walls for enhancing impact resistance. J Clean Prod2020; 268: 122211.
76.
ColamartinoIPinatoECavasinM, et al.Static, dynamic and impact properties of a high-performance flax-fiber composite. Results Mater2023; 20: 100493.
77.
SarasiniFTirillòJLampaniL, et al.Static and dynamic characterization of agglomerated cork and related sandwich structures. Compos Struct2019; 212: 439–451.
78.
HuangKRammohanAVKureemunU, et al.Shock wave impact behavior of flax fiber reinforced polymer composites. Compos Part B Eng2016; 102: 78–85.
79.
BoumbimbaRMWangKHablotE, et al.Renewable biocomposites based on cellulose fibers and dimer fatty acid polyamide: experiments and modeling of the stress–strain behavior. Polym Eng Sci2017; 57: 95–104.
Garcia FilhoFCLuzFSOliveiraMS, et al.Influence of rigid Brazilian natural fiber arrangements in polymer composites: energy absorption and ballistic efficiency. J Compos Sci2021; 5: 201.
82.
RuaJBuchelyMFMonteiroSN, et al.Impact behavior of laminated composites built with fique fibers and epoxy resin: a mechanical analysis using impact and flexural behavior. J Mater Res Technol2021; 14: 428–438.
83.
PandyaTSDaveMJStreetJ, et al.High strain rate response of bio-composites using split hopkinson pressure bar and digital image correlation technique. Int Wood Prod J2019; 10: 22–30.
84.
HuDSongBDangL, et al.Effect of strain rate on mechanical properties of the bamboo material under quasi-static and dynamic loading condition. Compos Struct2018; 200: 635–646.
85.
DaveMJPandyaTSStoddardD, et al.Dynamic characterization of biocomposites under high strain rate compression loading with split hopkinson pressure bar and digital image correlation technique. Int Wood Prod J2018; 9: 115–121.
86.
Li PianiTWeerheijmJPeroniM, et al.Dynamic behaviour of adobe bricks in compression: the role of fibres and water content at various loading rates. Constr Build Mater2020; 230: 117038.
87.
HaroEESzpunarJAOdeshiAG. Dynamic and ballistic impact behavior of biocomposite armors made of HDPE reinforced with chonta palm wood (Bactris gasipaes) microparticles. Def Technol2018; 14: 238–249.
88.
XiangCHuSZhangS, et al.Compressive characterization of hemp fiber–epoxy matrix composite for lightweight structures. JOM2020; 72: 2324–2331.
89.
YangYQiuZFanH. Close-in explosion performances and damage evaluation of bamboo fiber reinforced laminates. Thin-Walled Struct2024; 205: 112461.
90.
GabrielSLangdonGSKlempererCJV, et al.Blast behaviour of fibre reinforced polymers containing sustainable constituents. J Reinf Plast Compos2022; 41: 771–790.
91.
QiuZFanHWangB, et al.A more explosion-resistant bamboo fiber reinforced composite structure through balancing bamboo anisotropy. Constr Build Mater2023; 409: 133968.
92.
KumarRKumarKBhowmikS. Assessment and response of treated Cocos nucifera reinforced toughened epoxy composite towards fracture and viscoelastic properties. J Polym Environ2018; 26: 2522–2535.
93.
BasraniJKumarMKumarP. An experimental study of static and dynamic behavior of the hybrid composite. J Nat Fibers2022; 19: 15475–15487.
94.
PathakRKPatelSGuptaVK, et al.A computational analysis of the high-velocity impact performance of lightweight 3D hybrid composite armors. Appl Compos Mater2023; 30: 727–751.
95.
JingLZhaoL. Blast resistance and energy absorption of sandwich panels with layered gradient metallic foam cores. J Sandw Struct Mater2017; 21: 464–482.
96.
IrwinZClaytonJDRegueiroRA. A large deformation multiphase continuum mechanics model for shock loading of soft porous materials. Int J Numer Methods Eng2024; 125: e7411.
97.
WuJQQinBZhangX, et al.Protective performance of helmets based on the shock wave from rocket launcher. J Phys Conf Ser2024; 2891: 042031.
98.
AndamiHToopchi-NezhadH. Performance assessment of rigid polyurethane foam core sandwich panels under blast loading. Int J Prot Struct2019; 11: 109–130.
99.
SawantRPatelS. Efficient design of composite honeycomb sandwich panels under blast loading. Proc Inst Mech Eng Part C J Mech Eng Sci2024; 238: 10515–10535.
100.
ChenJKongD. Study on the variation law of shock wave on the surface of landmine shell under touchdown explosion. Meas Sci Technol2024; 35: 055119.
101.
MatosHJavierCLeBlancJ, et al.Underwater nearfield blast performance of hydrothermally degraded carbon–epoxy composite structures. Multiscale Multidiscip Model Exp Des2018; 1: 33–47.
102.
ZhouHGuoRLiuR, et al.Dynamic response of composite sandwich structures with the honeycomb-foam hybrid core subjected to underwater shock waves: numerical simulations. J Compos Mater2022; 56: 911–928.
103.
DeenadayalanGSivakumaSVishnuvardhanR, et al.Fabrication and characterisation of B-H-G fiber with teak wood particles reinforced hybrid composite. Int J Eng Technol2018; 7: 208.
104.
GuledFDChittappaHC. Damage tolerance of carbon and kevlar based hybrid composites against quasi-static indentation. Eng Res Express2019; 1: 025020.
