Experimental evaluation and analytical prediction of effects of skin defect size on the long-term durability of bio-based balsa core sandwich structures
Restricted accessResearch articleFirst published online January, 2026
Experimental evaluation and analytical prediction of effects of skin defect size on the long-term durability of bio-based balsa core sandwich structures
This work focuses on the characterization of the cyclic moisture absorption-desorption aging behavior of balsa wood core sandwich structures with two-dimensional defects in Glass-Fiber-Reinforced-Polymer (GFRP) skins. Experimental investigations and analytical predictions were compared to evaluate the effects of skin defect size on the moisture diffusion kinetics during long-term aging cycles, in terms of the moisture diffusion coefficients and maximum moisture content capacity. Two distinct protocols were employed to investigate the effects of hygroscopic aging history on the moisture diffusion kinetics, including complete-cycle and incomplete-cycle absorption conditions, respectively. The Dual Fickian model proves to be admissible in predicting the moisture absorption behavior, while the moisture desorption process is in good agreement with the classical Fickian model, regardless of the skin defect size. Furthermore, the results reveal that the main moisture diffusion coefficient DI of the Dual Fickian model in the first complete absorption cycle could be doubled with a twofold increase in the skin defect size, while the larger skin defect has resulted in a slight decrease in the moisture diffusion coefficient D during all desorption cycles, which is mainly due to the transport of more bound water. In addition, the predicted maximum moisture content capacity is nearly three times higher for all absorption and desorption cycles as the skin defect size is doubled.
Osa-UwagboeNSilberschimdtVVAremiA, et al.Mechanical behaviour of fabric-reinforced plastic sandwich structures: a state-of-the-art review. J Sandw Struct Mater2023; 25: 591–622.
2.
MeddourMSi SalemAAit TalebS. Bending behavior of new composited sandwich panels with GFRP waste based-core and PVC facesheets: experimental design, modeling and optimization. Constr Build Mater2024; 426: 136117.
3.
ZhangZCaiSLiY, et al.High performances of plant fiber reinforced composites—a new insight from hierarchical microstructures. Compos Sci Technol2020; 194: 108151.
4.
MoudoodARahmanAÖchsnerA, et al.Flax fiber and its composites: an overview of water and moisture absorption impact on their performance. J Reinforc Plast Compos2019; 38(7): 323–339.
5.
NkeuwaWNZhangJSempleKE, et al.Bamboo-based composites: a review on fundamentals and processes of bamboo bonding. Compos B Eng2022; 235: 109776.
6.
KrabbenhoftKDamkildeL. A model for non-Fickian moisture transfer in wood. Mater Struct2004; 37: 615–622.
7.
SadlerRLSharpeMPandurangaR, et al.Water immersion effect on swelling and compression properties of Eco-Core, PVC foam and balsa wood. Compos Struct2009; 90(3): 330–336.
8.
VahediNTiagoCVassilopoulosAP, et al.Thermophysical properties of balsa wood used as core of sandwich composite bridge decks exposed to external fire. Constr Build Mater2022; 329: 127164.
9.
SayahlatifiSRahimiGBokaeiA. Experimental and numerical investigation of sandwich structures with balsa core and hybrid corrugated composite/balsa core under three-point bending using digital image correlation. J Sandw Struct Mater2021; 23(1): 94–131.
10.
AcetiPCarminatiLBettiniP, et al.Hygrothermal ageing of composite structures. Part 2: mitigation techniques, detection and removal. Compos Struct2023; 319: 117105.
11.
BachchanAADasPPChaudharyV. Effect of moisture absorption on the properties of natural fiber reinforced polymer composites: a review. Mater Today Proc2022; 49: 3403–3408.
12.
Osa-uwagboeNSilberschmidtVVBaxevanakisKP, et al.Effects of moisture absorption on penetration performance of FRP sandwich structures. Compos Struct2024; 344: 118319.
13.
PéronMCélinoACastroM, et al.Study of hygroscopic stresses in asymmetric biocomposite laminates. Compos Sci Technol2019; 169: 7–15.
14.
CélinoAFréourSJacqueminF, et al.The hygroscopic behavior of plant fibers: a review. Front Chem2014; 1: 43.
15.
AzwaZNYousifBFManaloAC, et al.A review on the degradability of polymeric composites based on natural fibres. Mater Des2013; 47: 424–442.
16.
GassanJBledzkiAK. Effect of cyclic moisture absorption desorption on the mechanical properties of silanized jute‐epoxy composites. Polym Compos1999; 20(4): 604–611.
17.
Glaskova-KuzminaTAniskevichASevcenkoJ, et al.Cyclic moisture sorption and its effects on the thermomechanical properties of epoxy and epoxy/MWCNT nanocomposite. Polymers2019; 11(9): 1383.
18.
MubasharAAshcroftIACritchlowGW, et al.Moisture absorption-desorption effects in adhesive joints. Int J Adhesion Adhes2009; 29(8): 751–760.
19.
WuYPerrinMPastorML, et al.Moisture effects on acoustic emission characteristics and damage mechanisms of balsa wood core composite sandwich under 4-point bending. Materials2024; 17: 1044.
20.
OhGHKimHSParkDW, et al.In-situ monitoring of moisture diffusion process for wood with terahertz time-domain spectroscopy. Opt Laser Eng2020; 128: 106036.
21.
GalosJDasRSutcliffeMP, et al.Review of balsa core sandwich composite structures. Mater Des2022; 221: 111013.
LiXWeitsmanYJ. Sea-water effects on foam-cored composite sandwich lay-ups. Compos B Eng2004; 35(6-8): 451–459.
24.
EarlJSShenoiRA. Determination of the moisture uptake mechanism in closed cell polymeric structural foam during hygrothermal exposure. J Compos Mater2004; 38(15): 1345–1365.
25.
AmeliADatlaNVPapiniM, et al.Hygrothermal properties of highly toughened epoxy adhesives. J Adhes2010; 86(7): 698–725.
26.
JoharMKangHSChongWWF, et al.A further generalized thickness-dependent non-Fickian moisture absorption model using plain woven epoxy composites. Polym Test2018; 69: 522–527.
27.
KessentiniRKlinkovaOTawfiqI, et al.Modeling the moisture diffusion and hygroscopic swelling of a textile reinforced conveyor belt. Polym Test2019; 75: 159–166.
28.
JoharMChongWWFWongKJ. Moisture absorption and tensile behaviour of hybrid carbon/flax composites. Fibers Polym2023; 24(5): 1799–1810.
29.
JangESKangCW. Porosity analysis of three types of balsa (Ochroma pyramidale) wood depending on density. J Wood Sci2022; 68(1): 31.
30.
GoodrichTNawazNFeihS, et al.High-temperature mechanical properties and thermal recovery of balsa wood. J Wood Sci2010; 56: 437–443.
31.
LinYCChenX. Moisture sorption-desorption-resorption characteristics and its effect on the mechanical behavior of the epoxy system. Polymer2005; 46(25): 11994–12003.
32.
GaoCZhouC. Moisture absorption and cyclic absorption-desorption characters of fibre-reinforced epoxy composites. J Mater Sci2019; 54(11): 8289–8301.
33.
PopineauVCélinoAPéronM, et al.Understanding the effect of hygroscopic cycling on the internal stress and stiffness of natural fibre biocomposites. Compos Appl Sci Manuf2022; 158: 106995.
34.
BezzouAPéronMCasariP, et al.Characterization of microcracking of NCF composites under accelerated hygrothermal cycles: influence of the stitching yarn and the style of biaxial NCF. Compos Appl Sci Manuf2021; 149: 106507.
35.
GhabeziPHarrisonNM. Multi-scale modelling and life prediction of aged composite materials in salt water. J Reinforc Plast Compos2024; 43(3-4): 205–219.
36.
EslamiSTaheri-BehroozFTaheriF. Effects of aging temperature on moisture absorption of perforated GFRP. Adv Mater Sci Eng2012; 2012(1): 1–7.
37.
EslamiSTaheri‐BehroozFTaheriF. Long‐term hygrothermal response of perforated GFRP plates with/without application of constant external loading. Polym Compos2012; 33(4): 467–475.
38.
MubasharAAshcroftIACritchlowGW, et al.Modelling cyclic moisture uptake in an epoxy adhesive. J Adhes2009; 85(10): 711–735.
39.
WuYFajouiJCasariP, et al.Characterization of the cyclic aging behavior of balsa wood core biocomposite sandwich structures with preexisting defects in laminate skins. Polym Compos2025: 1–14.
40.
YadavAKCarreraEMarinM, et al.Reflection of hygrothermal waves in a nonlocal theory of coupled thermo-elasticity. Mech Adv Mater Struct2022; 31(5): 1083–1096.
41.
CrankJ. The mathematics of diffusion. Oxford: Clarendon Press, 1975.
42.
LegrandVTranVanLJacqueminF, et al.Moisture-uptake induced internal stresses in balsa core sandwich composite plate: modeling and experimental. Compos Struct2015; 119: 355–364.
43.
WuYFajouiJCasariP, et al.Experimental evaluation of the degradation of bio-based composites under extreme conditions: impact on mechanical performance and durability. EPJ Web Conf2025; 326: 03003.
