Parthenocissus-inspired, strongly adhesive, efficiently self-healing polymers for energetic adhesive applications

Abstract: Energetic self-healing adhesives have a positive effect on the energy level, mechanical properties, and microcrack healing performance of energetic composite materials (ECMs). However, it is very challenging to design and...

“…As shown in Figure 5d, EEUG-17.4%-DTSA-2 became more whitish when it was stretched to a strain of 1000%, suggesting the formation of crystals at high strain. 34 The energy dissipation of EEUG-17.4%-DTSA-2 at different strains was characterized by using cyclic tensile tests with an increasing strain but no delay time 45 SBR/PEI interlocked networks, 28 PU (hydrogen bonds), 46 PB dual network, 25 ENR/chitosan, 47 ENR/cellulose, 48 MIVs (mechanically interlocked vitrimers), 49 and SBR-M.HPDI.Upy dynamic liquid crystal networks. 50 (Figure 5e), and the hysteresis area represents the dissipated energy during each cycle.…”

“…(a) Stress−strain curve and (b) cyclic tensile−strain curves of EEUG-14.5%-DTSA-2, EEUG-14.5%-DTSA-3, and EEUG-17.4%-DTSA-2. (c) Comparison of mechanical properties with other recyclable elastomers: PDMS-Zn,45 SBR/PEI interlocked networks,28 PU (hydrogen bonds),46 PB dual network,25 ENR/chitosan,47 ENR/cellulose,48 MIVs (mechanically interlocked vitrimers),49 and SBR-M.HPDI.Upy dynamic liquid crystal networks 50. (d) Digital images showing the whitening process of the EEUG-17.4%-DTSA-2 at strain from 0 to 1000%.…”

Second Natural Rubber with Self-Reinforcing Effect Based on Strain-Induced Crystallization

“…As shown in Figure 5d, EEUG-17.4%-DTSA-2 became more whitish when it was stretched to a strain of 1000%, suggesting the formation of crystals at high strain. 34 The energy dissipation of EEUG-17.4%-DTSA-2 at different strains was characterized by using cyclic tensile tests with an increasing strain but no delay time 45 SBR/PEI interlocked networks, 28 PU (hydrogen bonds), 46 PB dual network, 25 ENR/chitosan, 47 ENR/cellulose, 48 MIVs (mechanically interlocked vitrimers), 49 and SBR-M.HPDI.Upy dynamic liquid crystal networks. 50 (Figure 5e), and the hysteresis area represents the dissipated energy during each cycle.…”

“…(a) Stress−strain curve and (b) cyclic tensile−strain curves of EEUG-14.5%-DTSA-2, EEUG-14.5%-DTSA-3, and EEUG-17.4%-DTSA-2. (c) Comparison of mechanical properties with other recyclable elastomers: PDMS-Zn,45 SBR/PEI interlocked networks,28 PU (hydrogen bonds),46 PB dual network,25 ENR/chitosan,47 ENR/cellulose,48 MIVs (mechanically interlocked vitrimers),49 and SBR-M.HPDI.Upy dynamic liquid crystal networks 50. (d) Digital images showing the whitening process of the EEUG-17.4%-DTSA-2 at strain from 0 to 1000%.…”

Second Natural Rubber with Self-Reinforcing Effect Based on Strain-Induced Crystallization

“…57 ln t = ln t 0 + E a (1) where E a is the activation energy, and R and T are the gas constant and absolute temperature, respectively. The activation energy of PU-C (60.3 kJ mol À1 ) was lower than other self-healing PU, which has been reported lately, 24,46,58,59 indicating that the energy barrier for the free movement of the molecular chain was lower (Fig. 4d and Fig.…”

“…[12][13][14][15][16][17][18][19][20] They had broad application prospects in aerospace, flexible electronics, smart coatings, and other fields. [21][22][23][24] Particularly in the aerospace field, selfhealing materials were expected to solve a series of safety problems caused by micro-cracks inside solid propellants and have received great attention.…”

Rapid self-healing and tough polyurethane based on the synergy of multi-level hydrogen and disulfide bonds for healing propellant microcracks

“…Energetic materials composed of polymeric binders and metallic fuels are widely applied in industrial and military elds, such as propellants, explosives, pyrotechnics et al [1][2][3][4][5] Metallic fuels, such as aluminum, are widely used in energetic composites to enhance the comprehensive performance, such as energy level, 6 combustion temperature, 7 density, 8,9 and so on. Nevertheless, aluminum particles in energetic composites oen suffer from incomplete combustion and easy agglomeration, leading to reduced energy release and combustion efficiency.…”

Thermal decomposition of nano Al-based energetic composites with fluorinated energetic polyurethane binders: experimental and theoretical understandings for enhanced combustion and energetic performance