![]() ![]() In thi s rega rd, ca rda nol -de riv ed epo xy resi n an d li gn in were used to pr oduce bioba sed GPE in potass ium- ion batter ies and the result s showed excel lent electr ochem ical stabi lity and proper ion conductivity in the potassium-ion battery. In this fra mew ork, gel pol yme r ele ctr oly tes (GP E) as nat ure -so urc ed con sti tue nts can be con sid ere d valua ble altern atives in the large- scale manuf actur ing of cells. The produ ction of energy from renewable energy sources as an alternative to fossil fuel is growing and this further in- creas es the need for efficient energy storage systems such as batter ies. The hydrogel strain sensor was found to be highly sensitive with superior durability by which both large and small motions were translated into the relative resistive changes when attaching to the human skin. introduced ferric io ns in to th e po ly (N - acry lami de-co -acry lami de) (P (THAM/ AM) hydro gel cross- linked with cellulose nanofiber. Additionally, small external stimulus and huge pressure load wer e bot h sens ed by the sensor which indic ate s its high sensitivity. fabricated a dual type of sensor using MXene/cellulose nanofibers and their findings showed that the sensor possesses excellent stability and degrad abili ty. Nonetheless, their rigidity, low sensiti vity, and sensing range signifi cantl y limit their pract ical appl icati ons in eco-f riend ly and real- time accu rate moni- toring. Public healthcare has been progressively utilizing various types of sensors to reduce the burden on the medical organi- zation and the total costs. Thus, nature can be an inspi ratio n to develo p and design man-m ade structures with high energy absorption. Furthermore, the peel of pomelo fruit provides significant impact protection when falling on the ground. For example, wood and bones with lattice structures often show remarkable mechanical properties and are known as natural energy absorbers. The bio ins pir ed design typically mimics the natural structures using modern manufacturing techniques to obtain comparabl e functionality. Th is le d to th e in tr od uc ti on of bi o- inspiration, which is known as the integration of scientific fiel ds inc lud ing bio log y and mat eri als sci enc e. Given the design concept, nature has pro- vided us with novel structures with high-impact tolerance capa bilit ies. This work provides a good understanding of architectural design for a new generation of advanced honeycomb-based structures with efficient energy-absorbing properties.Ĥ ]. ![]() Finally, the importance of po- tential design to enhance the crashworthy performance of honeycomb structures together with the future challenges is summarized. ![]() Then, the various classifications of advanced honeycomb design, including graded, hierarchical, and sandwich panel-based honeycomb structures, are established and discussed with a focus on the advantageous effect of various designs on the crashworthiness of honeycomb-based structures. In the present work, the criteria of crashworthiness as well as the nature-bioinspired cellular structures are first introduced. Thus, they have attracted attention in the field of automobiles, railway vehicles, etc. Hon eyc omb str uct ure s are kno wn to hav e excellent mechanical performances, which are mainly due to the configurations of the unit cell. S safety and lead to less fue l con sum pti on and gas emi ssio n. ![]()
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