RESUMO
Lithium-ion batteries (LIB) stand as ubiquitous power sources in the industrial sector, with a mounting emphasis on their sustainability considerations, where safety, durability, and recyclability are all considered. Within the intricate architecture of LIB, the anode sheet processes a stratified composition comprising an active material layer and a copper foil serving as the current collector. The delamination of the active materials from the current collector is one of the major mechanical failure exhibitions for battery short circuits and deteriorated electrochemical performance. On the contrary, the interfacial strength between the active materials and the current collector also determines the battery manufacturing quality and battery recycling success. To cope with this emerging challenge, we designed quantifiable laser shock-wave adhesion tests to characterize the adhesion strength and delamination behaviors between pure Si-based active materials and the current collector. A physics-based computational model is also established to quantify the adhesion strength further. We discovered that the C-Si sheet is easier for delamination as layer buckling due to the more severe stress concentration around the particles due to the heterogeneity of the carbon and silicon particles. Results highlight the promise to evaluate the delamination behaviors of the current materials via an innovative methodology and provide powerful tools for next-generation sustainable battery design.
RESUMO
INTRODUCTION: Oxidative state, a risk factor for several diseases, is increased by habitual conventional cigarette (CC) smoking. Reports have demonstrated that heat-not-burn cigarettes (HNBC), which have recently become popular among smokers, generate less oxidative state than CC in smokers with a long smoking history. However, no previous study has examined oxidative state in young HNBC users. Previously, we reported that exercise induces a greater oxidative state in young CC smokers than in never-smokers of similar age, but there was no difference in resting oxidative state. This study aimed to clarify the resting and exercise-induced oxidative states in young HNBC users, compared with those in never-smokers and CC users of similar age. METHODS: Healthy young never-smokers, HNBC users, and CC users were recruited, and they underwent the Wingate anaerobic test. Blood samples were collected before and after exercise, and the plasma hydroperoxide concentration, a marker of oxidative state, was measured. RESULTS: No significant differences in pre-exercise plasma hydroperoxide concentrations were detected among never-smokers, HNBC users, and CC users (n = 10 each). Plasma hydroperoxide concentration was significantly increased after exercise in all participants. The exercise induced a significant increase in plasma hydroperoxide concentration in HNBC users compared with that in never-smokers (P < .005), but it was significantly decreased compared with that in CC users (P < .01). CONCLUSIONS: The use of HNBC increased exercise-induced plasma oxidative state compared with that in never-smokers, indicating that HNBC may lead to the risk of oxidative damage. IMPLICATIONS: This study, for the first time, reports exercise-induced oxidative state in young heat-not-burn cigarette users compared with never-smokers and conventional cigarette users. The exercise-induced oxidative state in heat-not-burn cigarette users was higher than that in never-smokers and lower than that in conventional cigarette users. Our study suggests that the use of heat-not-burn cigarettes increases the risk of acute oxidative damage.
