Heat transfer enhanced inorganic phase change material compositing carbon nanotubes for battery thermal management and thermal runaway propagation mitigation

Developing technologies that can be applied simultaneously in battery thermal management(BTM)and thermal runaway(TR)mitigation is significant to improving the safety of lithium-ion battery systems.Inorganic phase change material(PCM)with nonflammability has the potential to achieve this dual function.This study proposed an encapsulated inorganic phase change material(EPCM)with a heat transfer enhancement for battery systems,where Na_(2)HPO_(4)·12H_(2)O was used as the core PCM encapsulated by silica and the additive of carbon nanotube(CNT)was applied to enhance the thermal conductivity.The microstructure and thermal properties of the EPCM/CNT were analyzed by a series of characterization tests.Two different incorporating methods of CNT were compared and the proper CNT adding amount was also studied.After preparation,the battery thermal management performance and TR propagation mitigation effects of EPCM/CNT were further investigated on the battery modules.The experimental results of thermal management tests showed that EPCM/CNT not only slowed down the temperature rising of the module but also improved the temperature uniformity during normal operation.The peak battery temperature decreased from 76℃to 61.2℃at 2 C discharge rate and the temperature difference was controlled below 3℃.Moreover,the results of TR propagation tests demonstrated that nonflammable EPCM/CNT with good heat absorption could work as a TR barrier,which exhibited effective mitigation on TR and TR propagation.The trigger time of three cells was successfully delayed by 129,474 and 551 s,respectively and the propagation intervals were greatly extended as well.

Constructing the bonding between conductive agents and active materials/binders stabilizes silicon anode in Lithium-ion batteries

Silicon(Si)anode has been considered a promising candidate due to its remarkable theoretical capacity but it was plagued by severe pulverization because of the inherent huge volume variation.Enhancing electrode stability is an effective approach to improve electrochemical performance.Herein,a stable Si anode was established by an innovative construction of the bonding between conductive agents and active materials/binders.As a result,the strong interaction of electrode components not only effectively alleviates the volume expansion of Si but also achieves a stable interface by generating the beneficial solid electrolyte interphase(SEI)composition.Attributed to the deliberate scheme of the electrode,the Si anode exhibits sterling electrochemical performance.Besides,the device of the electrode is not only effective for other binders but also for other anode materials with high volume variation,thus shedding light on the rational design of electrodes for high-energy-density lithium-ion batteries.

Robust Genetic Diagnosis of Split Hand–Foot Malformation by Exome Sequencing

Purpose The present study aimed to evaluate the genetic diagnostic yield and accuracy of exome sequencing in Chinese patients with split hand–foot malformation(SHFM),a severe heterogeneous congenital anomaly characterized by hypodevelopment of the central ray of the hands and feet.Methods A cohort of seven families and five sporadic patients with SHFM was investigated.Genomic DNA was prepared from the peripheral blood of affected as well as unaffected individuals.Whole exome sequencing(WES)was performed to identify the pathogenic mutations.Array-based comparative genomic hybridization(aCGH),CytoScan,quantitative polymerase chain reaction(qPCR),and Sanger sequencing were performed to validate the findings of WES.WES data of an additional cohort of 24 patients with non-SHFM congenital hand anomalies were analyzed as the control.Results Pathogenic variants of TP63,c.G956A p.R319H,and c.T602A:p.L201H,were identified in two families by WES.In the remaining patients,copy number analysis of the WES data by XHMM software identified pathogenic 10q 24 duplication in five individuals from three families,which was further validated via CytoScan and qPCR;however,WES could not detect duplication in 10q24 in an additional cohort of 24 individuals with non-SHFM congenital hand anomaly.Importantly,qPCR analysis of the 10q24 region copy number revealed a definite consistency with WES data in all individuals.Genotype–phenotype analysis did not present any unique feature that could differentiate between the families with TP63 mutation and 10q24 duplication.Conclusions Our study demonstrated that WES is an accurate and sensitive method to detect the pathogenic 10q24 duplication.Collectively,with TP63 mutation,a single WES testing could yield a diagnosis rate of about 40%(5/12)for the SHFM patients,at least in our cohort.As the genotype–phenotype correlation remains unclear,WES could be used as a cost-effective method for the genetic diagnosis of SHFM.

Dicarboxylate CaC8H4O4 as a high-performance anode for Li-ion batteries

Currently, many organic materials are being considered as electrode materials and display good electrochemical behavior. However, the most critical issues related to the wide use of organic electrodes are their low thermal stability and poor cycling performance due to their high solubility in electrolytes. Focusing on one of the most conventional carboxylate organic materials, namely lithium terephthalate Li2CsH4O4, we tackle these typical disadvantages via modifying its molecular structure by cation substitution. CaCsH4O4 and A12（C8H4O4）3 are prepared via a facile cation exchange reaction. Of these, CaCsH4O4 presents the best cycling performance with thermal stability up to 570℃ and capacity of 399 mA.h.g-1, without any capacity decay in the voltage window of 0.005-3.0 V. The molecular, crystal structure, and morphology of CaCsH4O4 are retained during cycling. This cation-substitution strategy brings new perspectives in the synthesis of new materials as well as broadening the applications of organic materials in Li/Na-ion batteries.

Advances and challenges in thermal runaway modeling of lithium-ion batteries

The broader application of lithium-ion batteries(LIBs)is constrained by safety concerns arising from thermal runaway(TR).Accurate prediction of TR is essential to comprehend its underlying mechanisms,expedite battery design,and enhance safety protocols,thereby significantly promoting the safer use of LIBs.The complex,nonlinear nature of LIB systems presents substantial challenges in TR modeling,stemming from the need to address multiscale simulations,multiphysics coupling,and computing efficiency issues.This paper provides an extensive review and outlook on TR modeling technologies,focusing on recent advances,current challenges,and potential future directions.We begin with an overview of the evolutionary processes and underlying mechanisms of TR from multiscale perspectives,laying the foundation for TR modeling.Following a comprehensive understanding of TR phenomena and mechanisms,we introduce a multiphysics coupling model framework to encapsulate these aspects.Within this framework,we detail four fundamental physics modeling approaches:thermal,electrical,mechanical,and fluid dynamic models,highlighting the primary challenges in developing and integrating these models.To address the intrinsic trade-off between computational accuracy and efficiency,we discuss several promising modeling strategies to accelerate TR simulations and explore the role of AI in advancing next-generation TR models.Last,we discuss challenges related to data availability,model scalability,and safety standards and regulations.