The physical effects on surface and flexoelectric polarization in a weak anchoring nematic liquid crystal cell are investigated systematically. We derive the analytic expressions of two effective anchoring energies fo...The physical effects on surface and flexoelectric polarization in a weak anchoring nematic liquid crystal cell are investigated systematically. We derive the analytic expressions of two effective anchoring energies for lower and upper substrates respectively as well as their effective anchoring strengths and corresponding tilt angles of effective easy direction.All of these quantities are relevant to the magnitudes of both two polarizations and the applied voltage U. Based on these expressions, the variations of effective anchoring strength and the tilt angle with the applied voltage are calculated for the fixed values of two polarizations. For an original weak anchoring hybrid aligned nematic cell, it may be equivalent to a planar cell for a small value of U and has a threshold voltage. The variation of reduced threshold voltage with reduced surface polarization strength is also calculated. The role of surface polarization is important without the adsorptive ions considered.展开更多
The risk of flammability is an unavoidable issue for gel polymer electrolytes(GPEs).Usually,flameretardant solvents are necessary to be used,but most of them would react with anode/cathode easily and cause serious int...The risk of flammability is an unavoidable issue for gel polymer electrolytes(GPEs).Usually,flameretardant solvents are necessary to be used,but most of them would react with anode/cathode easily and cause serious interfacial instability,which is a big challenge for design and application of nonflammable GPEs.Here,a nonflammable GPE(SGPE)is developed by in situ polymerizing trifluoroethyl methacrylate(TFMA)monomers with flame-retardant triethyl phosphate(TEP)solvents and LiTFSI–LiDFOB dual lithium salts.TEP is strongly anchored to PTFMA matrix via polarity interaction between-P=O and-CH_(2)CF_(3).It reduces free TEP molecules,which obviously mitigates interfacial reactions,and enhances flame-retardant performance of TEP surprisingly.Anchored TEP molecules are also inhibited in solvation of Li^(+),leading to anion-dominated solvation sheath,which creates inorganic-rich solid electrolyte interface/cathode electrolyte interface layers.Such coordination structure changes Li^(+)transport from sluggish vehicular to fast structural transport,raising ionic conductivity to 1.03 mS cm^(-1) and transfer number to 0.41 at 30℃.The Li|SGPE|Li cell presents highly reversible Li stripping/plating performance for over 1000 h at 0.1 mA cm^(−2),and 4.2 V LiCoO_(2)|SGPE|Li battery delivers high average specific capacity>120 mAh g^(−1) over 200 cycles.This study paves a new way to make nonflammable GPE that is compatible with Li metal anode.展开更多
The reversibility and stability of aqueous Zn metal batteries(AZMBs)are largely limited by Zn dendrites and interfacial parasitic reactions.Herein,we propose a parallel modulation strategy to boost the reversibility o...The reversibility and stability of aqueous Zn metal batteries(AZMBs)are largely limited by Zn dendrites and interfacial parasitic reactions.Herein,we propose a parallel modulation strategy to boost the reversibility of the Zn anode by introducing N,N,N',N'-tetramethylchloroformamidinium hexafluorophosphate(TCFH)as an additive in the electrolyte.TCFH is composed of PF6-and TN+with opposite charges.PF6-can spontaneously induce the in-situ generation of ZnF_(2)solid electrolyte interface(SEI)on the anode,which can improve the transport kinetics of Zn^(2+)at the interface,thus promoting the rapid and uniform deposition of Zn as well as inhibiting the growth of dendrites.In addition,TN+is enriched at the anode surface during Zn deposition through the anchoring effect,which brings a reconfiguration of the ion/molecule distribution.The anchored-TN+reduces the concentrations of H_(2)O and SO_(4)^(2-),sufficiently restraining the parasitic reaction.Thanks to the dual-phase interface engineering constructed of PF6-and TN+in parallel,the symmetric cell with the proposed electrolyte survives long cycling stability over750 h at 20 mA cm^(-2),10 mAh cm^(-2).This study offers a distinct viewpoint to the multidimensional optimization of Zn anodes for high-performance AZMBs.展开更多
Oxygen vacancies(Ov)within metal oxide electrodes can enhance mass/charge transfer dynamics in energy storage systems.However,construction of surface Ovoften leads to instability in electrode structure and irreversibl...Oxygen vacancies(Ov)within metal oxide electrodes can enhance mass/charge transfer dynamics in energy storage systems.However,construction of surface Ovoften leads to instability in electrode structure and irreversible electrochemical reactions,posing a significant challenge.To overcome these challenges,atomic heterostructures are employed to address the structural instability and enhance the mass/charge transfer dynamics associated with phase conversion mechanism in aqueous electrodes,Herein,we introduce an atomic S-Bi_(2)O_(3)heterostructure(sulfur(S)anchoring on the surface Ovof Bi_(2)O_(3)).The integration of S within Bi_(2)O_(3)lattice matrix triggers a charge imbala nce at the heterointerfaces,ultimately resulting in the creation of a built-in electric field(BEF).Thus,the BEF attracts OH-ions to be adsorbed onto Bi within the regions of high electron cloud overlap in S-Bi_(2)O_(3),facilitating highly efficient charge transfer.Furthermore,the anchored S plays a pivotal role in preserving structural integrity,thus effectively stabilizing the phase conversion reaction of Bi_(2)O_(3).As a result,the S-Bi_(2)O_(3)electrode achieves72.3 mA h g^(-1)at 10 A g^(-1)as well as high-capacity retention of 81.9%after 1600 cycles.Our innovative SBi_(2)O_(3)design presents a groundbreaking approach for fabricating electrodes that exhibit efficient and stable mass and charge transfer capabilities.Furthermore,it enhances our understanding of the underlying reaction mechanism within energy storage electrodes.展开更多
Motivated by our recent work,in this work,we present the numerical study of the anchoring effect on the Frederiks threshold field in a nematic liquid crystal doped with ferroelectric colloidal nanoparticles.Assuming w...Motivated by our recent work,in this work,we present the numerical study of the anchoring effect on the Frederiks threshold field in a nematic liquid crystal doped with ferroelectric colloidal nanoparticles.Assuming weak anchoring conditions,we employ the relaxation method and Maxwell construction to numerically solve the Euler–Lagrangian differential equation for the total free energy together the Rapini–Papoular surface energy to take into account anchoring of nematic liquid crystal molecules at the substrates.In this study,we focus our attention on obtaining the phase diagrams of Frederiks transition for different values of anchoring strength which have been not computed in our previous work.In this way,the effect of nanoparticle radius,nanoparticle volume fraction,nanoparticle polarization,and cell thickness on the Frederiks transition for different values of anchoring conditions are summarized in the phase diagrams.The numerical results show that by increasing the nanoparticles size and nanoparticle volume fraction in the ferronematic system,the Frederiks threshold field is strongly reduced.展开更多
基金Project supported by the National Natural Science Foundation of China(Grant Nos.11274088,11374087,and11304074)the Natural Science Foundation of Hebei Province,China(Grant No.A2014202123)+1 种基金the Research Project of Hebei Provincial Education Department,China(Grant No.QN2014130)the Key Subject Construction Project of Hebei Provincial University,China
文摘The physical effects on surface and flexoelectric polarization in a weak anchoring nematic liquid crystal cell are investigated systematically. We derive the analytic expressions of two effective anchoring energies for lower and upper substrates respectively as well as their effective anchoring strengths and corresponding tilt angles of effective easy direction.All of these quantities are relevant to the magnitudes of both two polarizations and the applied voltage U. Based on these expressions, the variations of effective anchoring strength and the tilt angle with the applied voltage are calculated for the fixed values of two polarizations. For an original weak anchoring hybrid aligned nematic cell, it may be equivalent to a planar cell for a small value of U and has a threshold voltage. The variation of reduced threshold voltage with reduced surface polarization strength is also calculated. The role of surface polarization is important without the adsorptive ions considered.
基金supported by the National Natural Science Foundation of China(Nos.52172214,52272221,52171182)the Postdoctoral Innovation Project of Shandong Province(No.202102003)+2 种基金The Key Research and Development Program of Shandong Province(2021ZLGX01)the Qilu Young Scholar ProgramHPC Cloud Platform of Shandong University are also thanked.
文摘The risk of flammability is an unavoidable issue for gel polymer electrolytes(GPEs).Usually,flameretardant solvents are necessary to be used,but most of them would react with anode/cathode easily and cause serious interfacial instability,which is a big challenge for design and application of nonflammable GPEs.Here,a nonflammable GPE(SGPE)is developed by in situ polymerizing trifluoroethyl methacrylate(TFMA)monomers with flame-retardant triethyl phosphate(TEP)solvents and LiTFSI–LiDFOB dual lithium salts.TEP is strongly anchored to PTFMA matrix via polarity interaction between-P=O and-CH_(2)CF_(3).It reduces free TEP molecules,which obviously mitigates interfacial reactions,and enhances flame-retardant performance of TEP surprisingly.Anchored TEP molecules are also inhibited in solvation of Li^(+),leading to anion-dominated solvation sheath,which creates inorganic-rich solid electrolyte interface/cathode electrolyte interface layers.Such coordination structure changes Li^(+)transport from sluggish vehicular to fast structural transport,raising ionic conductivity to 1.03 mS cm^(-1) and transfer number to 0.41 at 30℃.The Li|SGPE|Li cell presents highly reversible Li stripping/plating performance for over 1000 h at 0.1 mA cm^(−2),and 4.2 V LiCoO_(2)|SGPE|Li battery delivers high average specific capacity>120 mAh g^(−1) over 200 cycles.This study paves a new way to make nonflammable GPE that is compatible with Li metal anode.
基金financially supported by the National Natural Science Foundation of China(52172159)the Postdoctoral Fellowship Program of CPSF(GZB20230631).
文摘The reversibility and stability of aqueous Zn metal batteries(AZMBs)are largely limited by Zn dendrites and interfacial parasitic reactions.Herein,we propose a parallel modulation strategy to boost the reversibility of the Zn anode by introducing N,N,N',N'-tetramethylchloroformamidinium hexafluorophosphate(TCFH)as an additive in the electrolyte.TCFH is composed of PF6-and TN+with opposite charges.PF6-can spontaneously induce the in-situ generation of ZnF_(2)solid electrolyte interface(SEI)on the anode,which can improve the transport kinetics of Zn^(2+)at the interface,thus promoting the rapid and uniform deposition of Zn as well as inhibiting the growth of dendrites.In addition,TN+is enriched at the anode surface during Zn deposition through the anchoring effect,which brings a reconfiguration of the ion/molecule distribution.The anchored-TN+reduces the concentrations of H_(2)O and SO_(4)^(2-),sufficiently restraining the parasitic reaction.Thanks to the dual-phase interface engineering constructed of PF6-and TN+in parallel,the symmetric cell with the proposed electrolyte survives long cycling stability over750 h at 20 mA cm^(-2),10 mAh cm^(-2).This study offers a distinct viewpoint to the multidimensional optimization of Zn anodes for high-performance AZMBs.
基金supported by the Research Program of Jilin Province Development and Reform Commission(2024C018-6).
文摘Oxygen vacancies(Ov)within metal oxide electrodes can enhance mass/charge transfer dynamics in energy storage systems.However,construction of surface Ovoften leads to instability in electrode structure and irreversible electrochemical reactions,posing a significant challenge.To overcome these challenges,atomic heterostructures are employed to address the structural instability and enhance the mass/charge transfer dynamics associated with phase conversion mechanism in aqueous electrodes,Herein,we introduce an atomic S-Bi_(2)O_(3)heterostructure(sulfur(S)anchoring on the surface Ovof Bi_(2)O_(3)).The integration of S within Bi_(2)O_(3)lattice matrix triggers a charge imbala nce at the heterointerfaces,ultimately resulting in the creation of a built-in electric field(BEF).Thus,the BEF attracts OH-ions to be adsorbed onto Bi within the regions of high electron cloud overlap in S-Bi_(2)O_(3),facilitating highly efficient charge transfer.Furthermore,the anchored S plays a pivotal role in preserving structural integrity,thus effectively stabilizing the phase conversion reaction of Bi_(2)O_(3).As a result,the S-Bi_(2)O_(3)electrode achieves72.3 mA h g^(-1)at 10 A g^(-1)as well as high-capacity retention of 81.9%after 1600 cycles.Our innovative SBi_(2)O_(3)design presents a groundbreaking approach for fabricating electrodes that exhibit efficient and stable mass and charge transfer capabilities.Furthermore,it enhances our understanding of the underlying reaction mechanism within energy storage electrodes.
基金the support of Shiraz University of Technology Research Council
文摘Motivated by our recent work,in this work,we present the numerical study of the anchoring effect on the Frederiks threshold field in a nematic liquid crystal doped with ferroelectric colloidal nanoparticles.Assuming weak anchoring conditions,we employ the relaxation method and Maxwell construction to numerically solve the Euler–Lagrangian differential equation for the total free energy together the Rapini–Papoular surface energy to take into account anchoring of nematic liquid crystal molecules at the substrates.In this study,we focus our attention on obtaining the phase diagrams of Frederiks transition for different values of anchoring strength which have been not computed in our previous work.In this way,the effect of nanoparticle radius,nanoparticle volume fraction,nanoparticle polarization,and cell thickness on the Frederiks transition for different values of anchoring conditions are summarized in the phase diagrams.The numerical results show that by increasing the nanoparticles size and nanoparticle volume fraction in the ferronematic system,the Frederiks threshold field is strongly reduced.
