The half-metallic Heusler alloy CO_(2)FeSi is an ideal material in spintronic devices due to its higher spin polarization,higher Curie temperature and lower damping parameters.In this work,the dynamic magnetism of CO_...The half-metallic Heusler alloy CO_(2)FeSi is an ideal material in spintronic devices due to its higher spin polarization,higher Curie temperature and lower damping parameters.In this work,the dynamic magnetism of CO_(2)FeSi is modulated by electric field and it is demonstrated that the charge-spin conversion efficiencyξis continuous and controllable by the electric field.We further find an extremely highξin ferromagnetic/ferroelectric(FM/FE)heterostructures,which could be ascribed to interfacial effect in FM/FE interface.Moreover,we investigate that the charge-spin conversion efficiency varies with the electric field in a butterfly-like behavior,which accords with the S–E curve of Pb(Mg_(1/3)Nb_(2/3))O_3-Pb_(0.7)Ti_(0.3)O_(3)(PMN-PT)and could be attributed to strain effect.The modulation of charge-spin conversion efficiency in FM/FE heterostructures via electric field presents a profound potential for next-generation spintronic devices and applications of current-induced magnetization switching.展开更多
The temperature-dependent Gilbert damping in Co2FeAl thin film grown on a Pb(Mg1/3Nb2/3)O3-30%PbTiO3 substrate is investigated by the systematic measurement of physical property measurement system(PPMS) on a series of...The temperature-dependent Gilbert damping in Co2FeAl thin film grown on a Pb(Mg1/3Nb2/3)O3-30%PbTiO3 substrate is investigated by the systematic measurement of physical property measurement system(PPMS) on a series of samples with different substrate temperatures. Varying the substrate temperatures from 350℃ to 500℃, the B2 ordering degrees of Co2FeAl thin films increase, which can lead the Gilbert damping to decrease, indicated by the field-sweep in-plane PPMS measurements. In addition, the measurement result of PPMS demonstrates that the Gilbert damping decreases first with measurement temperature decreasing down to about 150 K, then increases at a measurement temperature of ~ 50 K, and decreases again with the measurement temperature decreasing. There are two independent damping manners, namely bulk damping and surface damping, which contribute to the Gilbert damping. Moreover, the observed peak of Gilbert damping at ~ 50 K can be attributed to the spin re-orientation transition at the Co2FeAl surface, which is similar to the result of the effective magnetization as a function of measurement temperature. The result presents the evidence for further studying the Gilbert damping in Co2FeAl thin film.展开更多
We report that the ferromagnetic resonance(FMR)response of the CoFeB/HfO2 heterostructures is stabilized and reversibly manipulated by ionic gel.Ionic gel with excellent flexibility is used as a medium to form an elec...We report that the ferromagnetic resonance(FMR)response of the CoFeB/HfO2 heterostructures is stabilized and reversibly manipulated by ionic gel.Ionic gel with excellent flexibility is used as a medium to form an electric field.When a 4 V gate voltage is applied,the resonance field Hr and peak-to-peak linewidthΔHpp at different angles are regulated.Whenθ=20°,the Hr is regulated up to 82 Oe.Whenθ=70°,ΔHpp is tuned up to 75 Oe.When the gate voltage is repeatedly applied,the FMR spectra can be freely switched between the initial state and the gated state.Our study provides an effective method to manipulate the damping of the magnetic film stably and reversibly.展开更多
基金the National Natural Science Foundation of China(Grant No.11974149)the Natural Science Foundation of Gansu Province(Grant No.21JR7RA472)。
文摘The half-metallic Heusler alloy CO_(2)FeSi is an ideal material in spintronic devices due to its higher spin polarization,higher Curie temperature and lower damping parameters.In this work,the dynamic magnetism of CO_(2)FeSi is modulated by electric field and it is demonstrated that the charge-spin conversion efficiencyξis continuous and controllable by the electric field.We further find an extremely highξin ferromagnetic/ferroelectric(FM/FE)heterostructures,which could be ascribed to interfacial effect in FM/FE interface.Moreover,we investigate that the charge-spin conversion efficiency varies with the electric field in a butterfly-like behavior,which accords with the S–E curve of Pb(Mg_(1/3)Nb_(2/3))O_3-Pb_(0.7)Ti_(0.3)O_(3)(PMN-PT)and could be attributed to strain effect.The modulation of charge-spin conversion efficiency in FM/FE heterostructures via electric field presents a profound potential for next-generation spintronic devices and applications of current-induced magnetization switching.
基金Project supported by the National Natural Science Foundation of China(Grant Nos.51671099,11974149,and 51901163)the Program for Changjiang Scholars and Innovative Research Team in University,China(Grant No.IRT-16R35).
文摘The temperature-dependent Gilbert damping in Co2FeAl thin film grown on a Pb(Mg1/3Nb2/3)O3-30%PbTiO3 substrate is investigated by the systematic measurement of physical property measurement system(PPMS) on a series of samples with different substrate temperatures. Varying the substrate temperatures from 350℃ to 500℃, the B2 ordering degrees of Co2FeAl thin films increase, which can lead the Gilbert damping to decrease, indicated by the field-sweep in-plane PPMS measurements. In addition, the measurement result of PPMS demonstrates that the Gilbert damping decreases first with measurement temperature decreasing down to about 150 K, then increases at a measurement temperature of ~ 50 K, and decreases again with the measurement temperature decreasing. There are two independent damping manners, namely bulk damping and surface damping, which contribute to the Gilbert damping. Moreover, the observed peak of Gilbert damping at ~ 50 K can be attributed to the spin re-orientation transition at the Co2FeAl surface, which is similar to the result of the effective magnetization as a function of measurement temperature. The result presents the evidence for further studying the Gilbert damping in Co2FeAl thin film.
基金the National Natural Science Foundation of China(Grant Nos.51671099 and 11974149)the Open Foundation Project of Jiangsu Key Laboratory of Thin Films(Grant No.KJS1745)+1 种基金the Program for Changjiang Scholars and Innovative Research Team in University(Grant No.IRT-16R35)the Fundamental Research Funds for the Central Universities。
文摘We report that the ferromagnetic resonance(FMR)response of the CoFeB/HfO2 heterostructures is stabilized and reversibly manipulated by ionic gel.Ionic gel with excellent flexibility is used as a medium to form an electric field.When a 4 V gate voltage is applied,the resonance field Hr and peak-to-peak linewidthΔHpp at different angles are regulated.Whenθ=20°,the Hr is regulated up to 82 Oe.Whenθ=70°,ΔHpp is tuned up to 75 Oe.When the gate voltage is repeatedly applied,the FMR spectra can be freely switched between the initial state and the gated state.Our study provides an effective method to manipulate the damping of the magnetic film stably and reversibly.
