We have entered an era of rapid advances in neuroscience.The integration of innovative imaging technology,validated behavioral measures,and state-of-the-art algorithms is gradually unraveling the fundamental rules tha...We have entered an era of rapid advances in neuroscience.The integration of innovative imaging technology,validated behavioral measures,and state-of-the-art algorithms is gradually unraveling the fundamental rules that link the nervous system and complex behaviors,subsequently guiding diagnostics and therapeutics.However,there is a long history of an explicit lack of population diversity in neuroscience research.Although most influential studies in our field aim to elucidate universal and objective truths,it is disconcerting that the Western,educated,industrialized,rich,and democratic(WEIRD)populations are overrepresented[1].展开更多
The lattice Boltzmann Peierls Callaway(LBPC)method is a recent development of the versatile lattice Boltzmann formalism aimed at a numerical experiment on mesoscale thermal transport in a multiphase phonon gas.Two asp...The lattice Boltzmann Peierls Callaway(LBPC)method is a recent development of the versatile lattice Boltzmann formalism aimed at a numerical experiment on mesoscale thermal transport in a multiphase phonon gas.Two aspects of mesoscopic thermal trans-port are discussed:the finite phonon mean free path and the interface thermal resistance.Based on the phonon momentum screening length measured in the LBPC computa-tional apparatus,the validity of the Umklapp collision relaxation time in the Callaway collision operator is examined quantitatively.The discrete nature of the spatio-temporal domain in the LBPC method,along with the linear approximation of the exponential screening mechanism in the Callaway operator,reveals a large discrepancy between the effective phonon mean free path and the analytic phonon mean free path when the relaxation time is small.The link bounce back interface phonon collision rule is used to realize the interface thermal resistance between phonon gases with dissimilar dispersion relations.Consistent with the Callaway collision operator for the bulk phonon dynam-ics,the interface phonon collision process is regarded as a linear relaxation mechanism toward the local pseudo-equilibrium phonon distribution uniquely defined by the energy conservation principle.The interface thermal resistance is linearly proportional to the relaxation time of the proposed phonon interface collision rule.展开更多
基金supported by the National Natural Science Foundation of China(62336002 and 82302175)the National Science and Technology Innovation 2030 Program(2021ZD0200500)Xi-Nian Zuo is supported by the Start-up Funds for Leading Talents at Beijing Normal University.
文摘We have entered an era of rapid advances in neuroscience.The integration of innovative imaging technology,validated behavioral measures,and state-of-the-art algorithms is gradually unraveling the fundamental rules that link the nervous system and complex behaviors,subsequently guiding diagnostics and therapeutics.However,there is a long history of an explicit lack of population diversity in neuroscience research.Although most influential studies in our field aim to elucidate universal and objective truths,it is disconcerting that the Western,educated,industrialized,rich,and democratic(WEIRD)populations are overrepresented[1].
文摘The lattice Boltzmann Peierls Callaway(LBPC)method is a recent development of the versatile lattice Boltzmann formalism aimed at a numerical experiment on mesoscale thermal transport in a multiphase phonon gas.Two aspects of mesoscopic thermal trans-port are discussed:the finite phonon mean free path and the interface thermal resistance.Based on the phonon momentum screening length measured in the LBPC computa-tional apparatus,the validity of the Umklapp collision relaxation time in the Callaway collision operator is examined quantitatively.The discrete nature of the spatio-temporal domain in the LBPC method,along with the linear approximation of the exponential screening mechanism in the Callaway operator,reveals a large discrepancy between the effective phonon mean free path and the analytic phonon mean free path when the relaxation time is small.The link bounce back interface phonon collision rule is used to realize the interface thermal resistance between phonon gases with dissimilar dispersion relations.Consistent with the Callaway collision operator for the bulk phonon dynam-ics,the interface phonon collision process is regarded as a linear relaxation mechanism toward the local pseudo-equilibrium phonon distribution uniquely defined by the energy conservation principle.The interface thermal resistance is linearly proportional to the relaxation time of the proposed phonon interface collision rule.
