Calculation of thermal physical parameters of dissociated air by the dissociation degree method

The high temperature gas occurs behind shock or near the wall surface of vehicle in the hypersonic flight. As the temperature exceeds 2 000 K, 4 000 K, respectively, O2 and N2 molecules are successively dissociated. Because of variable components at dif- ferent temperatures and pressures, the dissociated air is no longer a perfect gas, In this paper, a new method is developed to calculate accurate thermal physical parameters with the dissociation degree providing the thermochemical equilibrium procedure. Based on the dissociation degree, it is concluded that few numbers of equations and the solutions are easily obtained. In addition, a set of formulas relating the parameter to the dissociation degree are set up four-species, O2 molecule The thermodynamic properties of dissociated air containing and N2 molecule, O atom and N atom, are studied with the new method, and the results are consistent with those with the traditional equilibrium constant method. It is shown that this method is reliable for solving thermal physical parameters easily and directly.

Spatial multi-omics characterizes GPR35-relevant lipid metabolism signatures across liver zonation in MASLD

Metabolic dysfunction-associated steatotic liver disease(MASLD)is a metabolic disease that can progress to metabolic dysfunction-associated steatohepatitis(MASH),cirrhosis,and cancer.The zonal distribution of biomolecules in the liver is implicated in mediat-ing the disease progression.Recently,G-protein-coupled receptor 35(GPR35)has been highlighted to play a role in MASLD,but the precise mechanism is not fully understood,particularly,in a liver-zonal manner.Here,we aimed to identify spatially distributed specific genes and metabolites in different liver zonation that are regulated by GPR35 in MASLD,by combining lipid metabolomics,spatial transcriptomics(ST),and spatial metabolomics(SM).We found that GPR35 influenced lipid accumulation,inflammatory and metabolism-related factors in specific regions,notably affecting the anti-inflammation factor ELF4(E74 like E-twenty six(ETS)tran-scription factor 4),lipid homeostasis key factor CIDEA(cell death-inducing DNA fragmentation factor alpha(DFFA)-like effector A),and the injury response-related genes SAA1/2/3(serum amyloid A1/2/3),thereby impacting MASLD progression.Furthermore,SM elucidated specific metabolite distributions across different liver regions,such as C10H11N4O7P(3ʹ,5ʹ-cyclic inosine monophosphate(3ʹ,5ʹ-IMP))for the central vein,and this metabolite significantly decreased in the liver zones of GPR35-deficient mice during MASLD progression.Taken together,GPR35 regulates hepatocyte damage repair,controls inflammation,and prevents MASLD progression by influencing phospholipid homeostasis and gene expression in a zonal manner.