Did carbon emission trading scheme improve energy use in China? An integrated approach based on SCM and threshold regression.

The analysis of energy use not only sheds light on lightening the increasing pressures from energy systems but also improves the flexibility and reliability of power systems. As the highest carbon emission country in the world, detailed evaluation of China's carbon emission trading scheme (ETS) on the energy use is sensitive to energy sectors and highlights the importance of energy utilization in current society. Yet, because of the presence of a possible discontinuity caused by policy implementation, this study uses synthetic control method (SCM) to confirm whether there is a cutoff for energy use after the ETS implementation. Furthermore, threshold regression model is integrated to estimate the causal relationship when there is a discontinuity. SCM is used to verify which has caused the discontinuity for threshold regression model, and threshold regression model is used to quantify and estimate the causal relationship which SCM cannot evaluate. Through the data analysis, it is found that ETS makes effect on energy use deduction in most of pilot ETS regions while the effect is affected by economic development, population, industry, and research. Some suggestions on how to reduce energy use conclude this paper.

Theoretical Analysis of Stacking Fault Energy, Elastic Properties, Electronic Properties, and Work Function of MnxCoCrFeNi High-Entropy Alloy.

The effects of different Mn concentrations on the generalized stacking fault energies (GSFE) and elastic properties of MnxCoCrFeNi high-entropy alloys (HEAs) have been studied via first-principles, which are based on density functional theory. The relationship of different Mn concentrations with the chemical bond and surface activity of MnxCoCrFeNi HEAs are discussed from the perspectives of electronic structure and work function. The results show that the plastic deformation of MnxCoCrFeNi HEAs can be controlled via dislocation-mediated slip. But with the increase in Mn concentration, mechanical micro twinning can still be formed. The deformation resistance, shear resistance, and stiffness of MnxCoCrFeNi HEAs increase with the enhancement of Mn content. Accordingly, in the case of increased Mn concentration, the weakening of atomic bonds in MnxCoCrFeNi HEAs leads to the increase in alloy instability, which improves the possibility of dislocation.

Molecular dynamics study on structural modulation and dyeing property optimization of meta-aramid in a DMSO/electrolyte system.

Meta-aramid (PMIA) fabrics are typically problematic to dye owing to their extremely crystalline structure and high compactness. Herein, Dimethyl sulfoxide (DMSO) and electrolyte as hydrogen bond regulators were selected to improve the dyeability of PIMA dyed with cationic dyes. The PMIA shows both high dyeing and mechanical properties as a result of the synergistic effect of DMSO and electrolyte in the system, which destructs hydrogen bonding networks and increase interaction energy density between dye molecules and PMIA, confirmed by a series of characterization and molecular dynamics simulations. In the DMSO/NaCl/PMIA system, while maintaining excellent mechanical (breaking strength and elongation at break of 24.6Mpa and 37.6 %, respectively) and thermal properties, PMIA not only obtained the best dyeability, increasing the Dye uptake from 20 % to 70.62 % and the K/S value from 2.92 to 18.02, but also achieved excellent colour fastness (fastness to dry and wet rubbing, fastness to light, and fastness to washing of 4-5, 3-4, 3-4 and 4-5, respectively). Simulated results and experimental data verified that the DMSO/NaCl system optimally synergizes hydrogen bond regulation for PMIA and achieves the best dyeing effects for cationic dyes, manifesting its great potential in the PMIA wearability area.

Exploration of D022-Type Al3TM(TM = Sc, Ti, V, Zr, Nb, Hf, Ta): Elastic Anisotropy, Electronic Structures, Work Function and Experimental Design.

The structural properties, elastic anisotropy, electronic structures and work function of D022-type Al3TM (TM = Sc, Ti, V, Y, Zr, Nb, La, Hf, Ta) are studied using the first-principles calculations. The results indicate that the obtained formation enthalpy and cohesive energy of these compounds are in accordance with the other calculated values. It is found that the Al3Zr is the most thermodynamic stable compound. The mechanical property indexes, such as elastic constants, bulk modulus, shear modulus, Young's modulus, Poisson's ratio, and Vickers hardness are systematically explored. Moreover, the calculated universal anisotropic index, percent anisotropy and shear anisotropic factors of D022-type Al3TM are analyzed carefully. It demonstrates that the shear modulus anisotropy of Al3La is the strongest, while that of Al3Ta is the weakest. In particular, the density of states at Fermi level is not zero, suggesting that these phases have metal properties and electrical conductivity. More importantly, the mechanisms of correlation between hardness and Young's modulus are further explained by the work function. Finally, the experimental design proves that D022-Al3Ta has an excellent strengthening effect.

Investigation on Mg3Sb2/Mg2Si Heterogeneous Nucleation Interface Using Density Functional Theory.

In this study, the cohesive energy, interfacial energy, electronic structure, and bonding of Mg2Si (111)/Mg3Sb2 (0001) were investigated by using the first-principles method based on density functional theory. Meanwhile, the mechanism of the Mg3Sb2 heterogeneous nucleation potency on Mg2Si grains was revealed. The results indicated that the Mg3Sb2 (0001) slab and the Mg2Si (111) slab achieved bulk-like characteristics when the atomic layers N ≥ 11, and the work of adhesion of the hollow-site (HCP) stacking structure (the interfacial Sb atom located on top of the Si atom in the second layer of Mg2Si) was larger than that of the other stacking structures. For the four HCP stacking structures, the Sb-terminated Mg3Sb2/Si-terminated Mg2Si interface with a hollow site showed the largest work of adhesion and the smallest interfacial energy, which implied the strongest stability among 12 different interface models. In addition, the difference in the charge density and the partial density of states indicated that the electronic structure of the Si-HCP-Sb interface presented a strong covalent, and the bonding of the Si-HCP-Mg interface and the Mg-HCP-Sb interface was a mixture of a covalent bond and a metallic bond, while the Mg-HCP-Mg interfacial bonding corresponded to metallicity. As a result, the Mg2Si was conducive to form a nucleus on the Sb-terminated-hollow-site Mg3Sb2 (0001) surface, and the Mg3Sb2 particles promoted the Mg2Si heterogeneous nucleation, which was consistent with the experimental expectations.