Due to the complex composition, large fluctuation of material characteristics and low energy density of MSW, the gasification characteristics of its hydrochars are not well understood. Therefore, it is of great significance to study the gasification characteristics of single component hydrochars. In this paper, a typical component of MSW, disposable bamboo chopsticks (DBC), was used as raw material to study the effect of hydrothermal carbonization (HTC) conditions on the structural properties and gasification reaction characteristics of DBC hydrochars. The results showed that HTC improved the energy quality of DBC, the HHV of DBC-230-60 sample was 1.62 times of that of DBC, and H/C and O/C decreased from 1.57 and 0.76 of original sample to 1.00 and 0.33 of DBC-230-60. The results of characterization also demonstrate that the aromatization degree of hydrochar and hydrochar semicoke is higher than that of the DBC original one. The specific surface area of hydrochar is lower than that of DBC original sample, but hydrochar semicoke is higher than that of DBC original sample semicoke. Compared with hydrothermal time, hydrothermal temperature has the more significant effect on the structure and gasification reactivity of hydrochar. Higher hydrothermal temperature increases the aromatization degree of hydrochar and decreases the gasification reactivity of hydrochar. The gasification reactivity of hydrochar is worse than that of DBC original sample, which is mainly because the increase of the degree of semicoke arbulization of hydrochar has a greater negative effect on the gasification reactivity than the abundance of pore structure.

La0.5Sr0.5Co0.2Fe0.8O3 (LSCF) perovskite materials were prepared by hard template method with SBA-15 as the template in methanol and ethanol solvents and the electrochemical properties of LSCF were investigated. It is found that LSCF prepared with ethanol solvent has larger specific surface area and more oxygen vacancy concentration, which in turn exhibits higher electrical conductivity and better catalytic activity towards oxygen reduction reaction (ORR) and hydrogen oxidation reaction (HOR). This is because the LSCF prepared by the ethanol solvent has more Co2 + /Co3 + and Fe2 + /Fe3 + electron pairs, which promotes the electronic conduction of the material. In addition, for HOR, the rate determining step (RDS) is the transfer of adsorbed H to the reaction site, and for ORR, the RDS is the reduction of the adsorbed oxygen atom on LSCF. In addition, the reversible single-component cell (RSCC) composed of LSCF prepared by ethanol solvent shows better performance for discharge and water electrolysis. The maximum power density (Pmax) of the RSCC is 232.9 mW/m2, and the current density at 1.3 V is −398.3 mA/cm2 at 700 ℃.

In this paper, two-dimensional B/N co-doped porous carbon sheets (BNCSs) were prepared by one-step carbonization using glycine as carbon source and nitrogen source, boric acid as template and boron source. The boric acid template can be removed by water washing, and the synthesis method is green and environmentally friendly. The short pores in BNCSs shorten the transport distance of potassium ions, and the abundant micropores provide a large number of potassium storage active sites. In addition, the higher B/N doping in BNCSs increases the defect degree of carbon matrix, expands the carbon layer spacing, and is conducive to the adsorption, insertion and de-insertion of potassium ions. The measurement results of potassium ion half cell performance indicate that BNCS800 electrode shows high specific capacity (310 mA·h/g at 0.05 A/g), excellent rate performance (100 mA·h/g at 2 A/g) and good cycle stability (after 1000 cycles at 1 A/g, the capacity retention is 75.9%). This work provides a simple strategy for preparing cathode materials with high capacity and long life.

Zinc-zirconium oxide (ZnZr) was effectively coupled with HZSM-5 zeolite in this report. The effects of SiO2/Al2O3 ratio of HZSM-5 zeolite and Zn/Zr ratio on the performance of CO2 hydrogenation to C5+ isoalkanes over the composite catalyst were investigated, respectively. The results show that ZnZr-4/HZSM-5 prepared by SiO2/Al2O3 = 130 and Zn/Zr = 1∶5 manifests the optimal performance of CO2 hydrogenation to C5+ isoalkanes, with CO2 conversion of 17% and CO selectivity of 25%, as well as the selectivity of C5+ hydrocarbons and isoalkanes in C5+ hydrocarbons up to 60% and 89%. Moreover, ZnZr/HZSM-5 composite catalyst shows excellent stability with time on stream for 120 h without losing activity. A suitable coupling between ZnZr and HZSM-5 zeolite is critical for highly selective synthesis of C5+ isoalkanes by CO2 hydrogenation.

Ce0.8Cu0.2O2 oxygen carrier has excellent performance in chemical-looping reforming of methane coupled with CO2 reduction technology. Different mass of S-1 molecular sieve was added to Ce0.8Cu0.2O2 oxygen carrier. The physicochemical properties and reactivity of the carrier were characterized by XRD, BET, XPS, SEM, TEM and CH4-TPR & CO2-TPO. The effect of S-1 molecular sieve on the performance of Ce0.8Cu0.2O2 oxygen carrier in chemical-looping reforming of methane coupled with CO2 reduction was systematically investigated. Compared with Ce0.8Cu0.2O2 oxygen carrier alone, the specific surface area of the composite oxygen carrier increased from 15.44 to 73.27 m2/g after adding 0.3 g S-1 molecular sieve. At the same time, its thermal stability and structural stability were greatly improved. The CH4 conversion rate of composite oxygen carrier with 0.3 g S-1 molecular sieve increased from 38.93% to 56.03%, and the CO yield increased from 1.18 to 2.16 mmol/g during CO2 reduction.

CeO2-WO3 catalysts were successfully prepared by in-situ synthesis and used in the denitrification reaction. The best activity of CW-550 catalyst was achieved at a roasting temperature of 550 ℃, and the denitrification activity of CW-550 reached over 90% at 200 ℃. The superior catalytic performance of CW-550 catalyst can be attributed to the large specific surface area, more Ce3+ species, abundant surface acidity and superior redox performance. The increased Ce3+ facilitates the formation of oxygen vacancies and promotes redox performance. The introduction of WO3, into CeO2 can enhance the amounts of Brönsted acid, which contributes to the improvement of the adsorption and activation of ammonia, resulting in the excellent catalytic performance. The NH3-adsorbed species can react with gaseous NO. However, both of NH3-adsorbed and NO-adsorbed sepcies cannot participate in the SCR reaction effectively. Therefore, the SCR reaction of CW catalysts mainly follows the Eley-Rideal mechanism.