Phosphotungstic Acid as a Dechlorination Agent Collaborates with CeO2 for Synergistic Catalytic Elimination of NOx and Chlorobenzene.

The development of efficient technologies for the synergistic catalytic elimination of NOx and chlorinated volatile organic compounds (CVOCs) remains challenging. Chlorine species from CVOCs are prone to catalyst poisoning, which increases the degradation temperature of CVOCs and fails to balance the selective catalytic reduction of NOx with the NH3 (NH3-SCR) performance. Herein, synergistic catalytic elimination of NOx and chlorobenzene has been originally demonstrated by using phosphotungstic acid (HPW) as a dechlorination agent to collaborate with CeO2. The conversion of chlorobenzene was over 80% at 270 °C, and the NOx conversion and N2 selectivity reached over 95% at 270-420 °C. HPW not only allowed chlorine species to leave as inorganic chlorine but also enhanced the BroÌ·nsted acidity of CeO2. The NH4+ produced in the NH3-SCR process can effectively promote the dechlorination of chlorobenzene at low temperatures. HPW remained structurally stable in the synergistic reaction, resulting in good water resistance and long-term stability. This work provides a cheaper and more environmentally friendly strategy to address chlorine poisoning in the synergistic reaction and offers new guidance for multipollutant control.

Observations on the Therapeutic Efficacy of Biomimetic Physiotherapy Combined with Manipulation Therapy in Managing Myofascial Pelvic Pain Syndrome in Women.

Objective: This study aims to investigate the clinical efficacy of biomimetic physiotherapy combined with manipulation therapy in the management of female myofascial pelvic pain syndrome (MPPS). Methods: A total of 120 patients diagnosed with MPPS at our hospital from June 2018 to June 2021 were included. All patients had a history of sexual activity, met the diagnostic criteria for female chronic pelvic pain, and exhibited pelvic floor muscle and myofascial trigger points in gynecological examinations. Based on treatment methods, patients were categorized into a control group (n=64, treated with biomimetic physiotherapy) and an experimental group (n=56, treated with biomimetic physiotherapy plus manipulation therapy). Pre- and post-treatment assessments in both groups included pelvic floor muscle surface electromyogram, Visual Analogue Scale (VAS) score, pelvic floor muscle tenderness score, and pelvic floor muscle strength. Results: After treatment, the mean values of pre-resting potential and post-resting potential declined significantly, from (9.58±2.22) to (4.06±0.77) and from (8.18±1.78) to (3.56±0.61), respectively. In the control group, these values decreased from (9.61±2.77) to (3.15±0.58), and in the experimental group, they decreased from (8.16±1.78) to (2.79±0.59). The VAS score exhibited a noteworthy decrease from (6.18±1.00) to (3.15±0.56) in the control group and from (6.20±1.13) to (2.04±0.68) in the experimental group. The pelvic floor muscle tenderness score decreased from (8.14±0.86) to (3.78±0.77) in the control group and from (7.91±1.03) to (1.93±0.80) in the experimental group. Furthermore, the percentage of patients whose pelvic floor muscle strength increased from

Preparation of CuO@humic acid@carbon nanotube composite material using humic acid as a coupling agent and its lithium-ion storage performance.

The conventional Li-ion battery composite electrode material composed of CuO and carbon nanotubes (CNTs) suffer from poor contact between CuO and CNTs. This results in high electrode resistance and poor electrochemical performance. To solve this problem, CuO@humic acid (HA) @CNT anode material with cross-linked network structure was generated by linking CuO and CNT with HA as a coupling agent. For comparison, CuO@HA or CuO@CNT were also prepared in the absence of CNT or HA, respectively. The results showed that CuO@HA@CNT had lower charge transfer resistance, higher conductivity, lithium-ion diffusion coefficient, specific capacity, and rate capability than CuO@HA and CuO@CNT. The specific capacity of the CuO@HA@CNT electrode was significantly better than that of the composite electrode materials of CuO and CNT, which have been prepared by scientists using various methods. Due to the introduction of HA, not only was the uniformly distributed flower-like CuO obtained, but also the specific capacity and rate capability of the electrode material were substantially improved. This study thus provides a good strategy to optimize the capability of transition metal oxide lithium-ion anode materials.

Expediting Toluene Combustion by Harmonizing the Ce-O Strength over Co-Doped CeZr Oxide Catalysts.

Low-temperature catalytic degradation of volatile organic compounds (VOCs) by enhancing the activity of non-precious metal catalysts has always been the focus of attention. The mineralization of aromatic VOCs requires the participation of a large number of oxygen atoms, so the activation of oxygen species is crucial in the degradation reaction. Herein, we originally adjust the Ce-O bond strength in CeZr oxide catalysts by cobalt doping to promote the activation of oxygen species, thus improving the toluene degradation performance while maintaining high stability. Subsequent characterizations and theoretical calculations demonstrate that the weakening of the Ce-O bond strength increases the oxygen vacancy content, promotes the activation of oxygen species, and enhances the redox ability of the catalysts. This strategy also promotes the activation of toluene and accelerates the depletion of intermediate species. This study will contribute a strategy to enhance the activation ability of oxygen species in non-noble metal oxide catalysts, thereby enhancing the degradation performance of VOCs.