Additional file 2 of New insights into the plastome evolution of Lauraceae using herbariomics

Supplementary Material 2: Fig. S2. Validation of the presence of trnI-CAU in the plastomes of Licaria capitata and Ocotea bracteosa

Additional file 5 of New insights into the plastome evolution of Lauraceae using herbariomics

Supplementary Material 5: Fig. S5. Unusual plastomes in Caryodaphnopsis and Camphora

Additional file 6 of New insights into the plastome evolution of Lauraceae using herbariomics

Supplementary Material 6: Table S1. Summary of available plastomes of Lauraceae in NCBI. Table S2. Number of three repeats types. Table S3. Length of three repeats types. Table S4. Types and amounts of SSRs in the five newly sequenced chloroplast genomes. Table S5. The distribution of simple sequence repeats. Table S6. The pairwise similarity of Lauraceae. Table S7. Plastomes and sequences obtained from NCBI for phylogenetic studies

Additional file 3 of New insights into the plastome evolution of Lauraceae using herbariomics

Supplementary Material 3: Fig. S3. Percentages of variable characters in 35 aligned Lauraceae plastome

Additional file 4 of New insights into the plastome evolution of Lauraceae using herbariomics

Supplementary Material 4: Fig. S4. Maximum-likelihood (ML) tree inferred from the complete plastomes

Additional file 1 of New insights into the plastome evolution of Lauraceae using herbariomics

Supplementary Material 1: Fig. S1. Circular gene map of the five newly sequenced plastomes

Mixed Catalyst SmMn₂O₅/Cu-SAPO34 for NH₃‑Selective Catalytic Oxidation

Low-temperature selective catalytic oxidation (SCO) is crucial for removing the NH3 slip from the upstream of NH3-selective catalytic reduction (NH3-SCR). Herein, combining zeolite Cu-SAPO34 and the active oxidant mullite SmMn2O5, we developed mixed-phase catalysts SmMn2O5/Cu-SAPO34 by grinding powder mixtures to achieve a low-temperature activity and a reasonable N2 selectivity. The physicochemical properties of the catalysts were characterized by X-ray diffraction (XRD), Brunauer–Emmett–Teller (BET) measurement, scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), and in situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS). The evaluation of NH3 oxidation activity showed that for 30 wt % SmMn2O5/Cu-SAPO34, 90% NH3 conversion was at a temperature of 215 °C in the presence of 500 ppm NH3 and 21% O2 balanced with N2. The in situ DRIFTS spectra reveal the internal SCR mechanism (i-SCR), i.e., NH3 oxidizing to NOx on mullite and NOx subsequently to proceed with SCR reactions, leading to higher conversion and selectivity over the mixed catalysts. This work provides a strategy to design the compound catalyst to achieve low-temperature NH3 oxidation via synergistic utilization of the advantages of each individual catalyst

Additional file 1 of Pheochromocytoma with Takotsubo Syndrome and acute heart failure: a case report

Additional file 1

Ligand-Free Heck Reaction: Pd(OAc)₂ as an Active Catalyst Revisited

Palladium acetate was shown to be an extremely active catalyst for the Heck reaction of aryl bromides. Both the base and the solvent were found to have a fundamental influence on the efficiency of the reaction, with K3PO4 and N,N-dimethylacetamide being the optimal base and solvent, respectively

FUNCTION MONITORING AND RECOVERY METHODS IN THE REHABILITATION OF TENNIS PLAYERS

ABSTRACT Introduction Sports injury is a common injury among professional tennis players compared to other sports. Updated rehabilitation methods can accelerate players’ recovery and ensure a return to sporting activity. However, contemporary rehabilitation monitoring practices want updated reporting. Objective Monitoring tennis players’ function and recovery methods during rehabilitation training after injury. Methods The tennis player underwent arthroscopic capsulotomy of the left ankle joint, free body removal, and synovectomy. The athlete’s body composition, blood routine, biochemistry, nutritional indices, and physiological indicators were monitored. Data were collected before, during, and at the end of the four months (6-10 months) of rehabilitation after the operation. Results 1 month after the operation, weight and lean mass decreased significantly; body fat percentage increased; static heart rate increased significantly (P</div