Previous studies have indicated that China is one of the domestication centres of Asian cultivated rice (Oryza sativa), and common wild rice (O. rufipogon) is the progenitor of O. sativa. However, the number of domestication times and the geographic origin of Asian cultivated rice in China are still under debate. In this study, 100 accessions of Asian cultivated rice and 111 accessions of common wild rice in China were selected to examine the relationship between O. sativa and O. rufipogon and thereby infer the domestication and evolution of O. sativa in China through sequence analyses of six gene regions, trnC-ycf6 in chloroplast genomes, cox3 in mitochondrial genomes and ITS, Ehd1, Waxy, Hd1 in nuclear genomes. The results indicated that the two subspecies of O. sativa (indica and japonica) were domesticated independently from different populations of O. rufipogon with gene flow occurring later from japonica to indica; Southern China was the genetic diversity centre of O. rufipogon, and the Pearl River basin near the Tropic of Cancer was the domestication centre of O. sativa in China.
Methane-to-syngas conversion plays an important role in industrial gas-to-liquid technologies, which is commercially fulfilled by energy-intensive reforming methods. Here we present a highly selective and durable iron-based La 0.6 Sr 0.4 Fe 0.8 Al 0.2 O 3-δ oxygen carrier for syngas production via a solar-driven thermochemical process. It is found that a dynamic structural transformation between the perovskite phase and a Fe 0 @oxides core-shell composite occurs during redox cycling. The oxide shell, acting like a micro-membrane, avoids direct contact between methane and fresh iron(0), and prevents coke deposition. This core-shell intermediate is regenerated to the original perovskite structure either in oxygen or more importantly in H 2 O-CO 2 oxidant with simultaneous generation of another source of syngas. Doping with aluminium cations reduces the surface oxygen species, avoiding overoxidation of methane by decreasing oxygen vacancies in perovskite matrix. As a result, this material exhibits high stability with carbon monoxide selectivity above 95% and yielding an ideal syngas of H 2 /CO ratio of 2/1.
Direct
conversion of methane to C2 hydrocarbons under
nonoxidative conditions is an attractive technology but is challenging
due to high reaction temperature, severe coke deposition, and low
selectivity. Here, we report three dual-metal-site catalysts (DMSCs)
based on nitrogen-doped graphene (FeCo–N–C, Fe2–N–C, and Co2–N–C) for nonoxidative
coupling of methane to C2 hydrocarbons from a theoretical
perspective. Our calculated results reveal that DMSCs present universally
better performance in methane activation than single-metal-site catalysts
(Fe–N–C and Co–N–C). Among the three DMSCs,
Co2–N–C exhibits the best catalytic activity
and superior selectivity to ethane in the whole reaction pathway.
Our microkinetic modeling reveals that the Co2–N–C
catalyst can convert methane to CH3, C2H6, and H2 at 1200 K. The electronic structure analysis
and ab initio molecular dynamics simulations demonstrate
that Co2–N–C possesses both intrinsic stability
and high-temperature stability. Moreover, Co2–N–C
also manifests better coke resistance compared with larger Co clusters,
indicated by the difficult kinetics of methane deep dehydrogenation
to naked carbon. This work provides a potential catalyst prototype
for the selective conversion of methane to C2 hydrocarbons
under nonoxidative conditions.
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