【Vapourtec】Application Note 21 – Michael Addition with Nitromethane
This example illustrates the use of the Vapourtec R-Series flow chemistry platform to safely process an extremely energetic, reactive intermediate.
This example illustrates the use of the Vapourtec R-Series flow chemistry platform to safely process an extremely energetic, reactive intermediate.
This example illustrates the use of the new Vapourtec tube in tube gas reactor combined with the Vapourtec R-Series system to react reagent gases under pressure without the use of scale limiting pressure reactors (e.g. Parr ‘bombs’).
This example illustrates the use of the new Vapourtec tube in tube gas reactor combined with the Vapourtec R-Series system to react reagent gases under pressure without the use of scale limiting pressure reactors (e.g. Parr ‘bombs’).
Nitration with fuming nitric acid and subsequent scale-up
This Application Note illustrates how a Vapourtec acid resistant R Series flow chemistry system
CO₂ is a thermodynamically stable molecule and an increase in reaction pressure is known to be advanta- geous for efficient CO₂ activation as evident from the thermodynamic equilibrium conversion and selectivity calculations (Figure 1).
Steel components are generally used in the design of deep geological repositories for high-level radioactive waste. After closure of the underground disposal gal- leries, anoxic corrosion of steel is expected to produce hydrogen gas.
Geologic carbon sequestration (GCS) is needed to mitigate global warming caused by increased atmo- spheric CO₂ concentrations.
Iron hydroxide precipitation is an important process in many subsurface environments, such as managed aquifer recharge, geologic carbon sequestration, as well as water injection enhanced oil production.
Coal bed methane is a promising alternative to con- ventional gas. Enhanced Coal Bed Methane (ECBM) technology combines improved methane recovery with underground storage of CO₂.
Supercritical fluids exist at high pressures and offer potential for effective and efficient separations. This investigation involves exploring the equilibrium behavior of supercritical fluid mixtures with two or more species, one being carbon dioxide (CO₂).