Systems for generating eFuels from carbon based fuel combustion flue gas are provided. Systems for generating platform chemicals from carbon based fuel combustion flue gas are also provided. Methods for generating platform chemicals from carbon based fuel combustion flue gas are also provided.

This disclosure relates to a mobile pyrolysis plant and related systems and methods. An example method includes: providing a mobile pyrolyzer configured to traverse a field where biomass is grown; providing harvested biomass to the mobile pyrolyzer as the mobile pyrolyzer traverses the field; subjecting the harvested biomass to a fast pyrolysis process in the mobile pyrolyzer to generate biochar, bio-oil, and syngas as the mobile pyrolyzer traverses the field; and applying the biochar to the field as the mobile pyrolyzer traverses the field.

This disclosure relates to a mobile pyrolysis plant and related systems and methods. An example method includes: providing a mobile pyrolyzer configured to traverse a field where biomass is grown; providing harvested biomass to the mobile pyrolyzer as the mobile pyrolyzer traverses the field; subjecting the harvested biomass to a fast pyrolysis process in the mobile pyrolyzer to generate biochar, bio-oil, and syngas as the mobile pyrolyzer traverses the field; and applying the biochar to the field as the mobile pyrolyzer traverses the field.

This disclosure relates to a mobile pyrolysis plant and related systems and methods. An example method includes: providing a mobile pyrolyzer configured to traverse a field where biomass is grown; providing harvested biomass to the mobile pyrolyzer as the mobile pyrolyzer traverses the field; subjecting the harvested biomass to a fast pyrolysis process in the mobile pyrolyzer to generate biochar, bio-oil, and syngas as the mobile pyrolyzer traverses the field; and applying the biochar to the field as the mobile pyrolyzer traverses the field.

This disclosure relates to a mobile pyrolysis plant and related systems and methods. An example method includes: providing a mobile pyrolyzer configured to traverse a field where biomass is grown; providing harvested biomass to the mobile pyrolyzer as the mobile pyrolyzer traverses the field; subjecting the harvested biomass to a fast pyrolysis process in the mobile pyrolyzer to generate biochar, bio-oil, and syngas as the mobile pyrolyzer traverses the field; and applying the biochar to the field as the mobile pyrolyzer traverses the field.

An integrated apparatus and method for co-production of carbon and hydrogen by biomass cascade pyrolysis-microwave gasification are provided. The apparatus includes an integrated reaction system, an internal and external radial energy supply system, and a product separation and collection system. The method includes firstly performing low-temperature pyrolysis on feedstock to greatly improve its absorbing property, and then preparing co-production of a hydrogen-rich gas and a porous carbon product by microwave gasification and online reforming, where the combustion of the pyrolysis gas provides heat for feedstock drying and its low-temperature pyrolysis reaction; performing separation and purification on the hydrogen-rich gas to prepare a high-purity hydrogen product, where the separated gas serving as a gasification agent returns for gasification reaction. By using multi-system collaborative integrated designing, the low-temperature pre-pyrolysis improves microwave product quality and reaction efficiency while greatly reducing high-quality electric energy consumption, and supplying heat by self-made low-quality thermal energy recycling.