Carbon sequestering infrastructure incorporates carbon-sequestering cladding members that are separate and distinct from structural elements configured to carry a structural load of the infrastructure. The cladding is capable of capturing and sequestering carbon from carbon dioxide in atmospheric/ambient air. The cladding may be distinct members having a high carbon capture capacity (but a low compressive strength unsuitable for use in a structural member) attached to structural members having a lower carbon capture capacity (and a higher compressive strength suitable for use in a structural member). The cladding member may be formed as an envelope suitable for use as a form in casting a structural member. Infrastructure elements including cladding may be configured such that the cladding is removable and replaceable after is carbon sequestering capacity is diminished, to allow for carbon sequestration over the entire length of the infrastructure.

The invention includes systems, methods, compositions, and processes for designing, manufacturing, and utilizing carbon dioxide-sequestering substrates that can fully or partially replace natural sand in coastal engineering applications. These engineered substrates can offset demand for scarce native sand resources, while also effecting the conversion of gaseous carbon dioxide to dissolved or solid-phase products thereby offsetting impacts of anthropogenic climate change.

The invention is directed to a process for the biological conversion of bisulphide into elemental sulphur, comprising the following steps: a) converting bisulphide as dissolved in an aqueous solution to elemental sulphur in the presence of sulphide-oxidizing bacteria and under anaerobic conditions to obtain a first liquid effluent comprising elemental sulphur and used sulphide-oxidizing bacteria; b) regenerating the used sulphide-oxidizing bacteria as obtained in step (a) and as comprised in an aqueous solution in the presence of an oxidant to obtain a second liquid effluent comprising regenerated sulphide-oxidizing bacteria; c) separating elemental sulphur from either the first and/or the second liquid effluent; d) using the regenerated sulphide-oxidizing bacteria in step (a) as the sulphide-oxidizing bacteria.

A process to treat a gas comprising hydrogen sulphide and mercaptans is described. The following steps are part of this process: (a) contacting the hydrogen sulphide and mercaptans comprising gas (1) with an aqueous solution (3) comprising sulphide-oxidising bacteria thereby obtaining a loaded aqueous solution (5) and a gas (4) having a lower content of hydrogen sulphide and mercaptans, (b) contacting the loaded aqueous solution with mercaptan reducing microorganisms immobilized on a carrier under anaerobic conditions, (c) separating the aqueous solution obtained in step (b) from the mercaptan reducing microorganisms to obtain a first liquid effluent (7), and (d) contacting the first liquid effluent (7) with an oxidant (9) to regenerate the sulphide-oxidising bacteria to obtain a second liquid effluent (11) comprising regenerated sulphide-oxidising bacteria. The sulphide-oxidising bacteria as present in step (a) are comprised of regenerated sulphide-oxidising bacteria obtained in step (d).

The present compositions and methods relate to a thermostable carbonic anhydrases, polynucleotides encoding the carbonic anhydrase, and methods of make and/or use thereof. Formulations containing the carbonic anhydrase are suitable for use in extracting carbon dioxide.

An agent for removing malodor from a painting booth includes a volatile organic compound (VOC) degrading microorganism and a volatile fatty acid (VFA) degrading microorganism. The VOC degrading microorganism is configured to degrade VOC. The VFA degrading microorganism is configured to degrade VFA generated when the VOC is degraded.A method of removing malodor is also disclosed.

A method for preparing a fungi-bacteria composite microecologics, including: cultivating and conducting high-density fermentations of Zoogloea sp. HJ1 which has been deposited in China Center for Type Culture Collection (CCTCC) with an accession number: CCTCC NO. M2012235, Pandoraea sp. FLX-1 which has been deposited in CCTCC with an accession number: CCTCC NO. M2011242, and Ophiostoma sp. LLC which has been deposited in CCTCC with an accession number CCTCC NO. M2014531 to obtain mixed strains; cultivating, fermenting, and vacuum drying the mixed strains to yield a resulting product which is ground into a powder; cultivating and conducting high-density fermentation of Aspergillus sp. HD-2 which has been deposited in CCTCC with an accession number: CCTCC NO. M2014175 and Trichoderma sp. LW-1 which has been deposited in CCTCC with an accession number: CCTCC NO. M2014176 to yield spores; and mixing the powder and the spores.

The invention relates to a device (1) for treating a flow of gas, for example of air, comprising a means (6) for dispersing a liquid in the form of droplets, preferably in the form of microdroplets, into said flow of gas to be treated, and an ultraviolet treatment means configured to subject the flow of gas to be treated to UV radiation. The UV treatment means is positioned downstream of the means (6) for dispersing a liquid in the form of droplets, and the UV treatment means is mounted inside a liquid-gas separation means (10) so as to separate the liquid present in the flow of gas when the flow of gas to be treated is subjected to the UV radiation.

Biodegradation media placed in, around, and/or above a methane source reduces the quantum of methane and other alkane gases such as ethane, propane, and butane released into the atmosphere under diverse and fluctuating environmental conditions over a sustainable and/or extended duration. Non-biodegradable material configured for methane biodegradation possesses enhanced drainage of precipitation, improved gas transmission and gas exchange, moisture retention, and a nutrient sustainability.

The object of the invention is a process for sequestering carbon or removing carbon dioxide from air using a bioreactor equipped with autotrophic microorganisms, where the carbon dioxide from the air is the only carbon source.