A system and method for monitoring or controlling an aerobic landfill bioreactor having a plurality of zones each including at least one well head. The system comprises: a gas extraction blower, a plurality of temperature sensors disposed in the well heads, an ex-situ relative humidity detector, an ex-situ gas constituent detector, an air injection system, a liquid injection system, and a controller. Landfill gas is extracted by the blower and it's temperature, relative humidity, and gas constituents are measured. The system further comprises a system of headers, isolation valves, and flow control valves which serve to isolate zones for measurement and/or air and liquid injection as well as control the flow of either the landfill gas extraction or liquid and air injection. The method involves measuring: temperature, relative humidity, and gas constituents of the extracted landfill gas. Advantageously, the ex-site placement of the sensors and detectors ensure that measurements are representative of the aerobic bioreactor operating parameters. The air and liquid injection systems are adjusted, based on the measured temperature, relative humidity, and gas constituents to optimize the operation of the aerobic landfill bioreactor.

The present disclosure provides a sample test card and a sample loading method thereof, relates to the technical field of microbiological testing. The present disclosure includes sample wells arranged in an array; the sample wells are connected together through a flow channel network, and the sample wells are filled with a sample through a unified intake port. Sample filling is completed by vacuuming; during filling, a liquid sample is firstly filled, and air or other inert gas or insoluble liquid is filled; liquid sample volume and air volume are formed in proportion in the sample wells. In the present disclosure, the filled liquid sample is controlled not to fill the sample wells completely, and there are sufficient air space in sample wells, so that the sample wells are independent from each other to avoid contamination, and more sample wells can be arranged on the test card with the same size.

Disclosed herein are carbon dioxide capture devices, facilities, methods, and compositions. Specifically disclosed herein are devices, facilities, compositions and methods to capture carbon dioxide from the Earth's atmospheric air for providing long-term sequestration of the captured carbon and/or utilization thereof. To this end, a carbon dioxide capture device configured in accordance with one or more embodiments of the present invention can comprise a coating substrate having at least one coatable surface and a carbon dioxide capture coating composition on a coatable surface of the coating substrate. The carbon dioxide capture coating composition preferably comprises a coating material and a photosynthetic organism, wherein the photosynthetic organism is at least one of admixed within the coating material and on an exposed surface of the coating material. The coating material can deliver all or a portion of water to the photosynthetic organism necessary for sustaining photosynthetic activity of the photosynthetic organism.

Embodiments of the present invention may provide fluid flow coordinators, passive flow field modifiers, or even inwardly protruding helical spines which can be used in continuous, scalable, low energy usage, bioreactor systems perhaps to provide optimal mixing of microorganisms with nutrients, gases, or the like or even to move microorganisms, such as algae, in and out of light for effective and optimal growth.

A sludge digester including a vessel and floating cover. The vessel includes a sidewall and an interior volume configured to receive and contain sludge. According to one embodiment, the cover comprises a frame structure that is constructed and arranged to form a skirt member formed at a periphery of the cover and extending downwardly into the vessel, and a continuous ballast ring attached to a lower portion of the skirt member and configured to form a trough member with an interior surface of the skirt member. The sludge digester may also include a guide system coupled to the sidewall and the skirt member and configured to allow vertical displacement of the cover with change in volume of at least one of a gas and a sludge contained in the vessel beneath the cover.

The invention discloses a device for producing biogas with high methane content by utilizing livestock and poultry feces, wherein the interior of a tank body of a biogas fermentation tank is divided by a baffle, so as to form a main reaction chamber and an auxiliary reaction chamber which are communicated in upper portions, so that a reactant flows into the auxiliary reaction chamber only after entering the main reaction chamber via a relatively low feeding hole and then reaching a high position of a liquid level, and extension of fermentation time is realized, meanwhile, scales formed at the top of fermentation broth flow into the auxiliary reaction chamber along with liquid, so that the interior of the main reaction chamber keeps a liquid state all the time, and sealing and reduction of quantity of anaerobic bacteria are avoided.

Presented herein is a method for in-situ real-time non-invasive estimation of the level of living cells proliferation and/or growth in a biological material present in a container sealed to prevent biological contamination. The method comprises measuring the concentration of at least one metabolic gas that is emitted by the living cells. The method can be adapted inter alia to detect a microorganism contamination in a storage container for platelets sealed to biological contamination, to monitor a fermentation process in a fermenter enclosing microorganisms and sealed to biological contamination, and to monitor the concentration of living cells in a bioreactor sealed to biological contamination.

A method and system for measuring metabolic gas concentration. The method includes: applying, via a tunable coherent infrared light source, an infrared light beam to a region of interest, wherein the region of interest is positioned between the tunable coherent infrared light source and a detection module, wherein the region of interest is in fluid communication with a biological material including living cells emitting a metabolic gas; measuring, via the detection module, a plurality of signals based on the application of the infrared light beam to the region of interest, wherein measuring each of the plurality of signals further comprises tuning the tunable coherent infrared light source; and determining the concentration of the metabolic gas based on the plurality of signals.

A system comprising a collocated thermal plant, water source, CO.sub.2 source and biomass growth module is disclosed. A method of improving the environment by utilizing the system is disclosed.

The present invention is related to an anaerobic photobioreactor and a method for active biomass cultivation, wastewater treatment, nutrients recovery, energy production and high-value products synthesis. Phototrophic bacteria are cultured in the anaerobic photobioreactor lighted with solar or artificial irradiation where certain light wavelengths are selectively discarded with a light selector installed on the top of the photobioreactor. In this light-based process wastewater treatment and resources recovery, like nutrients and high-value bioproducts (fertilizers, polymers and proteins) present in wastewater are performed simultaneously. Cultured biomass is treated by anaerobic digestion for biofuel production, including optative hydrolytic pre-treatment, and/or valuable bioproducts can be obtained in a downstream process.