Sample monitoring and flow control systems and methods are disclosed for monitoring of airborne particulates. A system may include a particle collection filter. The system also includes a fluid moving device for moving a sample through the particle collection filter. Further, the system includes a light source configured to direct irradiating light towards the particle collection filter. The system also includes a light detector positioned to receive the irradiating light passing through the particle collection filter and configured to generate a signal representative of an amount of the received light. Further, the system includes a controller configured to receive the signal and to control the fluid moving device based on the amount of the received light.

Sample monitoring and flow control systems and methods are disclosed for monitoring of airborne particulates. A system may include a particle collection filter. The system also includes a fluid moving device for moving a sample through the particle collection filter. Further, the system includes a light source configured to direct irradiating light towards the particle collection filter. The system also includes a light detector positioned to receive the irradiating light passing through the particle collection filter and configured to generate a signal representative of an amount of the received light. Further, the system includes a controller configured to receive the signal and to control the fluid moving device based on the amount of the received light.

A process for stable fermentation of CO-containing substrates and improved ethanol productivity includes providing medium components in amounts needed by microorganisms in the fermentation. The process includes determining a potassium concentration in the fermentation medium and providing a first medium and a second medium to the fermentation, the first medium provided at a rate effective for maintaining the potassium in the fermentation medium in a range of about 20 to about 200 mg/L until reaching a target cell density.

A process for stable fermentation of CO-containing substrates and improved ethanol productivity includes providing medium components in amounts needed by microorganisms in the fermentation. The process includes determining a potassium concentration in the fermentation medium and providing a first medium and a second medium to the fermentation, the first medium provided at a rate effective for maintaining the potassium in the fermentation medium in a range of about 20 to about 200 mg/L until reaching a target cell density.

A transfer device includes at least one pump unit provided for a defined gas transfer between a first, closed-off space of an installation, in particular a photobioreactor installation, and a second space which is separate from the first space. The at least one pump unit is embodied as a selective oxygen pump.

A transfer device includes at least one pump unit provided for a defined gas transfer between a first, closed-off space of an installation, in particular a photobioreactor installation, and a second space which is separate from the first space. The at least one pump unit is embodied as a selective oxygen pump.

Described embodiments include a culture incubator, method, and sensor circuit. A culture incubator includes an accessible incubation compartment configured to contain a culture item at a specified incubation temperature; a phase change material having a phase transition temperature over the specified incubation temperature; and a heat transfer element in thermal communication with the phase change material and configured to transfer heat to the phase change material. A sensor circuit is configured to acquire data indicative of a phase composition state of the phase change material. A manager circuit is configured to determine a difference between the phase composition state and a target phase composition state for the phase change material. A controller circuit is configured to transfer heat to the phase change material in an amount estimated to change the phase composition state of the phase change material to the target phase composition state.

Described embodiments include a culture incubator, method, and sensor circuit. A culture incubator includes an accessible incubation compartment configured to contain a culture item at a specified incubation temperature; a phase change material having a phase transition temperature over the specified incubation temperature; and a heat transfer element in thermal communication with the phase change material and configured to transfer heat to the phase change material. A sensor circuit is configured to acquire data indicative of a phase composition state of the phase change material. A manager circuit is configured to determine a difference between the phase composition state and a target phase composition state for the phase change material. A controller circuit is configured to transfer heat to the phase change material in an amount estimated to change the phase composition state of the phase change material to the target phase composition state.

Methods of culturing microorganisms in combinations of phototrophic, mixotrophic, and heterotrophic culture conditions are disclosed. A culture of microorganisms may be transitioned between culture conditions over the life of a culture in various combinations, utilizing various conditions in a sequential manner to optimize the culture for growth or product accumulation.

Methods of culturing microorganisms in combinations of phototrophic, mixotrophic, and heterotrophic culture conditions are disclosed. A culture of microorganisms may be transitioned between culture conditions over the life of a culture in various combinations, utilizing various conditions in a sequential manner to optimize the culture for growth or product accumulation.