A process for gas-phase synthesis of titanium dioxide aerosol gels with controlled monomer size and crystalline phase using a diffusion flame aerosol reactor operated in a buoyancy-opposed configuration is disclosed. The process includes introducing a precursor stream into a diffusion flame aerosol reactor, introducing a fuel stream into the reactor, combusting the precursor stream and the fuel stream in a flame to form at least one nanoparticle, and operating the reactor in a down-fired buoyancy-opposed configuration to produce the aerosol gel.

The invention relates to an aerosol product exposure system comprising an exposure chamber intended to receive an aerosol product, an aerosol product diffusion device comprising a source of aerosol product to be sprayed connected to an aerosol generator, said aerosol generator cooperating with a desiccator so as to at least partially eliminate the moisture from the aerosol product, at least one supply duct intended to bring the aerosol product into the exposure chamber. Such a system can in particular be used to test the integrity of a container and/or the antimicrobial activity of a product of interest.

Disclosed herein is a multi-purpose aerosol platform capable of producing and delivery of submicron and nano structured materials for pharmaceutical, biomedical and environmental applications. Depending on the application, active chemical and biological materials may be processed from liquid dispersions into droplets and/or particle formulations. The disclosed system uses moderate gas pressures to atomize liquids into submicron-size droplets that are 10-1000 times smaller in diameter than commercial and research systems. This allows much gentler and rapid droplet-to-particle conversion, applying much smaller physical and chemical stresses on the processed materials than conventional techniques like spray drying, spray coating, spray freeze drying and other technologies. For example, the disclosed system can be used for an ultra-fine nebulization and delivery of viscous therapeutic oils including oils of medical cannabis, for which conventional nebulization systems either fail or became ineffective. Such systems could help patients with acute respiratory distress syndrome (ARDS) developed in hard COVID-19 cases.

A method for producing a quantum dot including crystalline nanoparticle fluorescent material, wherein, using a first precursor solution and a second precursor solution containing different elements each other, the second precursor solution is sprayed as an aerosol on the heated first precursor solution, or both the first precursor solution and the second precursor solution are sprayed on a heated solvent as aerosols, and the first precursor solution and the second precursor solution are reacted with each other to synthesize a core particle containing the different elements. The method for producing quantum dots, can suppress the non-uniformity of the particle size of the quantum dots and accompany increase in the distribution of emission wavelengths in large scale synthesis.

The present disclosure provides a device for controlling the shape of an aerosol particle condensation growth flow field through an electromagnetic field. The device includes an aerosol growth device and a power supply. The aerosol growth device includes a porous medium, magnetic rubber and an electromagnet group. The magnetic rubber is sleeved in an inner cavity of the electromagnet group, and the porous medium is sleeved in an inner cavity of the magnetic rubber. The magnetic rubber is clung or clings to the porous medium, and the power supply is connected with the electromagnet group. The present disclosure also provides a method for controlling the shape of the aerosol particle condensation growth flow field through the electromagnetic field.

The disclosed spray deposition systems and methods control the formation and dispensation of droplets during the atomization of a fluid. Such systems and methods generally can generate small quantities and droplets of a desired size of highly-viscous fluids and/or fluids having non-Newtonian properties or other complex rheologies using mechanical systems and processes with the option of further controlling the droplet size and/or the volume of droplets with various enhancements. The systems and methods stretch fluid between a fluid feed system and a surface and are able to form the controlled-volume of the droplets.

A method of manufacturing a flowable and dispersible powder includes solubilizing a lipophilic substance in a terpene to form a mixture and treating the mixture to form a nanoemulsion dispersed in an aqueous solution. The aqueous solution includes at least one functional excipient. The nanoemulsion is then spray dried, thereby evaporating first the aqueous portion and then the terpene to form a dry powder formed from solid particles comprising the lipophilic substance.

Aerosols can be created by filament stretching and breaking of Newtonian and non-Newtonian fluids by applying a strain to and stretching the fluid. The fluid is stretched along a strain pathway and forms a fluid filament between diverging surfaces. The stretched fluid filament breaks into droplets that can be harvested to form a mist or aerosol. The aerosol creation systems can include one or more pairs of counter-rotating rollers that are positioned adjacent to each other that stretch the fluid or a pair of pistons that move toward and away from each other to stretch the fluid. Some aerosol creation systems can include multiple pairs of counter-rotating rollers that are positioned in a circular, oval, or linear pattern. The aerosol creation system with multiple pairs of counter-rotating rollers can generate mist is one or more directions and can be positioned between two concentric rings or linearly, among other configurations.

The method for providing an aerosol-generating device for use with a shape-transformable aerosol-forming substrate comprises providing an aerosol-generating device comprising a device housing comprising a moulding cavity. The moulding cavity at least partially corresponds to a moulding space between a first mould half and a second mould half of a mould, the first mould half and the second mould half being internal surfaces of the device housing. The method further comprises the step of providing a flat aerosol-forming substrate adapted to change shape when pressed into the moulding cavity and being transformed into a non-flat aerosol-forming substrate. The invention also refers to a flat aerosol-generating article and a kit comprising a flat aerosol-generating article and an aerosol-generating device.

A process for the hydrophobization of a porous silica based compound involves the steps of providing a composition (I) containing a porous silica based compound, treating the composition (I) with a composition (II) containing hexamethyldisiloxane or its hydrolyzed form, and removing the treated silica based compound. The porous silica based compound obtained by the process is useful. A porous silica based compound obtained or obtainable by the process can be used for medical and pharmaceutical applications, as adsorbents, for cosmetic applications, as an additive for food, as a catalyst support, for the preparation of sensors, or for thermal insulation.