Abstract: The invention relates to a method for the production of materials. In particular the invention relates to nanostructured materials, and an apparatus and method for the production thereof. In accordance with the invention, nanostructured materials are produced by the subsequent steps of producing nanoparticles; transporting the nanoparticles into, and optionally through, a porous carrier by a gas flow; and depositing the nanoparticles onto the surface of said porous carrier in an essentially isotropic manner.

Abstract: The invention relates to a method for the production of materials. In particular the invention relates to nanostructured materials, and an apparatus and method for the production thereof. In accordance with the invention, nanostructured materials are produced by the subsequent steps of producing nanoparticles; transporting the nanoparticles into, and optionally through, a porous carrier by a gas flow; and depositing the nanoparticles onto the surface of said porous carrier in an essentially isotropic manner.

Abstract: The invention relates to a method for the production of materials. In particular the invention relates to nanostructured materials, and an apparatus and method for the production thereof. In accordance with the invention nanostructured materials are produced by the subsequent steps of producing nanoparticles; transporting the nanoparticles into, and optionally through, a porous carrier by a gas flow; and depositing the nanoparticles onto the surface of said porous carrier in an essentially isotropic manner.

Abstract: A spark ablation device for generating nanoparticles comprising a spark generator; the spark generator comprising first and second electrodes, wherein the spark generator further comprises at least one power source which is arranged to be operative at a first energy level for maintaining a discharge between the first and second electrodes, which power source is arranged for repetitively increasing the energy of the discharge to a predetermined secondary level that is higher than the first energy level for ablating a portion of the electrodes.

Abstract: The invention relates to a method for the production of materials. In particular the invention relates to nanostructured materials, and an apparatus and method for the production thereof. In accordance with the invention nanostructured materials are produced by the subsequent steps of producing nanoparticles; transporting the nanoparticles into, and optionally through, a porous carrier by a gas flow; and depositing the nanoparticles onto the surface of said porous carrier in an essentially isotropic manner.

Abstract: A spark ablation device for generating nanoparticles comprising a spark generator; the spark generator comprising first and second electrodes, wherein the spark generator further comprises at least one power source which is arranged to be operative at a first energy level for maintaining a discharge between the first and second electrodes, which power source is arranged for repetitively increasing the energy of the discharge to a predetermined secondary level that is higher than the first energy level for ablating a portion of the electrodes.

Abstract: In a combustion process a fuel is mixed with an oxygen-containing gas in an adjustable ratio. This fuel-gas-mixture is burned and thereby an exhaust gas is produced. At least a part of the exhaust gas is collected and exposed to an ultra violet radiation source, thereby generating positive and negative charge carriers in the exhaust gas by means of a photoelectric charge separation process. The kind or amount of the positive and/or negative charge carriers is detected to produce a measurement value which reflects the amount and/or the charge of the carriers. Therefrom a control signal is derived and the mixture-ratio of the oxygen-containing gas and the fuel, the so-called .lambda.-factor, is adjusted in response to said control signal in order to improve the efficiency of the combustion and to reduce the emission of toxic substances.

Abstract: The invention provides a method for the quantitative and/or qualitative characterization of substances which are contained in a gaseous carrier medium. Modifications of the surface of small solid particles suspended in a carrier gas may be measured with very high sensitivity by the application of the photoelectric effect. Thereby, an aerosol is chemically modified, e.g. by admixing a gaseous agent or a gas mixture, or by subjecting it to an electromagnetic radiation, and subsequently the resulting variation of the photoelectron emission from the suspended particles is recorded. By measuring the variation of the photoelectric effect during the admixing or variation of a gaseous agent to the aerosol to be examined or during a variation of the electromagnetic radiation, to which the aerosol to be examined is subjected, the suspended particles may be classified in one or several steps.

Abstract: The invention relates to a fire detector having a measuring chamber defined by two electrodes, so that a non-ionizing electric field is produced between the electrodes by a DC voltage source. The measuring electrode is connected to the input of a current measuring device without direct connection with the DC voltage source. As soon as charged particles of smoke penetrate into the measuring chamber between the electrodes, the electric field causes the positive and negative particles to drift. The charge drift induces a current into the measuring electrode which is measured.

Abstract: The invention concerns a method and apparatus for electrically charging particles of liquid or solid matter suspended in gases, especially in air. The particle carrying gas is irradiated with ultraviolet light having an energy below the threshold for ionization of the gas, but above the photoelectric threshold of the particles. The actual charging occurs by photoemission of electrons from the particles. The photoelectrons or negative small ions are removed from the neighborhood of the positively charged particles by diffusion to a charge absorbing surface. The photoelectric charging method and apparatus of the present invention are highly effective, particularly for very small particles and yields chemical information on the particles and their surface.