Abstract: There is provided an adherent cell-culture support comprising gold nanoparticles on the surface where the cells attach to, wherein the size of the nanoparticles is from 5 nm to 2 microns, the distance between the nanoparticles is from 2 nm to 30 nm and the anisotropy aspect ratio is greater than 1. These substrates have improved properties for allowing the culturing and subsequent detachment of cells, with potential applications in a wide range of fields such as stem cell research and tissue engineering. There is also provided a process for their preparation and several uses thereof.

Abstract: Disclosed are methods and systems for generating hydrogen gas at pressures high enough to fill a hydrogen storage cylinder for stationary and transportation applications. The hydrogen output of an electrochemical hydrogen gas generating device, a hydrogen-producing reactor, or a diluted hydrogen stream is integrated with an electrochemical hydrogen compressor operating in a high-differential-pressure mode. The compressor brings the hydrogen produced by the hydrogen generating device to the high pressure required to fill the storage cylinder.

Abstract: Method and practical use system for measuring the imbalance potential of an electrical installation or system comprising: i) acquiring instantaneous values of voltage (vA, vB, vC) and electrical intensity (iA, iB, iC) of each of the phases A, B, C of the installation, and breaking them down into their fundamental frequency components (vA1, vB1, vC1), (iA1, iB1, iC1); ii) obtaining effective voltage and intensity values and angles for initial phase difference between voltage and intensity, and, starting from these effective values obtaining active powers (PA, PB, PC) and reactive (QA, QB, QC) potentials for each of the phases; iii) from the active and reactive potentials, obtaining (4) a phasor imbalance potentials (?U) according to the following expression: ?U=?{square root over (2)}( p·|PA+a2PB+aPC|+ q·|QA+a2QB+aQC|) where a=1|120° and p and q are orthogonal unit phasors. The invention also relates to a device for calibrating (21) instruments for measurement instruments of this imbalance power.

Abstract: Method and practical use system for measuring the imbalance potential of an electrical installation or system comprising: i) acquiring instantaneous values of voltage (vA, vB, vC) and electrical intensity (iA, iB, iC) of each of the phases A, B, C of the installation, and breaking them down into their fundamental frequency components (vA1, vB1, vC1), (iA1, iB1, iC1); ii) obtaining effective voltage and intensity values and angles for initial phase difference between voltage and intensity, and, starting from these effective values obtaining active powers (PA, PB, PC) and reactive (QA, QB, QC) potentials for each of the phases; iii) from the active and reactive potentials, obtaining (4) a phasor imbalance potentials (?U) according to the following expression: ?U=?{square root over (2)}( p·|PA+a2PB+aPC|+ q·|QA+a2QB+aQC|) where a=1|120° and p and q are orthogonal unit phasors. The invention also relates to a device for calibrating (21) instruments for measurement instruments of this imbalance power.

Abstract: A miniaturized gas sensor comprised of thick- or thin-film type electrodes, on a non-conductive supportive substrate, and in contact with a solid ionomer electrolyte, for the detection of toxic gases, i.e., carbon monoxide, and other oxidizable or reducible gases and vapors is described. The all-solid planar sensor cell has two or more film type electrodes arranged on a non-conductive planar surface of a supportive substrate. The electrodes are discrete and in intimate contact with the same solid polymer ionomer membrane. The sensor cell contains no liquid electrolyte and is operated in a constant-voltage, potentiostatic or potentiodynamic mode. A high sensitivity to a select gas or vapor is achieved by a novel three-phase contact area design for a sensing electrode which provides contact with the solid ionomer electrolyte, as well as the gas sample via diffusion openings or holes that penetrate through the supportive substrate.

Abstract: Disclosed are methods and systems for generating hydrogen gas at pressures high enough to fill a hydrogen storage cylinder for stationary and transportation applications. The hydrogen output of an electrochemical hydrogen gas generating device, a hydrogen-producing reactor, or a diluted hydrogen stream is integrated with an electrochemical hydrogen compressor operating in a high-differential-pressure mode. The compressor brings the hydrogen produced by the hydrogen generating device to the high pressure required to fill the storage cylinder.

Abstract: Disclosed are methods and systems for generating hydrogen gas at pressures high enough to fill a hydrogen storage cylinder for stationary and transportation applications. The hydrogen output of an electrochemical hydrogen gas generating device is integrated with an electrochemical hydrogen compressor operating in a high-differential-pressure mode. The compressor brings the hydrogen produced by the gas generating device to the high pressure required to fill the storage cylinder.

Abstract: Disclosed are methods and systems for generating hydrogen gas at pressures high enough to fill a hydrogen storage cylinder for stationary and transportation applications. The hydrogen output of an electrochemical hydrogen gas generating device is integrated with an electrochemical hydrogen compressor operating in a high-differential-pressure mode. The compressor brings the hydrogen produced by the gas generating device to the high pressure required to fill the storage cylinder.

Abstract: A rechargeable battery comprising two or more electrochemical cells using a reoxidizable nickel oxide at the positive electrode and hydrogen as the negative electrode reactant. The electrodes of the cells are disposed in a common chamber in a battery case and connected so as to series couple the cells between a pair of terminals. The battery case is precharged with hydrogen gas while the positive electrodes are in a discharged state and then is sealed off. Additional hydrogen gas is evolved during charging and the state of charge can be determined by monitoring the gas pressure in the battery case. On discharging the battery, hydrogen is consumed down to the precharge level. The battery has inherent protection against damage from overcharging and overdischarging. The unique overdischarge mechanism prevents battery failure in the event that one cell in the series in discharged prematurely.