Abstract: A novel aquatic system that includes a motorized housing which can be propelled across a body of water. The motorized housing is coupled to a tethering line that can be used to provide a command to stop and/or control the movement of the housing. The line may be coupled to a rod and reel used to pull the housing back to the operator. The housing may be shaped as a fish and contain an off-center weight that vibrates and provides the simulated experience of “catching the fish”.

Abstract: A discharge light-emitting device includes a gas-filled discharge spaces (30) to use electric discharge in the gas. The gas contains at least 0.01-1% water vapor by volume. The specified amount of water vapor decreases discharge voltage markedly. Water vapor is introduced between a sealing step and an evacuation step so that the gas-filled discharge spaces can finally contain a desired amount of water vapor.

Abstract: A method and apparatus for manufacturing a bulb wherein a bead mount and a glass bulb are set in a recess in an upper surface of a heater arranged inside a hermetically sealed chamber, a first gas comprised of one component of a composition of a sealing gas in the glass bulb or an inert gas excluding the sealing gas is supplied to the chamber at a predetermined pressure after the chamber is evacuated, a second gas comprised of a remaining component of the sealing gas or all of the components thereof is sprayed in a space between the glass bulb and the bead mount at a pressure higher than that of the first gas to exhaust the first gas from the space within the glass bulb. The heater is energized after the substitution of the gas within the space of the bulb is performed, or while the gas substitution in the space is being performed, in order to heat and melt an edge portion of the bead mount and glass bulb to seal the glass bulb to the bead mount with the second gas sealed within the glass bulb.

Abstract: A method is provided for making a lithium-sodium-antimony photocathode including the step of forming a base layer including antimony on a substrate. Sodium is then deposited onto the base layer at an elevated temperature to a first peak value of responsivity, thereby forming a sodium-antimony surface. Next, at room temperature, lithium is deposited onto the substrate containing the sodium-antimony surface until the lithium-sodium-antimony photocathode develops a hazy brown color. The photocathode is sensitized by heating the substrate to an elevated temperature until a second peak value of responsivity, greater than the first peak value, is obtained. Antimony, sodium and lithium are then alternately deposited on the photocathode in order to stabilize the second responsivity peak.