Explanation: The fundamental principle of mercury-vapor lamp operation involves an electric arc passing through *vaporized* mercury, not solid mercury.

Explanation: The fused quartz arc tube, not the outer glass bulb, is the component primarily responsible for containing the high-temperature electric arc within a mercury-vapor lamp.

Explanation: Upon reaching operating temperature, mercury-vapor lamps maintain an internal pressure of approximately one atmosphere within the arc tube, not significantly below 0.1 atmospheres.

Explanation: Argon gas is present in mercury-vapor lamps to facilitate the initiation of the electric arc upon startup. The primary visible light output is generated by the excited mercury vapor itself.

Explanation: The resistor associated with the starter electrode in some mercury lamps is designed to supply current to the starter, facilitating arc initiation, not to cool the arc tube.

Explanation: Medium-pressure mercury-vapor lamps emit light across a broader spectrum, extending from the ultraviolet range (approximately 200 nm) into the visible spectrum (up to 600 nm), not primarily in the UV range below 300 nm.

Explanation: Mercury-vapor lamps generate light through an electric arc that passes through vaporized mercury, causing the mercury atoms to become excited and emit photons.

Explanation: The fused quartz arc tube is the component specifically designed to contain the high-temperature electric arc within a mercury-vapor lamp due to its resistance to heat and chemical inertness.

Explanation: Argon gas, present in low-pressure form within the lamp, ionizes upon power application, initiating the electric arc which then heats and vaporizes the mercury.

Explanation: The primary functions of the outer glass bulb in a mercury-vapor lamp are to provide thermal insulation for the arc tube and to shield users from harmful ultraviolet radiation.

Explanation: When operating at full temperature, the internal pressure within the arc tube of a mercury-vapor lamp is approximately one atmosphere.

Explanation: Peter Cooper Hewitt is credited with developing the first mercury-vapor lamp to achieve widespread success, with his initial patent granted in 1901.

Explanation: Peter Cooper Hewitt was granted U.S. patent 682,692 for his mercury-vapor lamp on September 17, 1901, not in 1903. An improved version was developed in 1903.

Explanation: During the 1930s, companies such as Osram-GEC and General Electric were instrumental in developing enhanced, contemporary forms of mercury-vapor lamps, contributing to their broad adoption for general illumination.

Explanation: Peter Cooper Hewitt is credited with developing the initial mercury-vapor lamp that achieved widespread commercial success, with his patent granted in 1901.

Explanation: Mercury-vapor lamps typically exhibit a luminous efficacy within the range of 35 to 55 lumens per watt, indicating a moderate level of energy efficiency compared to other lighting technologies.

Explanation: Mercury-vapor lamps are characterized by their long operational lifespans, often reaching approximately 24,000 hours, which is significantly longer than the 5,000 hours stated.

Explanation: Color-corrected mercury lamps employ a phosphor coating that absorbs ultraviolet emissions and re-emits them as red wavelengths, thereby enhancing the overall color rendition of the light.

Explanation: Mercury-vapor lamps require a warm-up period, typically ranging from four to seven minutes, to achieve their full light output after being switched on.

Explanation: Upon initial activation, a mercury-vapor lamp emits a dim, dark blue glow. It requires a warm-up period of several minutes to reach its full, brighter light output.

Explanation: A 125W mercury-vapor lamp typically draws approximately 1.15 amperes, while a 400W lamp draws approximately 3.25 amperes. Therefore, the 400W lamp operates at a higher current.

Explanation: The phosphor coating in color-corrected mercury lamps converts ultraviolet emissions into red wavelengths, improving color rendition by adding red light, not blue.

Explanation: Color-corrected mercury-vapor lamps can frequently be identified outdoors by the presence of a distinct blue halo encircling the emitted light.

Explanation: While mercury vapor emits strongly in the ultraviolet spectrum, its strongest emission lines also include visible wavelengths such as violet, blue, green, and yellow.

Explanation: Mercury-vapor lamps provide significantly higher luminous efficacy (lumens per watt) and a much longer operational lifespan compared to traditional incandescent lamps.

Explanation: The luminous efficacy of mercury-vapor lamps typically falls within the range of 35 to 55 lumens per watt, indicating a moderate level of energy efficiency.

Explanation: Clear mercury lamps emit a greenish hue that is often considered unflattering to human skin tones and can distort the appearance of colors, making them unsuitable for retail environments.

Explanation: Color-corrected mercury lamps utilize a phosphor coating that converts ultraviolet emissions into red wavelengths, thereby enhancing spectral balance and improving color rendition.

Explanation: Mercury-vapor lamps require a warm-up period, generally ranging from four to seven minutes, prior to achieving their maximum light output.

Explanation: A significant disadvantage of mercury-vapor lamps is their narrow spectral output, which lacks sufficient red wavelengths, causing colors to appear unnatural or distorted.

Explanation: The spectral emission line of mercury vapor in the violet range is approximately 404.7 nm (designated as the H-line).

Explanation: Upon initial activation, a mercury-vapor lamp typically exhibits a dim, dark blue glow, indicative of the early stages of arc formation and mercury vaporization before full brightness is achieved.

Explanation: Mercury-vapor lamps exhibit 'negative resistance,' meaning their electrical resistance decreases as the current flowing through them increases. This characteristic necessitates a ballast.

Explanation: An electrical ballast is essential for standard mercury-vapor lamps. Due to their negative resistance characteristic, they cannot self-regulate current and would self-destruct without a ballast to limit it.

Explanation: Self-ballasted mercury-vapor lamps are designed with an integrated filament that functions as a ballast, thereby eliminating the need for an external ballast.

Explanation: Mercury-vapor lamps require a cooling period after a power interruption before they can restrike. The elevated internal pressure prevents immediate reignition.

Explanation: An electrical ballast is essential for standard mercury-vapor lamps to regulate the current flow, preventing the lamp from drawing excessive amperage due to its negative resistance characteristic.

Explanation: Mercury-vapor lamps exhibit negative resistance, meaning their resistance drops as current increases. A ballast is required to limit this current and prevent lamp destruction.

Explanation: Self-ballasted mercury-vapor lamps simplify installation as they incorporate an internal ballast, eliminating the requirement for an external ballast unit.

Explanation: Following a power interruption, the mercury-vapor lamp requires substantial cooling to reduce its internal pressure before it can restrike.

Explanation: Clear mercury-vapor lamps emit a greenish light that is generally considered unflattering to skin tones and merchandise, making them unsuitable for retail environments requiring accurate color rendering.

Explanation: Metal halide lamps are generally considered more efficient and offer superior color balance compared to mercury-vapor lamps, leading to their increasing adoption as replacements.

Explanation: The application of ultraviolet light from mercury-vapor lamps for water treatment was documented as early as 1910, predating the mid-20th century.

Explanation: To provide immediate illumination during the cooling and restriking phase of a mercury-vapor lamp, many fixtures incorporate a secondary backup lamp, frequently a halogen lamp of comparable brightness.

Explanation: Before the widespread adoption of phosphors for color correction, mercury-vapor lamps were often operated concurrently with incandescent lamps to supplement the red wavelengths and improve perceived color quality.

Explanation: Low-pressure sodium lamps are considered the most effective option for minimizing light pollution because they emit light in very narrow spectral lines, facilitating easier filtering.

Explanation: Manufacturers are producing LED bulbs specifically designed to be compatible with existing mercury-vapor fixtures, often without requiring modifications to the fixture.

Explanation: Mercury-vapor lamps are not commonly used for street lighting in Germany and France; their use is more prevalent in countries like the United States, Canada, and Japan.

Explanation: High-powered mercury-vapor lamps are commonly utilized in the printing industry for UV curing, a process employed to rapidly solidify and harden inks.

Explanation: Specialized ultra-high-pressure mercury-vapor lamps, designated as Ultra-high-performance (UHP) lamps, are frequently utilized as the light source in digital video projectors.

Explanation: The 'thermal shorting switch' in certain metal halide lamps serves to eliminate potential differences between electrodes after ignition, thereby preventing halide buildup on the starting electrode and protecting the glass-metal seal.

Explanation: Metal halide lamps are progressively supplanting mercury-vapor lamps due to their superior luminous efficacy and enhanced color balance.

Explanation: The application of ultraviolet light from mercury-vapor lamps for the purpose of water treatment was documented as early as 1910.

Explanation: Manufacturers produce replacement bulbs, including compact fluorescent (CFL) and light-emitting diode (LED) bulbs, designed for compatibility with existing mercury-vapor fixtures.

Explanation: Low-pressure sodium lamps are generally regarded as the optimal choice for minimizing light pollution due to their emission of light in highly narrow spectral lines, which facilitates more effective filtering.

Explanation: High-powered mercury-vapor lamps are commonly utilized in the printing industry for UV curing, a process employed to rapidly solidify and harden inks.

Explanation: Mercury-vapor lamps without phosphor coatings are regarded as the second most effective option for mitigating light pollution, following low-pressure sodium lamps, due to their relatively discrete spectral output.

Explanation: The 'thermal shorting switch' in certain metal halide lamps serves to eliminate potential differences between the main electrode and the starting electrode after the lamp has ignited, preventing damage to the glass-metal seal.

Explanation: High-pressure mercury-vapor lamps function as valuable and cost-effective sources in molecular spectroscopy, providing broadband continuum energy across millimeter and terahertz wavelengths, derived from their plasma's high electron temperature.

Explanation: The 185 nm ultraviolet emission line, which can pass through synthetic quartz, has the potential to create ozone in an oxygen-rich atmosphere, posing a health hazard.

Explanation: The European Union implemented a ban on low-efficiency mercury-vapor lamps for lighting purposes in 2015, not 2008.

Explanation: The ban on ballasts for general illumination mercury-vapor lamps in the United States became effective on January 1, 2008, excluding specialty applications.

Explanation: In 2015, the U.S. Department of Energy decided not to implement proposed regulations for mercury vapor HID lamps because they were not projected to yield substantial energy savings.

Explanation: The short-wave UV-C radiation emitted by the arc tube of mercury-vapor lamps poses a significant health risk, capable of causing burns to the skin and eyes.

Explanation: Breaking the outer glass jacket of a mercury lamp does not prevent UV exposure; in fact, it can increase the risk of exposure to hazardous UV-C radiation from the inner arc tube.

Explanation: Mercury-vapor lamps emit a considerable quantity of 365 nm ultraviolet radiation, which can degrade certain plastics, such as polycarbonate, leading to discoloration and a yellowed appearance over time.

Explanation: The short-wave UV-C radiation emitted by the arc tube of mercury-vapor lamps poses a health risk, capable of causing inflammation to the eyes and burns to the skin.

Explanation: The 365 nm ultraviolet radiation emitted by mercury-vapor lamps can degrade certain plastics, such as polycarbonate, leading to discoloration and a yellowed appearance over time.

Explanation: The European Union enacted a prohibition on the utilization of low-efficiency mercury-vapor lamps for lighting purposes in the year 2015.

Explanation: The ban on ballasts for general illumination mercury-vapor lamps in the United States became effective on January 1, 2008.

Explanation: The U.S. Department of Energy did not implement the proposed regulations for mercury vapor HID lamps because they were not projected to yield substantial energy savings.

Explanation: The 185 nm ultraviolet emission line, which can pass through synthetic quartz, has the potential to create ozone in an oxygen-rich atmosphere, posing a health hazard.