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We get a bunch of thermometers.It would be a dumb choice but, just to make the point, we can use a mercury thermometer, an alcohol thermometer a gallium thermometer, a water thermometer and a hexane thermometer.
In clear air, what's the typical range of microwave radar?
Depends on the radiated peak power, and is only limited by the horizon.
Being unaware of these effects can lead to erroneous measurement values.
But you seem un\aware of the fact that a spinning magnet in air will heat the air, thus disturbing the equilibrium.
And, if it's not at equilibrium, it doesn't have a properly defined temperature.
Quote from: Bored chemist on 03/01/2025 23:00:36But you seem un\aware of the fact that a spinning magnet in air will heat the air, thus disturbing the equilibrium.You seem to be unaware that as an example, I put the spinning magnet inside a vacuum glass box. There will be no friction between the air and the spinning magnet. But the spinning magnet can still generate heat in nearby metals by inducing Eddy current.
Quote from: Bored chemist on 03/01/2025 23:00:36And, if it's not at equilibrium, it doesn't have a properly defined temperature.Does the surface of the sun have a properly defined temperature?Does the corona of the sun have a properly defined temperature?
If the magnet is spinning then viscous dag will heat the air near to it.And then it won't be at equilibrium any more.
Quote from: Bored chemist on 03/01/2025 22:57:00If the magnet is spinning then viscous dag will heat the air near to it.And then it won't be at equilibrium any more.We tend to consider the boundary layer a stationary in laminar viscous flow. And it would be a pity if Joule's determination of the mechanical equivalent of heat by stirring water was seriously wrong - his result was within 0.75% of the current value.
But, in principle, your spinning magnet warms it up a bit.
I started this thread in new theory section because I found that currently available explanations are not satisfactory and contains many caveats. I wondered if it can be improved. Quotehttps://en.m.wikipedia.org/wiki/TemperatureTemperature is a physical quantity that quantitatively expresses the attribute of hotness or coldness. Temperature is measured with a thermometer. It reflects the average kinetic energy of the vibrating and colliding atoms making up a substance.... When two systems in thermal contact are at the same temperature no heat transfers between them. When a temperature difference does exist heat flows spontaneously from the warmer system to the colder system until they are in thermal equilibrium. Such heat transfer occurs by conduction or by thermal radiation.[45][46][47][48][49][50][51][52]Experimental physicists, for example Galileo and Newton,[53] found that there are indefinitely many empirical temperature scales. Nevertheless, the zeroth law of thermodynamics says that they all measure the same quality. This means that for a body in its own state of internal thermodynamic equilibrium, every correctly calibrated thermometer, of whatever kind, that measures the temperature of the body, records one and the same temperature. For a body that is not in its own state of internal thermodynamic equilibrium, different thermometers can record different temperatures, depending respectively on the mechanisms of operation of the thermometers.From the underlined statement, we need to define what counts as thermal contact. Also, what counts as heat transfer and thermal equilibrium.
https://en.m.wikipedia.org/wiki/TemperatureTemperature is a physical quantity that quantitatively expresses the attribute of hotness or coldness. Temperature is measured with a thermometer. It reflects the average kinetic energy of the vibrating and colliding atoms making up a substance.... When two systems in thermal contact are at the same temperature no heat transfers between them. When a temperature difference does exist heat flows spontaneously from the warmer system to the colder system until they are in thermal equilibrium. Such heat transfer occurs by conduction or by thermal radiation.[45][46][47][48][49][50][51][52]Experimental physicists, for example Galileo and Newton,[53] found that there are indefinitely many empirical temperature scales. Nevertheless, the zeroth law of thermodynamics says that they all measure the same quality. This means that for a body in its own state of internal thermodynamic equilibrium, every correctly calibrated thermometer, of whatever kind, that measures the temperature of the body, records one and the same temperature. For a body that is not in its own state of internal thermodynamic equilibrium, different thermometers can record different temperatures, depending respectively on the mechanisms of operation of the thermometers.
The common temperature of incandescent lamps typically refers to their color temperature, which is measured in Kelvin (K). It usually falls in the range of:2,700 K to 3,000 K: This gives off a warm white or yellowish light, resembling traditional incandescent lighting.3,200 K: Often used in photography and studio lighting, providing a slightly cooler white light.In terms of operating temperature, the filament inside an incandescent lamp can reach 2,500 to 3,000?C (4,500 to 5,400?F) when glowing. The surface of the bulb itself is much cooler but still quite hot, often around 150 to 250?C (300 to 480?F) depending on the wattage.
Yes, the spectrum of incandescent lamps is very similar to black body radiation because the light is produced by heating a tungsten filament to high temperatures.Here?s how they compare:1. Black Body Radiation:A black body is an idealized physical body that absorbs all incident radiation and emits a spectrum of radiation based solely on its temperature.Its spectrum is continuous, with a peak wavelength determined by the Planck radiation law.2. Incandescent Lamps:The tungsten filament closely approximates a black body because it emits light due to being heated to 2,500?3,000 K.The spectrum is continuous, covering visible light and extending into the infrared (IR), which is why these lamps are inefficient as a significant portion of energy is emitted as heat (IR radiation).However, the spectrum of an incandescent lamp is not a perfect black body due to:Material properties: The tungsten filament isn't an ideal black body, so its emissivity deviates slightly.Glass envelope: The bulb's material can absorb some of the emitted light, especially UV radiation.Overall, incandescent lamps are a practical approximation of black body radiation in the visible and near-IR regions.
The typical glass material used in incandescent lamps is soda-lime glass or borosilicate glass, depending on the application:1. Soda-Lime Glass:Commonly used for standard incandescent bulbs.Composed primarily of silica (SiO₂), sodium oxide (Na₂O), and calcium oxide (CaO).Suitable for general-purpose bulbs due to its affordability and ease of production.Not highly resistant to heat or thermal shock but adequate for the temperatures of most incandescent lamps.2. Borosilicate Glass:Used in specialized bulbs (e.g., high-wattage or heat lamps).Contains silica and boron oxide (B₂O₃), making it more resistant to heat and thermal shock.Common in applications where higher durability and temperature resistance are required.The choice of glass also depends on whether the bulb is designed to withstand specific conditions, such as higher operating temperatures, pressure, or exposure to chemicals.
The transmission of infrared (IR) radiation through the glass of an incandescent lamp depends on the type of glass used and the wavelength of the IR radiation. Here's a general breakdown:1. Soda-Lime Glass:IR Transmission: Poor for wavelengths beyond 2.5 ?m (mid to far-infrared).Glass absorbs most of the longer-wavelength IR radiation emitted by the filament.However, shorter wavelengths in the near-infrared range (0.8?2.5 ?m) can partially pass through soda-lime glass.2. Borosilicate Glass:IR Transmission: Slightly better than soda-lime glass for near-infrared radiation but still limited for mid- and far-IR wavelengths.Its improved heat resistance allows it to handle high temperatures without significant structural degradation.Efficiency:A significant portion (up to 85?90%) of the energy from an incandescent lamp is emitted as IR radiation, but much of this is absorbed or reflected back by the glass.To improve IR management, special coatings (e.g., dichroic reflectors) are sometimes applied to allow visible light through while reflecting or absorbing IR radiation.If precise IR transmission values are needed, these depend on the exact glass composition and thickness, which can vary between manufacturers and specific lamp designs.
The ratio of absorbed and reflected infrared (IR) radiation by the glass in an incandescent lamp depends on the type and thickness of the glass, as well as the IR wavelength. Here's a general overview:1. Soda-Lime Glass:Reflection: About 4?8% of IR radiation at each surface (depending on the angle of incidence and wavelength).For typical soda-lime glass, near-IR wavelengths (0.8?2.5 ?m) reflect less than mid- and far-IR radiation.Absorption: The majority of IR radiation (>80?90%) is absorbed for wavelengths above 2.5 ?m.Soda-lime glass strongly absorbs longer wavelengths in the mid-IR and far-IR range, converting them into heat.2. Borosilicate Glass:Reflection: Similar to soda-lime glass, reflecting about 4?8% per surface.Absorption: Less absorption in the near-IR range compared to soda-lime glass but still absorbs strongly in the mid- and far-IR range.Slightly better transmission in the near-IR spectrum (0.8?2.5 ?m) than soda-lime glass.Overall Ratio:For incandescent bulbs with soda-lime glass:About 85?95% of IR radiation is absorbed.About 5?15% of IR radiation is reflected.The exact distribution depends on the thickness and coatings on the glass.For specialized applications, glass coatings (like low-emissivity or dichroic coatings) can be applied to alter this ratio, increasing reflectance to reduce heat loss or improving IR transmission for specific uses.
When two systems in thermal contact are at the same temperature no heat transfers between them. When a temperature difference does exist heat flows spontaneously from the warmer system to the colder system until they are in thermal equilibrium. Such heat transfer occurs by conduction or by thermal radiation.[45][46][47][48][49][50][51][52]
I spent several years working on "dynamic equilibrium" calorimeters for measuring ionising radiation dose rates. Long story but it was a cunning way of measuring millidegree temperature changes to better than 0.1% precision.The classic Callendar and Barnes continuous flow water calorimeter uses a similar principle.
Note that objects heated by radiation from incandescent lamps can have higher temperature than the glass surface of the lamps. This pose question about thermal contact. Is exchange of kinetic energy through radiation counted as thermal contact?
If you put a mirror round the bulb so that all the radiation was reflected back then the glass would reach thermal equilibrium with the filament. (And it would melt)
But a bit like the Calender and Barnes continuous flow water calorimeter, the heat is continuously carried away from the glass (by the air round it, and by emission of IR) , so it never reaches the same temperature as the filament.It never reaches equilibrium.
Paradoxically, even though quartz glass is nearly opaque to far IR radiation quartz halogen lamps were sometimes used as the "light" source for far IR spectroscopy.The radiation used was actually that emitted from the quartz envelope.