Examples of thermal radiation in the following topics:
-
- Let's imagine a blackbody enclosure, and we stick some material inside the enclosure and wait until it reaches equilibrium with the radiation field, $I_\nu = B_\nu(T)$.
- $\displaystyle \text{Another Kirchoff's Law: }S_\nu = B_\nu(T) \text{ for a thermal emitter}$
- Because $I_\nu=B_\nu(T)$ outside of the thermal emitting material and $S_\nu=B_\nu(T)$ within the material, we find that $I_\nu=B_\nu(T)$ through out the enclosure.
- If we remove the thermal emitter from the blackbody enclosure we can see the difference between thermal radiation and blackbody radiation.
- A thermal emitter has $S_\nu = B_\nu(T)$,$B_\nu(T)$ so the radiation field approaches $B_\nu(T)$ (blackbody radiation) only at large optical depth.
-
- We are going to set the stage for a deeper look at astrophysical sources of radiation by defining the important concepts of radiative transfer, thermal radiation and radiative diffusion.
- One can make a large amount of progress by realizing that the distances that radiation typically travels between emission and detection or scattering etc. are much longer than the wavelength of the radiation.
-
- This range of wavelengths corresponds to a frequency range of approximately 300 GHz to 400 THz, and includes most of the thermal radiation emitted by objects near room temperature.
- Unlike heat transmitted by thermal conduction or thermal convection, radiation can propagate through a vacuum.
- Humans, their surroundings, and the Earth itself emit most of their thermal radiation at wavelengths near 10 microns, the boundary between mid and far infrared according to the delineation above.
- The range of wavelengths most relevant to thermally emitting objects on earth is often called the thermal infrared.
- Many astronomical objects emit detectable amounts of IR radiation at non-thermal wavelengths.
-
- The greenhouse effect is an elevation in surface temperatures due to atmospheric gases absorbing and re-radiating thermal energy.
- This thermal radiation from the surface has a much longer wavelength than the solar radiation that was initially absorbed.
- The majority of gases in the atmosphere, such as nitrogen, oxygen, and argon, cannot absorb this infrared radiation.
- Greenhouse gases then re-radiate this energy back to Earth, elevating atmospheric temperatures even when the surface is not being directly irradiated by the sun.
- The cloud layer can also absorb infrared radiation and contribute further to the greenhouse effect.
-
- Blackbody radiation is a radiation field that is in thermal equilibrium with itself.
- In general we will find it convenient to think about radiation that is in equilibrium with some material or its enclosure.
- Using detailed balance between two enclosures in equilibrium with each other and the enclosed radiation we can quickly derive several important properties of blackbody radiation.
- The intensity ($I_\nu$) of blackbody radiation does not depend on the shape, size or contents of the enclosure.
-
- ., if the radiating particles do not have a Maxwellian distribution) one has to use the full expression for the source function; a power-law distribution often occurs astrophysically.
- An extreme example of non-thermal emission is the maser.For atoms in thermodynamic equilibrium we have
- This yields a negative absorption coefficient, so the optical depth decreases and becomes negative as one passes through a region with inverted populations and the intensity of the radiation actually increases exponentially as the magnitude of the optical depth increases.
-
- A black body emits radiation called black body radiation.
- Planck described the radiation by assuming that radiation was emitted in quanta.
- A black body in thermal equilibrium (i.e. at a constant temperature) emits electromagnetic radiation called black body radiation.
- Max Planck, in 1901, accurately described the radiation by assuming that electromagnetic radiation was emitted in discrete packets (or quanta).
- Contrary to the common belief that electromagnetic radiation can take continuous values of energy, Planck introduced a radical concept that electromagnetic radiation was emitted in discrete packets (or quanta) of energy.
-
- Ionizing radiation from fallout can cause genetic effects, birth defects, cancer, cataracts, and other organ and tissue defects.
- Initial stage: the first 1–9 weeks; the period with the greatest number of deaths—90 percent due to thermal injury and/or blast effects and 10 percent due to super-lethal radiation exposure.
- Intermediate stage: from 10–12 weeks; deaths in this period are from ionizing radiation in the median lethal range.
- By directly or indirectly ionizing, radiation can affect a cell's ability to conduct repair and reproduction.
- Recognize the name of the genetic defect that has been shown to be caused by acute radiation exposure during pregnancy
-
- The Zeroth Law of Thermodynamics states that systems in thermal equilibrium are at the same temperature.
- Even if two objects don't touch, heat may still flow between them, such as by radiation (as from a heat lamp).
- If A and C are in thermal equilibrium, and A and B are in thermal equilibrium, then B and C are in thermal equilibrium.
- Temperature is the quantity that is always the same for all systems in thermal equilibrium with one another.
- The double arrow represents thermal equilibrium between systems.
-
- In these examples, heat is transferred by radiation.
- There is a clever relation between the temperature of an ideal radiator and the wavelength at which it emits the most radiation.
- The rate of heat transfer by emitted radiation is determined by the Stefan-Boltzmann law of radiation:
- A black object is a good absorber and a good radiator, while a white (or silver) object is a poor absorber and a poor radiator.
- The visible light, although dramatic, transfers relatively little thermal energy.