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title, date
| title | date |
|---|---|
| Thermodynamics, Scattered | 2024-11-10 |
A Couple of Equations
When it comes to energy transfer and phase changes there are only two useful equations.
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Specific Heat Equation: This equation is used to calculate the heat required to change the temperature of a substance without a phase change.
\Delta \textbf{KE}=Q = mc\Delta TQ= heat energy added or removed (in joules, J)m= mass of the substance (in kilograms, kg)c= specific heat capacity of the substance (in J/kg°C)\Delta T= change in temperature (in °C or K)
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Latent Heat (Potential Energy Buildup): This equation is used for phase changes, where energy changes the state of the substance (like melting or boiling) without changing its temperature.
\Delta \textbf{PE} = Q = mL- ( Q ) = heat energy added or removed (in joules, J)
- ( m ) = mass of the substance (in kilograms, kg)
- ( L ) = latent heat of the substance (in J/kg), which could be the latent heat of fusion (for melting/freezing) or vaporization (for boiling/condensing)
These equations together describe the heat energy required for changing the temperature of a substance and for changing its phase.
**It is important to note the alternate arrangement of both:
Q=nc_{\mathrm{mol}}\Delta T = \Delta \textbf{KE}
or for the other Latent Heat equation:
\Delta \textbf{PE} = Q = nL_{\mathrm{mol}}
nis the number of moles- the subscript
molnotates the same variable, but in units per mole. - ==You might see both==, at least they were both on the concept builders.
Black-body radiation
All objects/bodies emit electromagnetic radiation over a range of wavelengths. Cooler objects emit less radiation than warmer bodies, simply because of having less energy. An increase in temperature directly correlates with a smaller wavelength (\lambda), and a higher frequency (f or v).
Radiation being incident means that it strikes or falls upon a surface, object, or body. Radiation that is incident on an object is partially absorbed and partially reflected. Thermodynamic Equilibrium is a state in which a body emits radiation at the same rate that radiation hits it. Therefore, a good absorber of radiation is also a good emitter. A perfect absorber absorbs all E.M. radiation incident on it. Such an object is called a black body. This doesn't mean no energy is emitted, however. A black body remits the radiation it absorbs as a thermal radiation in a spectrum determined solely by its temperature.
The intensity of the remissions of a black body is given by a function defined so:
I(\lambda,T)
Where I is the power intensity that is radiated per unit of wavelength \lambda, per unit area of the black body. By multiplying the differential of \lambda:
I(\lambda, T)\mathrm{d}\lambda
Provides the power per unit area of the black body, from the interval \left[\lambda, \lambda + \mathrm{d}\lambda\right], given that \mathrm{d}\lambda is an infinitesimally small quantity.
Wien's displacement law.
Wien's law states the wavelength of peak intensity at a given temperature in Kelvin T is given by:
\lambda_{\text{peak}}=\frac{b}{T}
Where b is Wien's displacement constant, equal to 2.897771955\cdot 10^{-3} \mathrm{m}\cdot\mathrm{K}.
Note
The material does not matter. All black bodies emit radiation over all wavelengths.
Stefan Boltzmann Law of Radiation
This law describes the emissive power of a Black Body per unit area.
E_b=\varepsilon \sigma\cdot T^4
In the above equation,:
E_bis the Emissive Power of a black body, per unit time, per unit area.\varepsilonis the emissivity of an object\sigmais the Boltzmann constant, about\approx 5.670374419\cdot 10^{-8} \mathrm{W}\cdot\mathrm{m}^{-2}\cdot \mathrm{K}^{-4}- A perfect black body has an emissivity of
1, and an albedo of0 - always work in default SI units
If you desire the total power across the entirety of the surface:
P_b=A\varepsilon \sigma\cdot T^4
Where A is the area of the exposed surface.