Differences
This shows you the differences between two versions of the page.
| Both sides previous revisionPrevious revisionNext revision | Previous revision | ||
| courses:ast201:2 [2023/06/09 21:21] – [4.3 Spectrum analysis] asad | courses:ast201:2 [2023/10/04 00:39] (current) – [1. Probes in astronomy] asad | ||
|---|---|---|---|
| Line 3: | Line 3: | ||
| ===== - Probes in astronomy ===== | ===== - Probes in astronomy ===== | ||
| + | Astronomy deals with particles or waves of matter or energy coming from outer space. Many of the fundamental particles illustrated in the **standard model of particle physics** below can be found in space. | ||
| + | |||
| + | {{https:// | ||
| + | |||
| + | Quarks are not found in isolation, but in packets called protons or neutrons. We detect mostly protons from space using specialized detectors. Among the leptons, electrons and neutrinos are the most common particles found streaming through space. Quarks and leptons are particles of matter ([[wp> | ||
| + | |||
| + | The particles of energy or force carriers ([[wp> | ||
| + | |||
| + | Fermions are massive, bosons are massless. The two are described below in the context of observational astronomy. | ||
| ==== - Massive particles ==== | ==== - Massive particles ==== | ||
| Line 79: | Line 88: | ||
| ==== - As a particle ==== | ==== - As a particle ==== | ||
| + | From the beginning of the twentieth century, quantum mechanics claimed that there are situations where light cannot be described as a wave, but rather as a stream of particles called **photons**. | ||
| + | |||
| + | The energy of a photon, however, is related to the frequency of the light when it exhibits its wave property according to the equation | ||
| + | |||
| $$ E = h\nu = \frac{hc}{\lambda} $$ | $$ E = h\nu = \frac{hc}{\lambda} $$ | ||
| + | |||
| + | where $h=6.626\times 10^{-34}$ J s is Planck' | ||
| ==== - As a ray ==== | ==== - As a ray ==== | ||
| Photometry | Photometry | ||
| Line 129: | Line 144: | ||
| Now if we can resolve the source, the solid angle subtended by a spherical source of radius $a$ at a distance $r$ (when $a\ll r$) | Now if we can resolve the source, the solid angle subtended by a spherical source of radius $a$ at a distance $r$ (when $a\ll r$) | ||
| - | $$ \Omega \approx \frac{\pi a^2}{r^2}. $$ | + | $$ \Omega \approx \frac{\pi a^2}{r^2} $$ |
| - | Then the surface brightness | + | whose is angle is [[un: |
| $$ S = \frac{F_o}{\Omega} = \frac{F_s}{\pi} $$ | $$ S = \frac{F_o}{\Omega} = \frac{F_s}{\pi} $$ | ||
| Line 239: | Line 254: | ||
| which is shown in the units of nW sr$^{-1}$ m$^{-2}$ Hz$^{-1}$. | which is shown in the units of nW sr$^{-1}$ m$^{-2}$ Hz$^{-1}$. | ||
| - | [{{: | + | [[https:// |
| The same brightness can be represented as a function of wavelength as | The same brightness can be represented as a function of wavelength as | ||
| Line 247: | Line 262: | ||
| and the corresponding plot in the units of kW sr$^{-1}$ m$^{-2}$ nm$^{-1}$ is given below. | and the corresponding plot in the units of kW sr$^{-1}$ m$^{-2}$ nm$^{-1}$ is given below. | ||
| - | [{{: | + | [[https:// |
| \\ | \\ | ||
| - | Why total power emitted by a blackbody at all angles is $\pi B$? | + | Why total power emitted by a blackbody at all angles is $\pi S$? |
| At long wavelengths | At long wavelengths | ||
| Line 304: | Line 319: | ||
| For a star, we could write either $m_B=5.67$ or $B=5.67$ for the magnitude at B band. | For a star, we could write either $m_B=5.67$ or $B=5.67$ for the magnitude at B band. | ||
| + | |||
| + | [{{: | ||
| ==== - Absolute ==== | ==== - Absolute ==== | ||
| + | $$ m-M = 5\log(r)-5 $$ | ||
| + | |||
| + | where $M$ is the absolute magnitude and $r$ the distance in [[un: | ||
| + | |||
| + | ($m-M$) is called the **distance modulus** of a source. | ||
| + | |||
| + | The absolute magnitudes of the sun are $M_B=5.48$, $M_V=4.83$ and $M_{bol}=4.75$. | ||
| + | ==== - Brightness from image ==== | ||
| + | The size of a star in an image only depends on the telescope and the atmosphere, not on the star. All stars have the same size in an image. The flux | ||
| + | |||
| + | $$ F = \frac{1}{tA} \sum_{x, | ||
| + | |||
| + | where $S_{xy}$ is the value of the pixel $(x,y)$, the exposure time is $t$ and $A$ is the area of the camera lens (if the image is taken by a lens camera). | ||
| + | |||
| + | But $S_{xy}$ has two contributions: | ||
| + | |||
| + | $$ E_{xy} = S_{xy} - B_{xy}. $$ | ||
| + | |||
| + | Assuming $B_{xy}=B$, the average background noise in the image, the flux of the star | ||
| + | |||
| + | $$ F_\star = \frac{1}{tA} \sum_{x,y} (S_{xy}-B). $$ | ||
| + | |||
| + | Now if we take two pictures, one of our target star and another of Vega as a standard star, then we can measure the magnitude of the target star with respect to Vega as | ||
| + | |||
| + | $$ m_\star-m_{Vega} = -2.5 \log_{10} \frac{F_\star}{F_{Vega}} = -2.5 \log_{10} \frac{\sum (S_{xy}-B)_\star}{\sum (S_{xy}-B)_{Vega}}. $$ | ||
| + | |||
| + | Instead of Vega we can use any other standard star. | ||
| + | |||
| + | - Differential photometry: two stars on the same image. | ||
| + | - All-sky photometry: two stars on different images. | ||
| + | |||
| - | ==== - Brightness from magnitude ==== | ||
courses/ast201/2.1686367299.txt.gz · Last modified: 2023/06/09 21:21 by asad