about the body properties. To measure the properties of this radiation, a collector is used, followed by a detector.
The collector is a collecting aperture which intercepts part of the radiated field. In microwave, an antenna is used to intercept some of the electromagnetic energy. Examples of antennas include dipoles, an array of dipoles, or dishes. In the case of dipoles, the surrounding field generates a current in the dipole with an intensity proportional to the field intensity and a frequency equal to the field frequency. In the case of a dish, the energy collected is usually focused onto a limited area where the detector (or waveguide connected to the detector) is located.
In the IR, visible, and UV regions, the collector is usually a lens or a reflecting surface which focuses the intercepted energy onto the detector. Detection then occurs by transforming the electromagnetic energy into another form of energy such as heat, electric current, or state change.
Depending on the type of the sensor, different properties of the field are measured. In the case of synthetic aperture imaging radars, the amplitude, polarization, frequency, and phase of the fields are measured at successive locations along the flight line. In the case of optical spectrometers, the energy of the field at a specific location is measured as a function of wavelength. In the case of radiometers, the main parameter of interest is the total radiant energy flux. In the case of polarimeters, the energy flux at different polarizations of the wave vector is measured.
In the case of x‐ray and gamma‐ray detection, the detector itself is usually the collecting aperture. As the particles interact with the detector material, ionization occurs, leading to light emission or charge release. Detection of the emitted light or generated current gives a measurement of the incident energy flux.
2.5 Interaction of Electromagnetic Waves with Matter: Quick Overview
The interaction of electromagnetic waves with matter (e.g., molecular and atomic structures) calls into play a variety of mechanisms which are mainly dependent on the frequency of the wave (i.e., its photon energy) and the energy level structure of the matter. As the wave interacts with a certain material, be it gas, liquid, or solid, the electrons, molecules, and/or nuclei are put into motion (rotation, vibration, or displacement), which leads to exchange of energy between the wave and the material. This section gives a quick simplified overview of the interaction mechanisms between waves and matter. Detailed discussions are given later in the appropriate chapters throughout the text.
Atomic and molecular systems exist in certain stationary states with well‐defined energy levels. In the case of isolated atoms, the energy levels are related to the orbits and spins of the electrons. These are called the electronic levels. In the case of molecules, there are additional rotational and vibrational energy levels which correspond to the dynamics of the constituent atoms relative to each other. Rotational excitations occur in gases where molecules are free to rotate. The exact distribution of the energy levels depends on the exact atomic and molecular structure of the material. In the case of solids, the crystalline structure also affects the energy levels’ distribution.
In the case of thermal equilibrium, the density of population Ni at a certain level i is proportional to (Boltzmann’s law):
(2.39)
where Ei is the level energy, k is Boltzmann’s constant, and T is the absolute temperature. At absolute zero all the atoms will be in the ground state. Thermal equilibrium requires that a level with higher energy be less populated than a level of lower energy (Fig. 2.13).
To illustrate, for T = 300 K, the value for kT is 0.025 eV (one eV is 1.6 × 10−19 joules). This is small relative to the first excited energy level of most atoms and ions, which means that very few atoms will be in the excited states. However, in the case of molecules, some vibrational and many rotational energy levels could be even smaller than kT, thus allowing a relatively large population in the excited states.
Figure 2.13 Curve illustrating the exponential decrease of population as a function of the level energy for the case of thermal equilibrium.
Let us assume a wave of frequency ν is propagating in a material where two of the energy levels i and j are such that
(2.40)
This wave would then excite some of the population of level i to level j. In this process, the wave loses some of its energy and transfers it to the medium. The wave energy is absorbed. The rate pij of such an event happening is equal to:
(2.41)
where ℰν is the wave energy density per unit frequency and Bij is a constant determined by the atomic (or molecular) system. In many texts, pij is also called transition probability.
Once exited to a higher level by absorption, the atoms may return to the original lower level directly by spontaneous or stimulated emission, and in the process they emit a wave at frequency ν, or they could cascade down to intermediate levels and in the process emit waves at frequencies lower than ν (see Fig. 2.14). Spontaneous emission could occur any time an atom is at an excited state independent of the presence of an external field. The rate of downward transition from level j to level i is given by
(2.42)
where Aji is characteristic of the pair of energy levels in question.
Stimulated emission corresponds to downward transition which occurs as a result of the presence of an external field with the appropriate frequency. In this case the emitted wave is in phase with the external field and will add energy to it coherently. This results in an amplification of the external field and energy transfer from the medium to the external field. The rate of downward transition is given by
(2.43)
Figure 2.14 An incident wave of frequency νij is adsorbed due to population excitation from Ei to Ej. Spontaneous emission for the above system can occur at νij as well as by cascading down via the intermediate levels l and k.
The relationships between Aji, Bji, and Bij are known as the Einstein’s relations:
(2.44)
