Abstract
This paper introduces a harmonic oscillator model for rovibronic terahertz spectrum of a model of a rigid diatomic rotor with some control parameters. The model shows a study of rotationally-resolved terahertz band spectra of the vibrational transition in diatomic molecules. THz radiation absorption is used as a closed-form system known as the analog computer dynamics mode. The optical terahertz region spectrum of the diatomic molecule consists of a series of lines. Their separations are not exactly constant. A diatomic molecule is not truly a rigid rotator, because it simultaneously vibrates with a small amplitude. Due to quantized vibrational and rotational energy levels and the selection rules, allowed transitions result in a highly ordered spectrum consisting of a P branch separated by a central gap. Adjacent spectral lines are separated by a spacing of 2B, and since line intensities depend on Boltzmann factor for thermal population and quantum number J, each branch monotonically increases and decreases. As temperature increases, more lines are observed, and line intensities decrease due to the population being spread over more rotational levels. Interactivity research also involves on effects of the fundamental vibrational frequency, rotational constant B and temperature included line width on the observed spectrum.
Highlights
Half of the cosmic background from the Big Bang is in the THz part of the spectrum [1,2,11]
This model shows a result of the study of rotationally-resolved terahertz band spectra of the v0 → v1 vibrational transition in diatomic molecules
The interaction of terahertz radiation with molecules in spectroscopy process is a rich source of information concerning the size, shape, and electron distribution within molecules
Summary
Half of the cosmic background from the Big Bang is in the THz part of the spectrum [1,2,11]. The interaction of terahertz radiation with biological tissues which is structured from organic atoms and molecules provides an important of probing into their structures. The result of this interaction for a wide range of terahertz spectrum radiation can yield useful bio-molecular information [8,9,10]. Results of theoretical computation will yield information concerning the mass of the diatomic molecule, stiffness or rigidity of chemical bonds, and vibrational amplitude. Predictions of these models will be compared with experimental studies
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