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Molecular Spectroscopy: Absorption and Emission01:14

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Molecules possess discrete energy levels called quantum states. Unlike atoms, which have simpler energy levels, molecules possess additional rotational and vibrational energy levels.  Each energy level is separated by an energy gap, with the gaps between adjacent electronic, vibrational, and rotational levels varying significantly. The three types of energy levels in a diatomic molecule are shown in Figure 1.
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Shortly after de Broglie published his ideas that the electron in a hydrogen atom could be better thought of as being a circular standing wave instead of a particle moving in quantized circular orbits, Erwin Schrödinger extended de Broglie’s work by deriving what is now known as the Schrödinger equation. When Schrödinger applied his equation to hydrogen-like atoms, he was able to reproduce Bohr’s expression for the energy and, thus, the Rydberg formula governing hydrogen spectra.
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Atomic spectroscopy is a vital tool in elemental analysis, both qualitatively and quantitatively. It can be broadly divided into optical spectroscopy, mass spectroscopy, and X-ray spectroscopy methods. The optical spectroscopic methods are atomic absorption spectroscopy (AAS), atomic emission spectroscopy (AES), and atomic fluorescence spectroscopy (AFS). The first step in all three methods is atomization, where the solid, liquid, or solution-phase samples are converted into gas-phase atoms and...
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Luminescence, the emission of light by a substance that has absorbed energy, is a process that involves the interaction of molecules with light. The energy-level diagram, or Jablonski diagram, is a graphical representation of these interactions, illustrating the various states and transitions a molecule can undergo. In a typical Jablonski diagram, the lowest horizontal line represents the ground-state energy of the molecule, which is usually a singlet state. This state represents the energies...
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UV–Vis Spectroscopy: Molecular Electronic Transitions01:16

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In Ultraviolet–Visible (UV–Vis) spectroscopy, the absorption of electromagnetic radiation is used to probe the electronic structure of molecules. This technique provides insights into molecular electronic transitions, particularly the movement of electrons between different molecular orbitals. Radiation is absorbed if the energy of the electromagnetic radiation passing through the molecule is precisely equal to the energy difference between the excited and ground states. During this...
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In the macroscopic world, objects that are large enough to be seen by the naked eye follow the rules of classical physics. A billiard ball moving on a table will behave like a particle; it will continue traveling in a straight line unless it collides with another ball, or it is acted on by some other force, such as friction. The ball has a well-defined position and velocity or well-defined momentum, p = mv, which is defined by mass m and velocity v at any given moment. This is the typical...
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Updated: Oct 21, 2025

Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators
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Entangled two-photon absorption by atoms and molecules: A quantum optics tutorial.

Michael G Raymer1, Tiemo Landes1, Andrew H Marcus2

  • 1Department of Physics, University of Oregon, Eugene, Oregon 97403, USA.

The Journal of Chemical Physics
|September 2, 2021
PubMed
Summary
This summary is machine-generated.

This study explores quantum-enhanced molecular spectroscopy using entangled photon pairs for two-photon absorption (TPA). It details how quantum light influences TPA rates, offering potential for enhanced molecular analysis.

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Area of Science:

  • Quantum optics
  • Molecular spectroscopy
  • Nonlinear optics

Background:

  • Two-photon absorption (TPA) and nonlinear molecular interactions with entangled photons show promise for quantum-enhanced spectroscopy.
  • Understanding the quantum nature of light is crucial for these applications.

Purpose of the Study:

  • To theoretically investigate one- and two-photon absorption by molecules using quantum light.
  • To analyze how quantum states of light affect molecular optical response.
  • To quantify the enhancement of TPA rates using entangled photon pairs.

Main Methods:

  • Review of basic quantum optics theory.
  • Density-matrix (Liouville) derivation of molecular optical response.
  • Detailed treatment of TPA using photon pairs from spontaneous parametric down-conversion.

Main Results:

  • Quantum light TPA differs significantly from classical light TPA.
  • Entangled states can enhance TPA rates, with specific quantification provided.
  • Comparison of TPA via far-off-resonant and dephasing-assisted off-resonant intermediate states.

Conclusions:

  • Theoretical framework established for quantum-enhanced TPA.
  • Demonstrated potential for significant TPA rate enhancement using entangled photons.
  • Identified challenges for experimental realization of entangled two-photon absorption.