thresholdless lasers (original) (raw)
Author: the photonics expert (RP)
Definition: lasers with a threshold power which is virtually zero
Categories: 
laser devices and laser physics, 
quantum photonics
- laser physics
- cooperative lasing
- gain efficiency
- in-band pumping
- gain narrowing
- gain saturation
- Kuizenga–Siegman theory
- laser dynamics
- laser gain media
- laser transitions
- laser threshold
- lasing without inversion
- linewidth enhancement factor
- lower-state lifetime
- McCumber theory
- metastable states
- mode competition
- mode hopping
- modes of laser operation
- multiphonon transitions
- non-radiative transitions
- optical pumping
- output coupling efficiency
- parasitic lasing
- population inversion
- pulse generation
- radiation-balanced lasers
- radiative lifetime
- rate equation modeling
- reciprocity method
- relaxation oscillations
- single-frequency operation
- single-mode operation
- slope efficiency
- spatial hole burning
- spiking
- Stark level manifolds
- stimulated emission
- threshold pump power
- thresholdless lasers
- transition cross-sections
- twisted-mode technique
- ultrafast laser physics
- upconversion
- upper-state lifetime
- wavelength tuning
- (more topics)
Related: laser thresholdthreshold pump powervertical cavity surface-emitting laserssingle-atom lasers
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DOI: 10.61835/fsb Cite the article: BibTex BibLaTex plain textHTML Link to this page! LinkedIn
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What is a Thresholdless Laser?
A thresholdless laser is a laser where the threshold pump power is essentially zero. Such a device was proposed by Kobayashi et al. in 1982 [1]. An essential point of that concept is that the spontaneous emission is forced to occur primarily into the spatial mode defined by the laser resonator (while normally most of it goes into other radiation modes). This is possible with a microcavity around the (microscopically small) gain medium, which modifies the mode structure of the environment of the gain medium. Even if there are several suitable modes, emission into the laser mode can be dominating if that mode has the highest Q-factor.
Experimentally, some lasers with very low threshold powers based on this principle have been demonstrated, e.g. a vertical cavity surface-emitting laser with a threshold current of only 36 μA [4] and a photonic crystal nanolaser with a threshold pump power of 1.2 μW [8]. Another technical approach is the single-atom laser [7], which was demonstrated in 2003, and indeed exhibited a zero threshold pump power. In that case, even more subtle quantum optics phenomena are behind the thresholdless behavior.
Bibliography
| [1] | T. Kobayashi et al., “Novel-type lasers, emitting devices, and functional optical devices by controlling spontaneous emission”, presented at the 46th Fall Meeting of the Japanese Applied Physics Society, 1982, paper 29a-B-6 (in Japanese) |
|---|---|
| [2] | E. Yablonovitch and T. J. Gmitter, “Inhibited spontaneous emission in solid state physics and electronics”, Phys. Rev. Lett. 58 (20), 2059 (1987); doi:10.1103/PhysRevLett.58.2059 |
| [3] | H. Yokoyama and S. D. Brorson, “Rate equation analysis of microcavity lasers”, J. Appl. Phys. 66 (10), 4801 (1989); doi:10.1063/1.343793 |
| [4] | D. L. Huffaker and D. G. Deppe, “Improved performance of oxide-confined vertical-cavity surface-emitting lasers using a tunnel injection active region”, Appl. Phys. Lett. 71, 1449 (1997); doi:10.1063/1.119933 |
| [5] | J. M. Gérard and B. Gayral, “Strong Purcell effect for InAs quantum boxes in three-dimensional solid-state microcavities”, IEEE J. Lightwave Technol. 17 (11), 2089 (1999); doi:10.1109/50.802999 |
| [6] | I. Protsenko et al., “Quantum theory of a thresholdless laser”, Phys. Rev. A 59 (2), 1667 (1999); doi:10.1103/PhysRevA.59.1667 |
| [7] | J. McKeever et al., “Experimental realization of a one-atom laser in the regime of strong coupling”, Nature 425, 268 (2003); doi:10.1038/nature01974 |
| [8] | K. Nozaki et al., “Room temperature continuous wave operation and controlled spontaneous emission in ultrasmall photonic crystal nanolaser”, Opt. Express 15 (12), 7506 (2007); doi:10.1364/OE.15.007506 |
(Suggest additional literature!)
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