Abstract:
A selective emitter pumped rare earth laser provides an additional type of laser for use in many laser applications. Rare earth doped lasers exist which are pumped with flashtubes or laser diodes. The invention uses a rare earth emitter to transform thermal energy input to a spectral band matching the absorption band of a rare earth in the laser in order to produce lasing.

Description:
The invention described herein was made by employees of the United States Government and may be manufactured and used by or for the Government for Government purposes without the payment of any royalties thereon or therefor. 
     BACKGROUND OF THE INVENTION 
     This invention relates to lasers and in particular to lasers thermally pumped using rare earth selective emitters. 
     Selective emitters are devices for converting thermal energy into narrow band radiation. Most solid state materials have nearly a constant spectral emittance (gray body). The spectral emittance of a rare earth is characterized by several emission bands in the visible and near infrared region resulting from electronic transitions from the lowest excited states. 
     Selective emitters have been used in thermophotovoltaic energy conversion systems such as those described in U.S. Pat. Nos. 4,584,426 and 5,080,724. 
     Lasing in rare earths such as neodymium (Nd), holmium (Ho) and erbium (Er) in a host material such as yttrium aluminum garnet (YAG, Y 3 Al 5 O 12 ) has been achieved using flashlamp or laser diode pumping. 
     SUMMARY OF THE INVENTION 
     A laser includes an emitter having a selective energy emission band in response to applied thermal energy and a rare earth doped laser rod having an energy absorption band matching the emission band. The emitter and the rod are arranged to allow energy from the emitter to impinge on the rod. 
     Using a selective emitter allows thermal energy to be used as the input for the rare earth ion laser. Not only does using a selective emitter allow thermal energy to be the input, but it also results in higher laser efficiency than flashlamp or diode laser pumped rare earth ion lasers. Both the flashlamp and diode laser pumping mechanisms are not as efficient at converting the input energy to radiation matched to the absorption band of the laser medium. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a perspective schematic view of a laser according to one aspect of the invention. 
     FIG. 2 is a top plan view of a laser according to another aspect of the invention with portions cut away. 
     FIG. 3 is a front elevation view of the laser of FIG. 2 with portions cut away. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to FIG. 1, a laser  10  or optical amplifier includes a circular cylindrical laser rod  12  and a circular cylindrical selective emitter  14 . The rod  12  and the emitter  14  are located at respective foci of an elliptical cylindrical laser cavity  16 . The internal walls of the cavity  16  are reflective and in the preferred embodiment the cavity  16  is under a vacuum. 
     A resistive heater  18  is located at the axis of the emitter  14 . The heater  18  may be a refractory metal (e.g., molybdenum). The heater  18  preferably has a polished surface to minimize emittance from its surface. In the preferred embodiment, the emitter  14  is segmented into a series beads to minimize thermal stresses. As is known in the art, a mirror and window are provided at each end of the rod  12 . 
     The rod  12  is composed of a crystal doped with a rare earth element and may be, for example, two millimeters in diameter and may include an attached unshown cooling fin. 
     The emitter  14  is composed of a selective emitting material that has a selective energy emission band in response to applied thermal energy. The emitter  14  may be, for example, Tm-YAG (Tm x , Y 3-x Al 5 O 12 ), thulium aluminum garnet (Tm 3  Al 5 O 12 ) or thulium oxide (Tm 2 O 3 ). The material of the emitter  14  may be either polycrystalline or a single crystal. 
     In operation, an electrical current from an unshown source is passed through the heater  18  causing the emitter  14  to heat and emit in the selective energy emission band characteristic to the particular emitter material. Because of the elliptical shape of the cavity  16 , except for end losses, all or substantially all of the radiation that leaves the emitter  14  impinges upon the rod  12 . 
     The rod  12  is doped with a rare earth having an energy absorption band matching the emission band of the emitter  14  (e.g., the emitter  14  and the rod  12  contain the same rare earth, for example, thulium). The absorbed radiation will produce excited states in the rod  12 , producing a population inversion between an energy level in the first excited state manifold and an energy level in the ground state manifold, and thus lasing in the rod  12 . For a rod  12  doped with just a single rare earth such as thulium, the emitter  14  may have to be operated at a temperature of greater than 2500° K for the laser  10  to operate. 
     In the preferred embodiment, the rod  12  is doped with more than one rare earth. In this case, one rare earth serves as the energy absorber and corresponds to the emission band of the emitter  14 . A second rare earth is the laser species. The population inversion is produced by energy transfer from the absorber rare earth to the lasing rare earth. For example, the rod  12  may be composed of Tm-Ho-YAG (Tm x , Ho y , Y 3-x-y Al 5 O 12 ) or Tm-Ho-YLF (yttrium lithium fluoride) (Tm x , Ho y , Y 1-x-y LiF). The Tm doping level (x) should be large while the Ho doping level (y) should be low in order to produce a population inversion in the Ho for emitter  14  temperatures of approximately 2000° K. 
     In order to keep the lower laser level density low, the laser rod  12  must be kept relatively cool. This can be accomplished by a combination of the vacuum in the cavity  16  and a thermal connection such as an unshown longitudinal rib between the rod  12  and the cavity  16  which is in turn cooled by a suitable means. 
     Referring to FIGS. 2 and 3, an additional embodiment of the laser  10 ′ includes a laser rod  12 , and selective emitters  14 ′. The rod  12  is contained in an evacuated chamber  22  that allows energy from the emitters  14 ′ to impinge on the rod  12 . The chamber  22  may be, for example, composed of sapphire. A coolant line  24  is in thermal contact with the rod  12 . Planar combustors  26  are arranged adjacent to the emitters  14 ′. 
     The combustors  26  may be formed of a matrix of interspersed tubes carrying fuel  28  and oxidizer  30  (e.g., methane and oxygen). 
     In operation, the combustors  26  produce flame fronts  32  that heat the emitters  14 ′, which then emit in an energy band matching the rare earth absorber in the rod  12 , resulting in lasing in the rod  12 . To reduce the lower laser level density, a cooling fluid is passed through the line  24  (e.g., liquid nitrogen (77° K)). 
     It is also possible to surround the rod  12  with additional emitter/combustion pairs or to use an annular emitter with suitable external combustors. 
     It should be evident that this disclosure is by way of example and that various changes may be made by adding, modifying or eliminating details without departing from the fair scope of the teaching contained in this disclosure. The invention is therefore not limited to particular details of this disclosure except to the extent that the following claims are necessarily so limited.