Abstract: A cavity assembly includes a mounting member, an active gain medium, at least one electro-optic component and at least one alignment assembly. The mounting member defines an aperture within which the active gain medium is disposed, and is comprised of a thermally conductive material. The alignment assemblies are disposed relative to the active gain medium, and are configured to receive the electro-optic components such that electro-optic components at least partially align with the active gain medium. The alignment assemblies are rotatably disposed relative to the active gain medium such that relative rotation of the alignment assemblies and the active gain medium alters the alignment of the respective electro-optic components with respect to the active gain medium. The cavity assembly may be mounted within a thermally conductive housing to transfer heat away from the active gain medium.

Abstract: A Q-switched microlaser is provided that is capable of supporting a zig-zag resonation pattern in response to pumping of the active gain medium so as to effectively lengthen the microresonator cavity without having to physically lengthen the microresonator cavity. As such, the microlaser can generate pulses having greater pulse widths and correspondingly greater pulse energies and average power levels than the pulses provided by conventional microlasers of a similar size. A corresponding fabrication method is also provided that permits a plurality of Q-switched microlasers to be fabricated in an efficient and repeatable manner.

Abstract: A cavity assembly includes a mounting member, an active gain medium, at least one electro-optic component and at least one alignment assembly. The mounting member defines an aperture within which the active gain medium is disposed, and is comprised of a thermally conductive material. The alignment assemblies are disposed relative to the active gain medium, and are configured to receive the electro-optic components such that electro-optic components at least partially align with the active gain medium. The alignment assemblies are rotatably disposed relative to the active gain medium such that relative rotation of the alignment assemblies and the active gain medium alters the alignment of the respective electro-optic components with respect to the active gain medium. The cavity assembly may be mounted within a thermally conductive housing to transfer heat away from the active gain medium.

Abstract: A wedge-shaped microresonator is provided that can be mounted proximate one or more wedge-shaped electro-optic components in order to construct a densely packed microlaser assembly. The wedge-shaped microresonator has first, second and third side surfaces. The wedge-shaped microresonator includes a passive Q-switch proximate the second side surface and an active gain medium proximate portions of the first and third side surfaces. The wedge-shaped microresonator also includes a reflective surface proximate each of the first, second and third side surfaces. At least one of the reflective surfaces is partially reflective, however, to then permit emission of laser signals. In addition to the wedge-shaped microresonator, a microlaser assembly is provided that also includes at least one wedge-shaped electro-optic component for receiving and modifying the laser pulses emitted by the wedge-shaped microresonator.

Abstract: A Q-switched microlaser is provided that is capable of supporting a zig-zag resonation pattern in response to side pumping of the active gain medium so as to effectively lengthen the microresonator cavity without having to physically lengthen the microresonator cavity. As such, the microlaser can generate pulses having greater pulse widths and correspondingly greater pulse energies and average power levels than the pulses provided by conventional microlasers of a similar size. corresponding fabrication method is also provided according to one embodiment of the present invention that permits a plurality of side pumped Q-switched microlasers to be fabricated in an efficient and repeatable manner.

Abstract: A Q-switched microlaser is provided that is capable of supporting a zig-zag resonation pattern in response to side pumping of the active gain medium so as to effectively lengthen the microresonator cavity without having to physically lengthen the microresonator cavity. As such, the microlaser can generate pulses having greater pulse widths and correspondingly greater pulse energies and average power levels than the pulses provided by conventional microlasers of a similar size. A corresponding fabrication method is also provided according to one embodiment of the present invention that permits a plurality of side pumped Q-switched microlasers to be fabricated in an efficient and repeatable manner.

Abstract: A Q-switched microlaser is provided that is capable of supporting a zig-zag resonation pattern in response to pumping of the active gain medium so as to effectively lengthen the microresonator cavity without having to physically lengthen the microresonator cavity. As such, the microlaser can generate pulses having greater pulse widths and correspondingly greater pulse energies and average power levels than the pulses provided by conventional microlasers of a similar size. A corresponding fabrication method is also provided that permits a plurality of Q-switched microlasers to be fabricated in an efficient and repeatable manner.

Abstract: A microlaser assembly is provided that includes a microresonator, such as a side pumped microresonator having an active gain medium and a passive Q-switch, a pump source for inducing resonation of the microresonator and the generation of laser signals, one or more electro-optic components, such as one or more non-linear crystals, amplifiers, oscillators or active gain mediums, for modifying the laser signals emitted by the microlaser and a beam steering element for aligning the laser signals emitted by the microresonator with the electro-optic components. The beam steering element is preferably controllably adjustable so as to precisely align the laser signals emitted by the microresonator with an electro-optic component. In order to provide more general alignment, the microlaser assembly can also include a mechanical alignment member.

Abstract: A Q-switched microlaser is provided that is capable of supporting a zig-zag resonation pattern in response to side pumping of the active gain medium so as to effectively lengthen the microresonator cavity without having to physically lengthen the microresonator cavity. As such, the microlaser can generate pulses having greater pulse widths and correspondingly greater pulse energies and average power levels than the pulses provided by conventional microlasers of a similar size. A corresponding fabrication method is also provided according to one embodiment of the present invention that permits a plurality of side pumped Q-switched microlasers to be fabricated in an efficient and repeatable manner.

Abstract: A Q-switched microlaser is provided that is capable of supporting a zig-zag resonation pattern in response to side pumping of the active gain medium so as to effectively lengthen the microresonator cavity without having to physically lengthen the microresonator cavity. As such, the microlaser can generate pulses having greater pulse widths and correspondingly greater pulse energies and average power levels than the pulses provided by conventional microlasers of a similar size. A corresponding fabrication method is also provided according to one embodiment of the present invention that permits a plurality of side pumped Q-switched microlasers to be fabricated in an efficient and repeatable manner.

Abstract: A Q-switched microlaser is provided that is capable of supporting a zig-zag resonation pattern in response to side pumping of the active gain medium so as to effectively lengthen the microresonator cavity without having to physically lengthen the microresonator cavity. As such, the microlaser can generate pulses having greater pulse widths and correspondingly greater pulse energies and average power levels than the pulses provided by conventional microlasers of a similar size. A corresponding fabrication method is also provided according to one embodiment of the present invention that permits a plurality of side pumped Q-switched microlasers to be fabricated in an efficient and repeatable manner.

Abstract: A wedge-shaped microresonator is provided that can be mounted proximate one or more wedge-shaped electro-optic components in order to construct a densely packed microlaser assembly. The wedge-shaped microresonator has first, second and third side surfaces. The wedge-shaped microresonator includes a passive Q-switch proximate the second side surface and an active gain medium proximate portions of the first and third side surfaces. The wedge-shaped microresonator also includes a reflective surface proximate each of the first, second and third side surfaces. At least one of the reflective surfaces is partially reflective, however, to then permit emission of laser signals. In addition to the wedge-shaped microresonator, a microlaser assembly is provided that also includes at least one wedge-shaped electro-optic component for receiving and modifying the laser pulses emitted by the wedge-shaped microresonator.

Abstract: The electro-optic apparatus includes a primary heat sink and at least one submount mounted to the heat sink. The electro-optic apparatus also includes a pump source, such as a laser diode, mounted to a sidewall of the at least one submount. A secondary heat sink is also mounted to the at least one submount with an active gain medium mounted, in turn, to the secondary heat sink. Typically, the active gain medium is part of a microlaser that also includes a passive Q-switch. The active gain medium is mounted to the secondary heat sink such that the active gain medium extends in a cantilevered fashion from the secondary heat so as to overlie the pump source such that the output of the pump source pumps the active gain medium.

Abstract: The submount assembly includes a heat sink and a submount mounted upon the heat sink that is formed of a thermally conductive, electrically insulating material so as to transfer heat from the various components mounted upon the submount to the heat sink while effectively electrically isolating the various components mounted upon the submount. The first surface of the submount defines at least one registration feature, such as at least one recess, for precisely aligning components mounted thereupon. For example, the submount assembly can include a microresonator cavity including an active gain medium disposed within a respective recess defined by the submount. The submount assembly can also include a laser diode mounted upon the submount in alignment with the active gain medium such that the output of the laser diode pumps the active gain medium.

Abstract: A laser marking system and an associated microlaser apparatus are provided which include a submount, a plurality of pump sources operably mounted upon the submount, and a microlaser disposed in alignment with the pump sources such that pump signals emitted by the pump sources pump respective portions of the active gain medium of the microlaser to produce a laser output. In order to impart a mark upon a workpiece that has a number of pixels, the laser marking system can be configured such that each pixel of the resulting mark is produced by the laser output generated by a different portion of the active gain medium of the microlaser in response to pumping by a respective one of the pump sources.