The invention relates to lasers, and more particularly, to terahertz radiation (THz) generation techniques.
Radiation in the terahertz (THz) frequency range has certain properties that make it useful in applications such as spectroscopy, medical and security imaging, process monitoring and inspection in manufacturing, and remote sensing. This is because THz radiation can safely pass through living organisms and materials such as clothing fabrics, plastics, paper materials, masonry, and ceramics. In short, the THz radiation interacts with such materials causing certain information signals to be generated, which in turn can be used to form multi-dimensional images of the materials. In addition, measuring absorption of THz radiation as a function of wavelength allows for spectroscopic imaging and chemical composition detection.
However, there are problems associated with THz radiation generation. For instance, because of frequency conversion techniques, the Manley-Rowe conditions limit conversion efficiency: As a result, conventional THz generation techniques limit terahertz conversion efficiency and output power achievable. What is needed, therefore, are techniques for efficient THz radiation generation.
One embodiment of the present invention provides a terahertz signal generation system. The system includes a first nonlinear difference frequency mixing (DFM) crystal stage for receiving pump radiation ωp1 and signal radiation ωs1, and mixing ωp1 and ωs1 to generate terahertz radiation ωi1. The system further includes a first optical parametric oscillator (OPO) crystal stage for receiving ωs1 as its pump radiation ωp2, and generating signal radiation ωs2 and terahertz radiation having a frequency substantially equal to ωi1. The system further includes a second nonlinear DFM crystal stage for receiving pump radiation ωp2 and signal radiation ωs2, and mixing ωp2 and ωs2 to generate terahertz radiation ωi2. The system further includes a second OPO crystal stage for receiving ωs2 as its pump radiation ωp3, and generating signal radiation ωs3 and terahertz radiation having a frequency substantially equal to ωi2. Note that ωi1 can be substantially equal to ωi2, but need not be. The system may further include additional DFM and OPO crystal stages to provide additional terahertz radiation, thereby providing desired quantum conversion efficiency (which may exceed Manley-Rowe relations). The DFM and OPO crystal stages may be, for example, in a single crystal. Alternatively, the DFM and OPO crystal stages may comprise a linear array of different nonlinear crystals. The DFM and OPO crystal stages can be implemented, for instance, with an orientation patterned gallium arsenide (OP-GaAs), periodically-poled lithium niobate (PPLN), zinc germanium phosphide (ZGP), gallium selenide (GaSe), or combinations thereof. The system may also include a first thin film polarizer on the output of the first DFM crystal stage for passing residual pump radiation ωp1
Another embodiment of the present invention provides a terahertz signal generation system. Here, the system includes a laser pump source for providing signal radiation ωs1 and pump radiation ωp1. The system further includes a first nonlinear difference frequency mixing (DFM) crystal stage for receiving ωp1 and ωs1, and mixing ωp1 and ωs1 to generate terahertz radiation ωi1. The system further includes a first optical parametric oscillator (OPO) crystal stage for receiving ωs1 as its pump radiation ωp2, and generating signal radiation ωs2 and terahertz radiation having a frequency substantially equal to ωi1. The system further includes a second nonlinear DFM crystal stage for receiving pump radiation ωp2 and signal radiation ωs2, and mixing ωp2 and ωs2 to generate terahertz radiation ωi2. The system further includes a second OPO crystal stage for receiving ωs2 as its pump radiation ωp3, and generating signal radiation ωs3 and terahertz radiation having a frequency substantially equal to ωi2. The system further includes terahertz collection optics for collecting generated terahertz radiation.
Another embodiment of the present invention provides a terahertz signal generation system. In this example case, the system includes a laser pump source for providing pump radiation ωp1. The system further includes a first optical parametric oscillator (OPO) crystal stage for pump radiation ωp1, and generating signal radiation ωs1 and terahertz radiation ωi1. The system further includes a first nonlinear difference frequency mixing (DFM) crystal stage for receiving ωp1 and ωs1 output by the first OPO crystal stage, and mixing ωp1 and ωs1 to generate terahertz radiation having a frequency substantially equal to ωi1. The system further includes a second OPO crystal stage for receiving ωs1 as its pump radiation ωp2, and generating signal radiation ωs2 and terahertz radiation ωi2. The system further includes a second nonlinear DFM crystal stage for receiving pump radiation ωp2 and signal radiation ωs2, and mixing ωp2 and ωs2 to generate terahertz radiation having a frequency substantially equal to ωi2. The system further includes terahertz collection optics for collecting the generated terahertz radiation.
The features and advantages described herein are not all-inclusive and, in particular, many additional features and advantages will be apparent to one of ordinary skill in the art in view of the drawings, specification, and claims. Moreover, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and not to limit the scope of the inventive subject matter.
a illustrates a cascaded nonlinear conversion module of
b illustrates a cascaded nonlinear conversion module of
Structures and techniques are disclosed that enable efficient generation of terahertz (THz) radiation surpassing the fundamental quantum limit, as defined by the Manley-Rowe relations. These structures and techniques can be employed, for example, to provide a highly efficient terahertz laser source with overall conversion efficiency higher than the quantum limit, in applications such as security screening, airport imaging, and port security. Other applications, such as medical imaging, quality control and process monitoring in manufacturing operations, and package and container inspection will be apparent in light of this disclosure.
General Overview
Conventional difference frequency mixing (DFM) processes cannot exceed the fundamental upper limit, as defined by the Manley-Rowe relations, which states that the number of THz photons which are created in a nonlinear process cannot exceed the number of pump photons present at the input. In theory, 100% quantum conversion efficiency for DFM is the upper limit. This is not achievable using conventional technology. However, and in accordance with an embodiment of the present invention, a pump recycling scheme can be used to achieve this goal or improve conversion efficiency, relative to conventional techniques.
In DFM, two beams are mixed to generate THz photons. One pump beam, with frequency ωp, is depleted and transfers energy to the other pump beam, with frequency ωs, amplifying that signal. Each time a pump photon with frequency ωp is destroyed, a signal photon and an idler photon, with frequencies ωs and ωi respectively, are created to conserve energy. In a traditional DFM process, the idler frequency ωi is the signal of interest, so after a single mixing stage, the amplified signal radiation with frequency ωs is discarded. Because a single nonlinear DFM process cannot exceed the quantum limit, the efficiency is low and cannot exceed ωi/ωp. To overcome this limit, and in accordance with an embodiment, the leftover signal ωs can be recycled to drive additional nonlinear processes.
In one particular embodiment, for instance, the leftover signal ωs is used to pump an optical parametric oscillator (OPO) stage, which is used to generate another mixing signal and more THz radiation. The output signal (ωs2) and the residual pump (ωp2) from the OPO can then be used in a subsequent DFM process (or multiple DFM processes) to generate even more terahertz radiation. Such cascaded OPO, DFM, OPO staging can then be repeated to maximize the total amount of THz output power. Although each nonlinear stage will not individually exceed the quantum limit, the total number of idler THz photons (ωi) created can exceed that defined by the Manley-Rowe relations. As will be apparent in light of this disclosure, these staged processes can be performed in several different nonlinear crystals, or in a single nonlinear crystal.
System Architecture
The laser pump source outputs the desired wavelength (or wavelengths) of light to create phase-matching in crystals of the cascaded nonlinear conversion module. In particular, the laser pump source is configured to generate wavelength ωp, or wavelengths ωp and ωs, depending on the configuration of the cascaded nonlinear conversion module, as will be explained in turn. In any case, the light from the laser pump source is focused into the first nonlinear conversion stage of the cascaded nonlinear conversion module to begin the cascading nonlinear process. Essentially any wavelength of pump light may be used as long as it may phase-match in the nonlinear crystals of the cascaded nonlinear conversion module. For example, the laser may output 1-micron, 1.5-micron, 2-micron light, as they are easily generated. The laser pump source (which may include one or more laser sources) can be implemented, for instance, with a conventional laser source such as a diode-pumped solid-state laser, gas laser, or a fiber laser system. In one specific example case, an Ytterbium-doped fiber laser may be used to generate 1.055 micron light and 1.064 micron light (the difference frequency of which is 122 microns).
The cascaded nonlinear conversion module, which will be discussed in more detail with reference to
The THz radiation (ωi1, ωi2, ωi3, etc) generated in each nonlinear step of the cascaded nonlinear conversion module may be at the same wavelength. Alternatively, each nonlinear step of the cascaded nonlinear conversion module can be designed to emit a different terahertz wavelength. Such will depend on factors such as phase-matching conditions of the crystals chosen (in the cascaded nonlinear conversion module) and the pump wavelengths used (from the laser pump source). If each stage of the cascaded nonlinear conversion module is designed to give the same energy difference between the mixing pumps ωp and signals ωs, then the same wavelength of terahertz radiation will be generated in each stage (e.g., where high power ωi is required). If the energy differences between the mixing pumps ωp and signals ωs are different in each stage of the cascaded nonlinear conversion module, then each nonlinear conversion step will produce a different terahertz wavelength (e.g., where a wide spectrum of ωi is required). As will be appreciated, whether the THz radiation output ωi is high power or broad spectrum depends on the given application.
Cascaded Nonlinear Conversion Module
a illustrates a cascaded nonlinear conversion module of
In particular, and as can be seen, a laser pump source generates two wavelengths, ωp1, ωs1, whose difference frequency is the THz signal of interest. These signals are passed into a nonlinear DFM crystal stage (DFM_1). The signals ωp1 and ωs1 are mixed in the crystal, generating THz photons ωi and depleting the pump beam with the highest frequency (ωp1). After several passes within DFM_1 (three passes shown), the pump ωp1 is depleted (any residual pump ωp1
In this first OPO stage, another signal (ωs2) is generated such that the difference frequency between that signal ωs2 and the pump ωp2 (which equals ωs1) has the same terahertz frequency as the previous stage output (i.e., ωi1). The two wavelengths produced by OPO_1, ωs2 and ωp2 (e.g., IR signals), are then difference frequency mixed in a second DFM crystal stage (DFM_2) to generate additional THz radiation (ωi2). After several passes within DFM_2, a second OPO stage (OPO_2) is run with the residual amplified signal light ωs2 (which is ωp3) to generate ωs3, followed by another DFM process (DFM_3) which generates additional THz radiation (ωi3), based on the difference between ωs3 and ωp3. This cascading of paired DFM and OPO stages as shown can be repeated a number of times (e.g., 2 to 20 times) and allows the total number of generated THz photons ωi to exceed the original limit defined by the Manley-Rowe relations (which is equal to the total number of photons with frequency ωp). This is achieved, in part, by recycling one of the original pumps ωs1 generated by the laser pump source which is not depleted in the first DFM process.
The nonlinear crystal material of the cascaded nonlinear conversion module may be a single crystal, or may consist of a linear array of different nonlinear crystals. In one example embodiment, orientation patterned gallium arsenide (OP-GaAs) is used for performing all DFM and OPO processes in the same crystal. Other suitable crystal such as periodically-poled lithium niobate (PPLN), zinc germanium phosphide (ZGP) and gallium selenide (GaSe) may also be used. Alternatively, each subsequent DFM or OPO process can be performed in separate crystals (e.g., ZGP, OP-GaAs, PPLN, or GaSe crystals, or combinations thereof). Note, however, that such a multi-crystal configuration increases system complexity (e.g., inter-crystal interface and optical coupling).
Also shown in the example embodiment of
A number of non-trivial nuances associated with generating terahertz radiation will now be discussed. In general, pump recycling using OPO/OPA or OPO/DFM for mid-IR light is known. However, pump recycling for terahertz generation is not. One fundamental difference is that, in embodiments for generating terahertz radiation as described herein, the pump and signal beams are very close together. For example, to generate terahertz radiation, the pump ωp may have a wavelength of 1059 nm and the signal ωs may have a wavelength of 1064 nm, generating a terahertz wavelength of 225-microns. Because the wavelengths are so close together, conventional thin-film coatings that are typically used cannot be used in the OPO cavities/stages of a terahertz generation system. Thus, gratings such as the VBG are used in accordance with embodiments of the present invention (other comparably selective optics may be used in place of gratings if available and so desired). Also, the OPO cavities are singly-resonant in accordance with some embodiments, to avoid the need for terahertz optics. Terahertz generation is essentially a by-product of the nonlinear processes occurring between the pump ωp and signal ωs beams. The terahertz signal ωi is generated as energy and momentum are conserved in the nonlinear interaction.
One conventional technique for THz generation uses optical rectification and waveguides. Such techniques are fundamentally different from embodiments of the present invention, which utilize difference frequency mixing and optical parametric oscillation to recycle the photons and improve efficiency. For instance, one such conventional optical rectification and waveguide system employs a Raman cascading scheme, which is a completely distinct process from DFM. In addition, that particular technique uses waveguide dispersion to engineer an efficient process. In contrast, embodiments of the present invention employ DFM and OPO processes in a cascaded scheme to recycle the photons and improve overall efficiency. Some such embodiments use nanosecond pulses (e.g., 1 to 100 nanometers, such as where the DFM pump radiation wavelength is within 10 nanometers of the DFM signal radiation wavelength). The use of the longer pulses in accordance with such embodiments of the present invention yields a narrow THz signal spectrum. No waveguides are required to engineer the material dispersion; rather, the nonlinear crystals themselves provide the proper phase-matching conditions for THz generation.
As an alternative configuration to beginning with a dual-wavelength pump source and DFM process, a single laser may be used to generate only a single pump ωp wavelength. A schematic of such an alternative pump recycling scheme for THz generation is shown in
The next stage is a multi-pass DFM (DFM_1), which acts as a THz converter and signal amplifier (where ωp1 is depleted to ωp1
Such architectures take advantage of the laser pump source. Each single pass element in such a system will not exceed the quantum limit defined by that interaction, but by cascading several nonlinear processes, the total THz conversion can exceed the initial limit (defined by ωi/ωp1). This is due to the fact that the residual photons created in the nonlinear processes are recycled and used to then drive subsequent nonlinear processes with an overall photon conversion efficiency that is greater than quantum limit. The overall quantum conversion efficiency of the system will be a function of the quantum efficiency of each DFM and each OPO stage as well as the total number of cascaded nonlinear processes. This cascaded architecture may be repeated as necessary to improve conversion efficiency.
The foregoing description of the embodiments of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of this disclosure. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto.