1. Field of the Invention
The invention generally relates to a coherent pulse source of a high power electromagnetic radiation produced by long-range wakefields induced in a slow-wave structure by a specially conditioned weakly relativistic electron beam produced by a photo gun. More particularly, the present invention is directed to providing a coherent high-power terahertz source via resonant Cherenkov radiation of a THz-modulated electron beam.
2. Description of the Prior Art
In the entire spectrum of available electromagnetic sources there is a gap between microwave and far infrared regions, where effective and compact, relatively inexpensive high-power sources are missing. A huge variety of applications in biology, medicine, chemistry, solid state physics, radio astronomy, homeland security, environment monitoring, microelectronics, plasma diagnostics, and industry are anticipating powerful terahertz (THz) sources for middle-size and small labs and businesses. The applications are related to fast processes, emerging time-domain spectroscopy (TDS), and imaging that require short THz pulses of high intensity. A heavy demand for terahertz technology also exists in the communications industry. Development of a powerful THz transmitter will result in a dramatic increase in the available bandwidth in wavelength-division-multiplexed communications networks.
Electron beams with time structures ranging typically from DC (as in electrostatic accelerator columns) to dozen(s) of picoseconds (as in photoinjectors) are capable of producing THz-radiation using e-beam-based or linac-driven sources such as Free Electron Lasers (FELs), Compton backscattering sources, traveling-wave tubes, klinotrons, and Smith-Purcell devices.
Currently, a few FELs are built to operate at THz frequencies. Typically such an FEL is driven by an electron accelerator and contains an undulator and an optical cavity. The first FEL facility to provide THz radiation to users has been the UCSB (University of California, Santa Barbara, Calif.)-FEL (0.3-0.8 mm wavelength). It is driven by a 6-MeV electrostatic accelerator with beam recirculation that delivers up to ˜2 A beam current of relatively high quality (˜10 mm-mrad emittance, and 0.3% energy spread). The maximum pulse power produced is 6 kW; this is short of the expected power of ˜10 kW (in 1-20 μs pulse length) because of mode competition in the overmoded optical cavity (˜5.4 m length) used to generate the radiation.
The largest FEL Facility at JLAB (Thomas Jefferson Laboratory) produces a broadband THz radiation with φW average and ˜1 MW peak power.
To date the Novosibirsk (Russia) FEL is the most powerful coherent THz source operating at 0.12-0.24 mm wavelengths and 0.3% line width to deliver 0.4 kW average power and up to ˜MW peak power and comprises a 20 m long optical cavity, and a long undulator driven by 40-50 MeV e-beam accelerated in a RF linac with energy recovery.
A super-radiant FEL does not have an optical cavity. The ENEA-Frascati FEL-CATS source operates in the 0.4-0.7 THz range with about 10% FWHM line width. The radiation beam has a pulsed structure composed of wave-packets in the 3 to 10 ps range, spaced at a repetition frequency of 3 GHz. A 5-microsecond long train of such pulses (macropulse) is generated and repeated at a rate of a few Hz. The power is 1.5 kW measured in the macropulse at 0.4 THz (corresponding to up to 8 kW peak in each micropulse).
Compact THz sources are basically CW devices of two types: vacuum and solid state. Vacuum devices use a non-relativistic low-power electron beam interacting with micro fabricated surfaces to generate diffraction radiation in an open geometry (e.g. Orotrons, Klinotrons, Smith-Purcell devices), or on a traveling wave in a closed system (e.g. the Backward Wave Oscillator (BWO) or Traveling Wave Tube (TWT). The typical power levels do not exceed a fraction of a Watt at terahertz frequencies. The power is typically limited by a low beam current density and a low degree of modulation occurring in the same limited interaction space.
Solid-state devices are low-power generators (or low-gain amplifiers integrated into a matrix array) based on Schottky varactor, high frequency Gunn, IMPATT or TUNNET diodes. The power produced in such devices is between tens and hundreds of milliwatts.
The most advanced solid-state device is the recently developed 1-4 THz laser based on lightly doped p-type germanium mono-crystals. The maximum emitted power depends on the crystal volume and can range from a few μW to several Watts, with duty cycles of up to 5%. Conventional gas lasers are line-tunable in the range 0.3 to 5 THz (λ=1000 to 60 μm) although with limited power (typically 100 mW for methanol).
Other known THz devices such as Quantum Cascade Lasers (QCD), laser-driven solid state emitters, and earlier Cherenkov FELs are also very limited in output power.
Thus, the problem with existing compact THz sources is low output power, whereas more powerful undulator-based FEL sources (having over kW peak power) are in national facilities that are extremely large and expensive. Undulator-based sources are very inefficient in the specific 0.3-1 mm wavelength range (between FEL and FEM).
The present invention overcomes the aforementioned problems related to a very low maximum power (for compact THz devices), or a large size and high cost (for FEL-type facilities) by providing a novel, compact solution for a high-power, sub-mm-wave generator using an electron beam. The invention provides a picosecond modulated, high-current-density photoinjector integrated with a THz radiator which eliminates the gap in robust, table-top THz pulse sources capable of generating high (kW to MW) peak power for a wide variety of practical applications.
According to the present invention, a (tens of ps) pulse of intensity-modulated (at THz frequencies) laser beam illuminates a metal photocathode and initiates a THz-modulated electron photoemission. The premodulated photocurrent is accelerated in the electron gun, focused, and then passed through a resonant dielectric-loaded THz-power radiator-extractor.
The principal advantages of the present invention when compared to known electron vacuum devices are as follows: i) radiation occurs at any beam current due to the absence of a threshold mechanism, ii) intensity modulation is provided at the very cathode and does not require extra space; iii) radiation steady state does not require a beam or laser pulse to be longer than the radiator filling time; and iv) the e-beam focusing is adjusted to minimize its size inside short radiator rather than optimize beam emittance as it occurs in undulator-based sources.
The present invention provides a method for generating a powerful terahertz radiation by passing a sub-wavelength focused, premodulated at THz frequencies electron beam through a short (˜cm), small-aperture (˜mm diameter) dielectric extractor.
The present invention also provides a method for space-charge-dominated beam transport through the radiator-extractor. For a RF photoinjector (or rf linac following the electron gun) a solenoidal magnetic system of the photoinjector and extractor works in the mode of maximized focusing rather than minimized emittance as it takes place with conventional emittance compensation technique and provides a sub-wavelength e-beam waist in the center of the radiator/extractor at substantial beam currents.
The present invention further provides a method for e-beam THz modulation by illuminating the emitting photocathode spot with laser beam(s) having resulting intensity modulated at the THz frequency. The laser intensity is modulated with a beatwave or multiplexing techniques. The beat wave technique is based on combining on the same cathode spot of two (or more) laser beams of comparable intensities but slightly different wavelengths to produce resulting beating at approximately the desired THz frequency. The multiplexing is a conventional technique for stretching the laser pulse and is based on optical split, recirculation and combining.
The present invention provides an apparatus for generating a terahertz wave using the following components:
Picosecond or sub-ps modulation of the photoemission with correspondingly conditioned laser beam and replacing the conventional undulator with a small dielectric power extractor results in a number of important benefits compared to linac-driven FEL/FEM in the sub-mm range of wavelengths. These benefits and features include the following:
For a better understanding of the present invention as well as other objects and further features thereof, reference is made to the following description which is to be read in conjunction with the accompanying drawing wherein:
a) and (b) shows temporal and spatial waveform envelopes calculated for the longitudinal electric field induced in the extractor by a uniformly micro bunched beam;
The present invention generates a coherent pulse source having a center frequency between 0.5 and 1 terahertz, or equivalently, having a wavelength between 0.6 and 0.3 millimeters. The invention may be used in many applications including, but not limited to, security (e.g., remote inspection of packages enclosed in plastic, cardboard or fabric), mine detection (e.g. land surface metal-detector/imager in arid areas), quality control of semiconductor logic chips (e.g., remote inspection of metal content therein), and quality control of agricultural products (e.g., remote inspection of water content therein).
The following sets forth the functions of the components shown in
A. Laser
B. Electron Gun (12,14)
C. Focusing System (Solenoids) (13, 24)
D. Extractor/Radiator (17)
E. Collector (21)
F. Antenna (19)
G. THz Output Window (22)
H. Coils/Magnets (24)
I. Collimator (27)
J. Accelerating RF Cavity (14)
Provides effective interaction of electron beam with microwaves by means of beam synchronized capture and resonant acceleration. The cavity can be combined with the cathode and electron gun. Typically consists of cylindrical cavity loaded by disks, RF coupler (or RF port), and vacuum port(s) 15.
The photoemission is modulated with a beat-wave or multiplexing technique. The beat-wave modulation of laser intensity results from a superposition of two or more coherent electromagnetic beams. Laser beam coherence and superposition lead to resulting intensity beating on the same cathode spot as it is shown in
Laser pulse multiplexing uses the sub-ps drive laser pulse, either actively, using an optical ring where the pulse is trapped, conditioned, circulated, and may be re-amplified, or passively, where the pulse is circulated into a confocal mirror system; e.g., with a periscope to rotate the polarization of the input pulse and a broadband thin film polarizer that allows for up to 20 passes at the focal interaction point. Such a scheme has been used in a Compton backscattering scheme, where multiplexing is necessary to enhance average brightness of the Compton source. In the Compton source scheme tested in LLNL a 7-pass confocal system producing 14 pulses at the interaction point have been used. Thus multiplexing can give a train of about a dozen (or more) of Gaussian optical bursts up to 24 μJ each with conventional optics by splitting and subsequent sub-delaying of the 30 fs, 300 μJ pulse from a commercial laser. The accuracy of the timing is not important as long as the time interval between the individual sub-ps bursts exceeds the drain time for the THz capillary extractor. In the microbunched, coherent mode of radiation the time interval has to be an integer of the period of the THz resonant frequency. Thus a premodulated electron beam with ps-scale or sub-ps microbunches is further accelerated in RF accelerating cell or cells. The entire emitted macro bunch has to be much shorter then the RF period to avoid strong distortion of the THz pre-modulation.
After being accelerated the pre-modulated and focused electron beam enters the slow-wave resonant extractor. The extractor is a traveling-wave, Cherenkov-type device having small reflections near the operating terahertz frequency. As it is shown in
ω≡2πf=h(ω)·V
where ν is the accelerated beam velocity, and h(ω) is the waveguide wavenumber as a function of frequency (i.e. dispersion function of the slow-wave extractor system). For example, for copper cylinder with ID=2b=0.6588 mm coated with Teflon having dielectric constant ∈=2.08 and thickness 2(b-a)=0.0344 mm the resonant radiation frequency is f=0.97 THz for a 2 MeV kinetic energy beam. This extractor waveguide possesses high group velocity βgr=0.8, high shunt impedance r/Q=12.4 kΩ/m, and low enough attenuation α=0.0244 cm−1 (assuming 0.0004 loss tangent for Teflon at that frequency).
The radiator aperture has to be small enough to maximize the power output. In our example the aperture radius a=0.295 mm is less than the radiation wavelength. To transport the beam through the aperture it has to be focused. In our example it is provided by solenoidal magnetic system (see
The power radiated by the beam inside the dielectric tube is given by the following formula:
where
is the bunch formfactor, q is the microbunch charge, ω=2πf=h(ω)ν is the resonant frequency, β=ν/c, k=ω/c, 2Q|β−βgr|>>1, [L(βgr−1−β−1)fb/c]2>>1, as=2Q(f/fb−1)(1−βgr/β) is the generalized detuning, fb=1/Tb is the final frequency of beam microbunching produced initially by wave beating or multiplexing at the cathode; L is the interaction length in the extractor, and α=πf/Qνgr is the attenuation constant.
Formula (1) gives the power neglecting finite beam radius. Since the electric field increases with radius at ω/h<c (see
Another example is 59 A beam at 3.2 nC charge, 26 ps laser pulse, and ˜54 ps output beam pulse length see
The flat-top length of the trapezoidal pulse (see
The frequency of the coherent radiation is determined by resonance between e-beam velocity ν and phase velocity (ν=ω/h); therefore it can be tuned by changing beam energy. The detuning sensitivity is given by df/fdγ=(γβ)−3/(1−β/βgr), that yields 78 MHz/kV for our example.
In the intermediate mode using train of independent microbunches when Tb≧tD, where tD=L(βgr−1−β−1)/c is the drain time, the THz radiation is produced at the same peak power as that for a single microbunch with the same shape and charge per microbunch. Hence the interaction space can be made shorter without diminishing the peak power to produce wider bandwidth radiation required some applications. The generated pulse duration from each microbunch is equal to tD in this mode of operation. If a beat-wave modulation or train of multiplexed sub-ps laser pulses is used in this case at Tb≧tD, the timing of individual laser pulses is no longer to be resonant with the radiation frequency; as it produces just series of synchronized short bursts of the same peak power. Or a single sub-ps laser pulse can be used. The peak power and radiated energy produced in this case are given by formula (2).
Formula (2) is confirmed experimentally very well (see, e.g, [1] and [2]). Higher group velocity enhances power (2) apart from coherent field superposition in a “long” structure with a bunch train (see Eqn. (1)).
For single microbunch example, the parameters above the microbunch charge is assumed q=61 pC. Assuming Φ=0.5 formfactor for the sub-ps microbunch charge that passes ˜1 mm short capillary channel (disk) of the same cross-section as above. Then from formula (2) we have P1b≈190 kW peak power with ˜0.7 ps duration and ˜0.13 μJ energy, which is still very substantial compared to superradiant THz FEL facilities. In just a 1 mm short capillary (or slab) this peak power will be produced in intrinsically synchronized, wide bandwidth pulses.
The performance in this ultra-short pulse mode is a somewhat similar to transition radiation [3] or laser wakefield scheme [4], but possesses narrower radiation spectrum which is still resonant and does not employ such a high beam energies (70-100 MeV in BNL and LBL experiments). The dispersion properties of the dielectric extractor provide additional control over the spectral characteristics of the emitted radiation.
The dielectric extractor comprises horn antenna 19 and collector 20 and dielectric window 22 shown in
While the invention has been described with reference to its preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the true spirit and scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its essential teachings.
Number | Name | Date | Kind |
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6844688 | Williams et al. | Jan 2005 | B1 |
Number | Date | Country | |
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20090146085 A1 | Jun 2009 | US |