X-rays (photon energy between about 100 eV and about 100 keV) have applications in a wide range of areas. For example, in medicine and dentistry, X-rays are used for diagnosis of broken bones and torn ligaments, detection of breast cancer, and discovery of cavities and impacted wisdom teeth. Computerized axial tomography (CAT) also uses X-rays produce cross-sectional pictures of a part of the body by sending a narrow beam of X-rays through the region of interest from many different angles and reconstructing the cross-sectional picture using computers. X-rays can also be used in elemental analysis, in which measurement of X-rays that pass through a sample allow a determination of the elements present in the sample. In business and industry, X-ray pictures of machines can be used to detect defects in a nondestructive manner. Similarly, pipelines for oil or natural gas can be examined for cracks or defective welds using X-ray photography. In the electronics industry, X-ray lithography is used to manufacture high density (micro- or even nano-scale) integrated circuits due to their short wavelengths (e.g., 0.01 nm to about 10 nm).
To this date, X-ray tubes are a popular X-ray source in applications such as dental radiography and X-ray computed tomography. In these tubes, electrons from a cathode collide with an anode after traversing a potential difference usually on the order of 100 kV. Radiation created by the collision generally comprises a continuous spectral background of Bremsstrahlung radiation and sharp peaks at the K-lines of the anode material. The X-rays are also emitted in all directions and the source is typically not tunable since the frequencies of the K-lines are material-specific. These limitations of X-ray tube technology translate to limitations in the resolution, contrast, and penetration depth in imaging applications. The limitations also result in longer exposure time and accordingly increased radiation dose. Moreover, the temporal resolution used for live imaging of extremely fast processes is usually beyond the reach of X-ray tubes.
As an alternative to X-ray tubes in some applications (e.g., elemental analysis), synchrotrons and free-electron lasers, which are usually based on large-scale accelerator facilities such as the Stanford Linear Accelerator Center (SLAC), can provide coherent X-ray beams with tunable wavelengths. However, these facilities are very expensive (e.g., on the order of billions of dollars) and are generally not accessible to everyday use.
A more compact approach to generate X-rays is through high harmonic generation (HHG). In this approach, an intense laser beam, usually in the infrared region (e.g., 1064 nm or 800 nm), interacts with a target (e.g., noble gas, plasma, or solid) to emit high order harmonics of the incident beam. The order of the harmonics can be greater than 200, therefore allowing generation of soft X-rays from infrared beams. However, HHG produces not only the high order harmonics in the soft X-ray region but also radiation in lower order harmonics. As a result, the energy in the particular order of harmonic of interest is generally very low and is not sufficient for most applications.
Embodiments of the present invention include apparatus, systems, and methods of generating electromagnetic radiation. In one example, an apparatus includes at least one conductive layer, an electromagnetic (EM) wave source, and an electron source. The conductive layer has a thickness less than 5 nm. The electromagnetic (EM) wave source is in electromagnetic communication with the at least one conductive layer and transmits a first EM wave at a first wavelength in the at least one conductive layer so as to generate a surface plasmon polariton (SPP) field near a surface of the at least one conductive layer. The electron source propagates an electron beam at least partially in the SPP field so as to generate a second EM wave at a second wavelength less than the first wavelength.
In another example, a method of generating electromagnetic (EM) radiation includes illuminating a conductive layer, having a thickness less than 5 nm, with a first EM wave at a first wavelength so as to generate a surface plasmon polariton (SPP) field near a surface of the conductive layer. The method also includes propagating an electron beam at least partially in the SPP field so as to generate a second EM wave at a second wavelength less than the first wavelength.
In yet another example, an apparatus to generate X-ray radiation includes a dielectric layer and a graphene layer doped with a surface carrier density substantially equal to or greater than 1.5×1013 cm−2 and disposed on the dielectric layer. The apparatus also includes a laser, in optical communication with the graphene layer, to transmit a laser beam, at a first wavelength substantially equal to or greater than 800 nm, in the graphene layer so as to generate a surface plasmon polariton (SPP) field near a surface of the graphene layer. An electron source propagates an electron beam, having an electron energy greater than 100 keV, at least partially in the SPP field so as to generate the X-ray radiation at a second wavelength less than 2.5 nm.
In yet another example, an apparatus includes at least one conductive layer having a thickness less than 5 nm. An electromagnetic (EM) wave source is in electromagnetic communication with the at least one conductive layer to transmit a first EM wave at a first wavelength in the at least one conductive layer so as to generate a surface plasmon polariton (SPP) field in the at least one conductive layer. An electron source is operably coupled to the at least one conductive layer to propagate an electron beam in the at least one conductive layer so as to generate a second EM wave at a second wavelength less than the first wavelength.
It should be appreciated that all combinations of the foregoing concepts and additional concepts discussed in greater detail below (provided such concepts are not mutually inconsistent) are contemplated as being part of the inventive subject matter disclosed herein. In particular, all combinations of claimed subject matter appearing at the end of this disclosure are contemplated as being part of the inventive subject matter disclosed herein. It should also be appreciated that terminology explicitly employed herein that also may appear in any disclosure incorporated by reference should be accorded a meaning most consistent with the particular concepts disclosed herein.
The skilled artisan will understand that the drawings primarily are for illustrative purposes and are not intended to limit the scope of the inventive subject matter described herein. The drawings are not necessarily to scale; in some instances, various aspects of the inventive subject matter disclosed herein may be shown exaggerated or enlarged in the drawings to facilitate an understanding of different features. In the drawings, like reference characters generally refer to like features (e.g., functionally similar and/or structurally similar elements).
Overview
So far, X-ray sources that can produce tunable and directional X-rays normally sacrifice compactness by requiring additional acceleration stages to bring the electron beam to extremely high energies and relativistic speeds (γ>>1, where γ˜(1−(v/c)2)−1/2, with v being the electron speed and c being the speed of light). These relativistic electrons then interact with an electromagnetic field that induces transverse oscillations in their trajectory, causing the electrons to emit radiation. Typically, the electromagnetic field is supplied by a counter-propagating electromagnetic wave (e.g., in nonlinear Thomson scattering or inverse Compton scattering) or by an undulator, which is a periodic structure of dipole magnets (undulator radiation).
In Thompson scattering or inverse Compton scattering, the energies of the emitted photons Eout and the energies of incident photons Ein are related by Eout≈4γ2Ein. In undulators, such as SLAC, the energy of the emitted photons Eout is about 2γ2Ein, instead of 4γ2Ein, due to the non-propagating nature of the magnetic field. Therefore, translating laser photons (e.g., about 1 eV) into X-ray (e.g., about 40 KeV) via laser-electron interaction normally needs electron beam having an energy on the order of about 50 MeV. As another example, in free electron lasers (FELs) that use an undulator with a period of about 3 cm (functionally similar to the wavelength in Thompson scattering or inverse Compton scattering and can be translated into incident photon energy of about 4.1×10−6 eV), it takes electron beams having electron energy of about 10 GeV (γ˜20,000) to produce X-rays of the same frequency as above. High energy electron acceleration is generally costly and bulky, thereby severely limiting the widespread use.
To address the limitations of existing X-ray sources such as X-ray tubes, synchrotrons, FELs, and high harmonic generation (HHG), this application describes approaches that use electron beams of modest energy and can therefore bypass the high energy electron acceleration stage altogether. X-rays are generated when electrons interact with the surface plasmon polaritons (SPPs) of two-dimensional (2D) conductive materials (e.g., graphene). SPPs in 2D conductive materials can be well confined and have high momentum. This localization of SPP fields allows more efficient energy transfer from incident photos to output photons through:
Eout≈2n×4γ2Ein (1)
The factor n is the “squeezing factor” (also referred to as the confinement factor) of the electromagnetic field when it is bounded to the surface between a metal and a dielectric. For 2D conductive materials, the squeezing factor n can be more than 100 or even higher. Therefore, approaches described here make it possible for a much lower electron acceleration (e.g., about 1-5 MeV) to create the same hard-X-ray frequency (e.g., about 40 KeV).
By simplifying or even eliminating the high energy electron acceleration in conventional X-ray sources, apparatus and methods described herein allow the development of table-top X-ray sources that are compact, tunable, coherent, and highly directional. These X-ray sources can revolutionize many fields of science, by making high-quality X-ray beams affordable to laboratories in academia and industry. Moreover, bringing these X-ray sources into regular use in hospitals would allow for incredibly sensitive imaging techniques with unprecedented resolution deep inside a human body.
In addition, the approaches of electron-SPP interaction can also be employed to create radiation in other spectral regimes, such as deep ultraviolet (UV), infrared, and Terahertz (THz), with only slight modifications. These radiation sources can have similar benefits of compactness, tunability, coherence, and directionality.
The system 100 shown in
For illustrative and non-limiting purposes only, the 2D conductive layer 110 can include graphene. Surface plasmon polaritons (SPP) in graphene (also referred to as graphene plasmons, or simply GPs) can exhibit extreme confinement of light with dynamic tunability, making them promising candidates for electrical manipulation of light on the nanoscale. Highly directional, tunable, and monochromatic radiation at high frequencies can be produced from relatively low energy electrons interacting with GPs, because strongly confined plasmons have high momentum that allows for the generation of high-energy output photons when electrons scatter off these plasmons.
Without being bound by any particular theory,
When electrons 135 are launched parallel to the graphene 110, subsequent interaction between electrons 135 and the GP field 101 induces transverse electron oscillations, as shown by the dotted white lines. The oscillations lead to the generation of short-wavelength, directional radiation 102, such as X-rays.
Without being bound by any particular theory,
Two-Dimensional Conductive Layers and SPP Fields
In the approach illustrated in
In general, at the interface between a metal and a dielectric (including air), there exists special electromagnetic modes called surface plasmon-polaritons (SPPs). These hybrid electron-photon states can have numerous promising applications, such as to bridge the gap between electronics and photonics, allowing high frequency communication and squeezing the photonics from micron-scale to the on-chip nano-scale. This squeezing of light can also lead to high confinement of the field to the surface, expressed in high field densities, which can be useful for enhancing many types of light-matter and light-light interactions.
Without being bound by any particular theory or mode of operation, the field squeezing originates from the fact that the SPP effective wavelength is reduced by a large factor (referred to as the “squeezing factor” n) relative to the wavelength in free-space (e.g., wavelength of the incident EM wave 125 that excites the SPP). This squeezing factor can be the basis for various promising features of the SPP, such as enhanced sensing and sub-wavelength microscopy. The squeezing factor n typically can be about 10-20 in regular metals. However, SPP modes in graphene can be much larger, reaching several hundreds and even more than a thousand.
Graphene is a two dimensional array of carbon atoms connected in a hexagonal grid. This seemingly simple material can have astonishing mechanical, electronic, and optical properties, such as high mechanical strength, high mobility, and very large absorption. One property of graphene that can be useful in the apparatus 100 shown in
In the approach shown in
Optical excitation of SPP fields 101 through EM waves 125 from air can be enhanced by patterning the graphene. For example, a grating structure can be fabricated into the substrate 140, deposited on top of the graphene layer 110, or implemented as an array of graphene nano-ribbons on the substrate 140. A graphene layer can also be implemented according to one or more of the designs shown in
Patterning graphene can also help reduce losses of SPP. Generally, plasmonics can suffer from limited propagation distances (also referred to as localization) due to short plasmon lifetimes. As an initial matter, the approach illustrated in
Patterning the graphene can generate and couple GPs simultaneously along the entire graphene surface (e.g., through the standing wave in nano-ribbon configurations shown in
The properties of GPs can be dynamically changed by electrostatic tuning of the graphene Fermi energy. The tuning of GP properties can in turn change the frequency of the output photons, therefore allowing a dynamically tunable radiation source. In addition, graphene can also be chemically doped as known in the art to further increase the dynamic range of doping. Approaches described here can use electrostatic doping, chemical doping, or both.
The above description uses graphene as the 2D conductive layer 110 shown in
In another example, the 2D conductive layer 110 can include 2D metal layers (e.g., single-atom layers of metal materials such as silver), which can also support SPPs of very high squeezing factor due to the electrons behaving like a 2D electron gas. For example, a single-atom-thick silver can have higher conductivity than graphene while still having very low losses in the optical regime. 2D silver therefore can support visible SPPs that can provide higher frequencies (shorter wavelengths) to start with.
In yet another example, double-layer graphene sheets can be used as the 2D conductive layer 110. Double layer graphene sheets, which include two single-atom carbon layers coupled together via van der Waals force, can have enhanced conductivity and high squeezing factors. Similar properties can also be found in other multi-layer materials such as gold, silver, and other materials with properties similar to graphene. These multi-layered structures can have their bounded electrons interacting between layers, creating properties that are generalizations of the 2D electron gas behavior of single-atom layers, such as high squeezing factor.
In yet another example, the 2D conductive layer 110 can include general 2D electron gas (2DEG) systems, which can exist without single-atom layers or few-atom layers. Instead, the physics of 2DEG systems can appear at the interface between bulk materials, such as in MOFSET structures. These interfaces therefore can also be used in the approaches described herein.
The length of the 2D conductive layer 110 in the direction of the electron motion can be just a few microns and still produce high quality radiation. This means that the structure does not have to include any space for the electron beam to move through—the penetration depth of the electrons is longer than the structure size anyway—so the structure can be solid and the electrons can just be sent directly through it.
The last point can be useful since it constitutes an advantage of the current approaches over conventional methods. Most electron beam-based radiation sources require electrons to travel a long distance inside a structure, e.g., to have many undulator periods. Since the electrons can pass through solid matter only to a limited distance, conventional methods typically use a vacuum channel for the electrons to pass through. This makes the sources more complicated since it requires a control over the beam spread (itself a very challenging problem). In contrast, approaches described herein only involve electron beam propagation within a small length of the sample (several microns is already enough). This can make the control over the e-beam spread much easier, and even not necessary at all in some cases. Furthermore, the distance of several microns can be even shorter than the mean-free-path of relativistic electrons in solids. The implication is that the current approach can work without any special control of the electron beam.
Several advantages can be derived from above discussion, including: (a) one does not need to worry that the electron-beam will destroy the sample (the energies are relatively small); (b) the exact alignment of the beam and the sample are less crucial; and (c) one can build a sandwich structure or multilayer structure by stacking many layers (dielectric-graphene-dielectric-graphene- . . . ). The structures can also be cascaded to extend the interaction length (only limited by the mean-free-path, which causes a gradual decrease in the beam velocity due to collisions).
Other alternative geometries are also possible, such as a sandwich structure with or without a substrate between two graphene sheets, or a stack of multiple graphene sheets with a dielectric substrate in between.
Electron Sources and Electron Beams
The electron source 130 in
The electron energy of the electron beam 135 can affect the output frequency through Equation (1).
As described above, using SPP near 2D conductive layers can significantly reduce the electron acceleration to generate short wavelength radiation, compared to conventional free electron laser or undulators. The reduced electron energy can be readily accessible via various technologies. Examples of electron sources 130 that can provide the electron beam 135 for short-wavelength generation are described below.
The frequency conversion regimes shown in
In regular use of a TEM, the sample to be imaged is suspended by the sample-holder 850 in the path of an electron-beam 835 that moves downward along the microscope cylindrical column. Therefore, a graphene sample-holder can be constructed to mount the graphene layer 810 on the dielectric slab 840 such that the graphene layer 810 is positioned precisely near the path of the electron beam 810.
In one example, the graphene sample holder can have fibers and electrical feed-throughs directed through the sample holder to give external control of the properties of the graphene layer 810 (e.g., the Fermi level), and to couple the electromagnetic field through it into the SPP mode on the surface of the graphene layer 810. In another example, other methods such as chemical doping for doping graphene without an external applied voltage can be used, therefore simplifying the holder by removing the electric feed-through. In either case, the graphene sample holder device, when put into the path of the electron beam 835, can create the interaction illustrated in the right panel of
TEMs can provide electron beams of high quality (e.g., small divergence and high velocity) so as to achieve better-than angstrom scale (10−10 m) resolution. This high quality electron beam 835, when used in in the system 800, can also benefit the generation of X-rays. In general, electron beams delivered by TEMs can have electron velocity of about 0.5 to about 0.8 of the speed of light (i.e., about 0.5 c to about 0.8 c), corresponding to electron energy of about 100 KeV to about 1 MeV. According to previous discussion, these electron energies are sufficient to generate X-rays using the system 800. In one example, the TEM 860 can provide electrons beams of about 200 to about 300 KeV. The SPP field created near the graphene layer 810 can be about 1000. Laser beams at a photon energy of about 2 eV (i.e., about 620 nm) can be used to excite the SPP field near the graphene layer 810. With these parameters, X-ray radiation of 10 KeV, already in the hard-x-ray regime, can be readily obtained, even without any additional modifications of the TEM 860.
Using TEMs as the electron source for X-ray generation based on electron-SPP interaction can have several benefits. First, TEMs are state-of-the-art instruments including a built-in electron-gun, a vacuum system, and a built-in X-ray detector that can be used to monitor the properties of the generated X-ray 802 and provide feedback control if desired. TEMs generally also have a high-quality beam control and a simple usage scheme. Second, TEMs are normally of lab size and reasonably priced (about $1M). Making small modifications (about $200K) that transform a part of this system into a coherent X-ray source would be a true revolution in X-ray sources. In particular, a TEM—unlike the very large, billion-dollar accelerator facilities—can be operated in hospitals, and in many places it already is.
The system 800 shown in
In another example, the graphene layer 810 can have a length that is sufficiently long for the electrons to rearrange themselves into coherent bunches via self-amplified spontaneous emission. The length of the graphene can dependent on, for example, the current of the electron pulse and the intensity of the optical pulse that excites the SPP field. In one example, the length of the graphene can be greater than 1 μm. In another example, the length of the graphene can be greater than 5 μm. In yet another example, the length of the graphene can be greater than 10 μm. As described above, since the SPP fields are generated and coupled simultaneously over the entire graphene, potential losses due to propagation of SPP can be neglected.
In yet another example, the electron beam 835 can include pre-bunched electrons, i.e., a sequence of electron bunches, similar to laser beams in pulsed mode. In this case, the laser beams that are used to excite the SPP field 810 can also operate in pulsed mode and can be synchronized with the electron bunches. In other words, each pulse in the sequence of laser pulses can be synchronized with one electron bunch in the sequence of electron bunches. Since pulsed laser beam can have a higher intensity compared to continuous wave (CW) beams, the resulting SPP can also be stronger, therefore allowing more efficient generation of X-rays.
In addition, each bunch of electrons in the sequence of electron bunches can be micro-bunched (i.e. periodic or modulated within an electron bunch). In one example, each electron bunch in the sequence can have a micro-bunch period on the order of attoseconds, i.e. micro-bunches are separated by attoseconds within each electron bunch. This micro-bunch can help generate coherent emission from the electron-SPP interaction. In another example, the micro-bunch period can be substantially equal to one oscillation cycle of the emitted radiation. For example, the emitted radiation can be about 5 nm, which has oscillation cycles of about 1.5 attoseconds. In this case, the time interval between micro-bunches with one electron bunch can also be about 1.5 attoseconds.
In yet another example, the electron beam 835 can have a flat sheet configuration. In other words, the cross section of the electron beam 835 can have an elliptical shape, or even a nearly rectangular shape. The flat sheet of electrons can be substantially parallel to the graphene layer 810 when propagating through the SPP field. This flattened shape of the electron beam 835 can better match the planar shape of the SPP field above the graphene layer 810, thereby increasing the number of electrons that can interact with the SPP field and accordingly the output energy of the output radiation 820.
In yet another example, the graphene layer 810 can be doped to prevent or reduce potential damage to the graphene layer 810. Doping the graphene layer 810 can create static charges on the graphene layer 810 and therefore repel the approaching electrons from the electron beam 835. In fact, potential damage to the graphene layer 810 should not be an issue in the approaches described here, because the electron energy is relatively low, compared to those in conventional FELs and undulators, and further because graphene have characteristically strong structures. In addition, the high conductivity of graphene can allow for quick dissipation of accumulated charge.
In yet another example, dielectric materials having a large refractive index can be used to make the dielectric slab 840 that supports the graphene layer 810. In general, a larger refractive index can result in a more confined SPP field (i.e., shorter wavelength or larger squeezing factor) near the graphene surface. In practice, example materials that can be used include, but are not limited to, silicon, silicon oxide, tantalum oxide, niobium oxide, diamond, hafnium oxide, titanium oxide, aluminum oxide, and boron nitride.
Other than TEM, scanning electron microscopes (SEM) can also be used as the electron source for GP-based radiation source. SEMs are normally less expensive than the TEMs and are easier to modify and control. In general, SEMs can generally provide electron beams having electron energy on the order of about 20 KeV. Due to the strong field confinement in graphene SPP (i.e. higher n), radiation in the soft-X-ray regime can be achieved. Soft-X-rays, such as those in the water window between 2.3 nm and 4.4 nm, can have useful applications in imaging live biological samples.
In addition, electron guns in old CRT television sets can also provide electrons having energy in the KeV range, therefore allowing the development of very cost-effective soft-X-ray source. For example, a 4 KeV acceleration, which is accessible in standard small office desk items (e.g. plasma globes) can be sufficient to create 300 eV radiation, which is a soft-X-ray that falls in the water window.
Generally, the voltage applied across the electrodes 930 is on the order to tens of volt. Therefore, the electros 935 are non-relativistic. In this case, the following equation for the up conversion from the incoming photon frequency (used to excite the graphene SPP) to the emitted radiation frequency applies:
Eout=Ein(1+nβ)/(1−nβ) (2)
where n is the graphene SPP “squeezing factor” as above, and β is the normalized electron velocity, which is the velocity divided by the speed of light. Equation (2) reduces to Equation (1) when β→1, which is the relativistic limit. Although Equation (2) only describes the frequency relation along the axis of the electron beam, a more general equation can be derived in the exact same way.
The output frequency of the radiation source 900 can be tunable by changing the voltage and accordingly the electron energy, i.e., β in Equation (2).
The approach illustrated in
This difference can induce implications in several aspects. In one aspect, the emission from the radiation source shown in
In another aspect, the frequency conversion efficiency of approaches described herein can depend on the strength of the SPP field, which can be controlled externally and can be brought to a high level (e.g., 1 GV/m or even higher for short pulses). The efficiency of the Cerenkov-based approaches depends on the structure interaction with the electron beam, which is much weaker and cannot be externally control.
In yet another aspect, the emission of light 902 in approaches described herein is created by the electrons and is radiating out of the structure right away, i.e., there may be no structure-based losses involved. The radiation in the Cerenkov-based approaches is from the structure electromagnetic modes. Therefore, structure losses can reduce the intensity of the radiation. Furthermore, much of the emission power might be lost in conventional methods unless perfect coupling of this power to the outside is achieved.
In yet another aspect, the emission 902 in the system 900 can be substantially monochromatic because the SPP can be controlled to be monochromatic via optical excitation using laser beams. On the other hand, Cerenkov-based ideas are usually broadband. Even though a specially designed structure can partly improve the monochromatic quality of the emission, the performance can still be far away from substantially monochromatic.
In yet another aspect, the approaches shown in
The electron source 130 shown in
GP-Based Radiation Sources Using Multiple Graphene Layers
Dielectric material in the cavity 1145 would not prevent operation of the radiation source 1100 because the electron beam 1135 can generally penetrate through a few tens of microns of dielectric with almost no energy loss (and even much more if the electron beam is more energetic). Several microns of propagation can be sufficient to generate an X-ray that is substantially monochromatic (spectral width on the order of a few eV).
The two schemes shown in
In one example, the systems shown in
The substrate material or the dielectric material separating multiple graphene layers can also affect the performance of the resulting radiation sources. Silica and silicon can be used in all examples shown in
Analytical and Numerical Analysis of GP-Based Radiation
This section describes analytical and numerical analysis that can explain the underlying physics behind the radiation generation presented above. The analysis can offer an excellent description of both the frequency and the intensity of the radiation. The interaction between an electron and a GP can be analytically studied from a first-principles calculation of conservation laws, solving for the elastic collision of an electron of rest mass m and velocity v (normalized velocity β=v/c, Lorentz factor γ=(1−β2)−1/2) and a plasmon of energy ω0 and momentum nω0/c. Their relative angle of interaction is θi, measured from the direction of the electron velocity. The output photon departing at angle θf has energy ωph and momentum ωph/c, where ωph is given by:
The approximate equality, which neglects the effects of quantum recoil, can hold whenever γmc2>>nω0. In the case of n=1, Equation (3) can reduce to the formula for Thomson/Compton scattering, involving the relativistic Doppler shift of the radiation due to the interaction of an electron with a photon in free space.
A separate derivation based on classical electrodynamics corroborates the results of the above treatment. The detailed analysis is presented below.
Properties of Graphene Plasmons
This section describes analytical expressions for the dispersion relations and the fields of electromagnetic modes sustained by a layer of graphene sandwiched between two layers of dielectric (one of them being free space in the main text). Consider a three-layer system in which Layer 1 extends from x=−∞ to x=0, Layer 2 from x=0 to x=d and Layer 3 from x=d to x=+∞, with ε1, ε2, and ε3 being the respective permittivities of each layer. By solving Maxwell's equations and matching boundary conditions in the standard fashion, the transverse-magnetic (TM) dispersion relation can be written as:
where Kj=(q2−ω2εjμ0)1/2, j=1, 2, 3, ω is the angular frequency, q=nω/c the complex propagation constant, and μ0 is the permeability of free space, which can also be taken as the permeability of the materials. Layer 2 is also used to model a monoatomic graphene layer of surface conductivity σswith Layer 2, by setting ε2=iσs/(ωd) and taking d→0, to obtain the dispersion relation:
which, in general, can be solved numerically for q, since σs can have a complicated dependence on both the frequency and the wave-vector.
The surface conductivity σs can be obtained within the random phase approximation (RPA). When the wave-vector is small enough that plasmon damping due to electron-hole excitations is not significant, a semi-classical approach that generalizes the Drude model can be used. Taking into consideration inter-band transitions derived from the Fermi golden rule, the conductivity can be written as:
where the low-temperature/high-doping limit (i.e., Ef>>kT) is assumed. The first term in the above expression is the Drude conductivity, the most commonly used model for graphene conductivity to describe GPs at low frequencies. The second term captures the contribution of inter-band transitions. In the above expression, e is the electron charge, Ef is the Fermi energy, ns is the surface carrier density, vf is the Fermi velocity, and τ is the relaxation time that takes into account mechanisms like photon scattering and electron-electron scattering. The spatial confinement factor, defined as n=cRe(q)/ω represents the degree of spatial confinement that results from the plasmon-polariton coupling.
In the limit of a large confinement factor (i.e., q2>>ω2εjμ0), the dispersion relation Equation (5) can be well approximated by:
which shows that the propagation constant, and hence the confinement factor, can be enhanced by the presence of a dielectric layer above or below the graphene. In the electrostatic limit, inter-band transitions may be ignored.
An analytical expression for the plasmon group velocity may be derived from Equation (5) by first differentiating the propagation constant to obtain:
and then evaluating the above equation at ω=ω0, where ω0 is the plasmon frequency. When the confinement factor is large, and losses are negligible so that surface conductivity σs=iσsi, the group velocity of a GP may be approximated by the analytical expression:
where all variables are evaluated at ω=ω0. The contribution of the substrate's material dispersion—captured by the third term in the denominator—can be ignored when:
This is a condition that can be obtained by comparing the first and third terms in the denominator of Equation (9). In one example, the graphene can have SiO2 as a substrate and free space on the other side, and the a free space wavelength of 1.5 μm can be used. SiO2 has a chromatic dispersion d(ε/ε0)1/2/dλ=−0.011783 μm−1. The equation may be rearranged to give ω0dε/dω=0.051ε0<<ε1,2, which satisfies Equation (10).
Equation (9) may be simplified even further in the case of large confinement factors, for which one usually has σsi<<ε0c˜1/120π, allowing the second term in the denominator of Equation (10) to be dropped without affecting the accuracy of Equation (10) significantly. In one examples, Ef=0.66 eV and εSi=1.4446, giving a confinement factor of n=180 at free space wavelength 1.5 μm. For these parameters, the surface conductivity is found to be σs=8.18×10−9+i4.56×10−5 S, according to the RPA approach.
To summarize, in the limit of large confinement factors and negligible material dispersion of the substrate, the group and phase velocities of a GP may be approximated by the analytical expressions:
where all variables are evaluated at ω=ω0. Since the electrostatic limit for the surface conductivity (i.e., the Drude model conductivity) is not assumed, the above expressions also hold for larger plasmon energies.
Electromagnetic Fields of Graphene Plasmons
An electromagnetic solution of the system is in general polychromatic and involves an integral over multiple frequencies subject to the RPA dispersion relation q=q(ω) obtained above. For a pair of counter-propagating, pulsed TM modes, the electric and magnetic fields in the free space portion x>0 are:
where F(ω) is the complex spectral distribution, ε0 is the permittivity of free space, zi>0 is the initial pulse position of the backward-propagating pulse, and the frequency dependence of each component is explicitly shown. Subscripts denoting layer have been omitted for convenience. A large confinement factor normally implies a very small group velocity vg (e.g., vg=2×105 m/s for confinement factor n=300 and a substrate of SiO2 of refractive index 1.4446 at free space wavelength 1.5 μm), which can be negligible compared to the speed of free electrons from standard electron microscopes and DC electron guns. Hence, the counter-propagating pulses practically approximate a stationary, standing wave grating.
When the GP pulse duration is large, a simplified form for Equation (12) can be:
where the subscript “0” in K and q denotes the wave-vector at the central frequency ω0 and ξ±=−((z∓zi)/vg±t)2/2T02, ψ±=q0k(z∓zi)±ω0t+ψ0±, q0=q(ω0), K0=K(ω0) and E0s is the peak electric field amplitude on the graphene sheet. The additional subscripts “r” and “i” on q0 and K0 refer to the associated variable's real and imaginary parts respectively.
The physical meaning of q0 may be understood by considering its real and imaginary parts separately: The real part q0r is related to the plasmon phase velocity through the confinement factor n, giving vph=c/n. The imaginary part q0i is related to the plasmon attenuation. T0 is the pulse duration associated with the number of spatial cycles Nz and temporal cycles Nt in the intensity full-width-half-maximum (FWHM) of the plasmon Gaussian pulse as:
Note that T0 can also be related to the spatial extent L by T0=L/nvg.
Electrodynamics in Graphene Plasmons
This section describes analytical expressions approximating the dynamics of a charged particle (e.g., an electron) interacting with a GP, based on the results from the previous section. The motion of an electron in an electromagnetic field is governed by the Newton-Lorentz equation of motion:
where {right arrow over (p)} is the momentum of the electron, m is its rest mass, Q=−e is its charge, {right arrow over (v)} is its velocity and γ=(1−(v/c)2)−1/2 is the Lorentz factor. For the fields described in Equation (12), Equation (15) becomes:
For the purposes of simplifying Equation (16), it can be assumed that: a) transverse velocity modulations are small enough so γ˜(1−(vz/c)2)−1/2 and x˜x0 throughout the interaction; b) longitudinal velocity modulations are negligible so z˜z0+vz0t and γ is approximately constant throughout the interaction, and c) q0=q0r, which can be made possible by pumping the plasmon along the entire range of interaction; along z (e.g., via a grating). The subscript “0” refers to the respective variables at initial time.
Then Equation (16) may be analytically evaluated to give:
βg=vg/c, and βph=vph/c. Note that in the case of a large confinement factor n, the last expression gives βph=vph/c˜1/n, resulting in ω±=ω0(1±n βz0). Ψ′0± is used to abstract away the phase constants that do not contribute in our case to the resulting radiation.
The resulting oscillations in x and z are:
Here δx and δz are the oscillating components of the electron displacements in x and z respectively.
In the above treatment, the assumption of a relatively narrow-band GP allows the neglecting of chromatic changes in group and phase velocity in going from Equations (12) to Equation (13). Propagation losses can also be neglected from Equation (16) to Equation (17). Such approximations are justified when the confinement factor is large, in which case the group velocity tends to be negligible compared to the free electron velocity, so the GP propagates negligibly during the GP-electron interaction and both loss and pulse-broadening can be ignored.
Radiation from GP-Electron Interaction
This section describes analytical expressions approximating the spectral intensity as a function of output photon frequency, polar angle, and azimuthal angle, when an electron interacts with a GP. Although the radiation spectrum for a free electron wiggled by electromagnetic fields in free space was studied before, the analysis here of electron-plasmon scattering generalizes the electron-photon scattering to regimes of n>1 and arbitrary dispersion relations, including those describing surface plasmon polaritons. This approach allows for the study of the previously unexplored regime of extreme electromagnetic field confinement (n>>1). Such high levels of field confinement affect the physics of the problem significantly through implications such as a very high plasmon momentum, a phase and group velocity far below the speed of light, and a ratio of magnetic to electric field that is much smaller than in typical waveguide systems and in vacuum. In addition, the graphene plasmons—contrary to traditional Thomson scattering configurations—have electric fields whose z-components (Ez) can be comparable to the x-components (Ex) in the vicinity of the electron beam. These factors motivate a new formulation of the scattering problem that in fact applies to physical systems beyond plasmons in graphene, including other surface plasmon polaritons such as those in silver and gold, layered systems of metal-dielectric containing plasmon modes.
The single-sided spectral intensity of the radiation emitted by a charged particle bunch, based on a Fourier transform of radiation fields obtained via the Lienard-Wiechert potentials:
where {circumflex over (n)}={circumflex over (x)}cos ϕ+ŷsin ϕ+{circumflex over (z)}cos θ is the unit vector pointing in the direction of observation, ε0 is the permittivity of free space, N is the number of particles in the bunch, and {right arrow over (r)}j is the position of each of the charged particles. A Taylor expansion of the exponential factor gives:
where the ellipsis in the argument of the exponential abstracts away constant phase terms.
After substituting Equation (18), (17) and (20) into (19) and further simplification, for a single charged particle:
Equations (21) to (23) hold when losses are negligible, but make no assumption about the size of the confinement factor besides n≥1. Equations (21)-(23) apply to the interaction between any charged particle and a surface plasmon of arbitrary group and phase velocity, where the transverse velocity oscillations of the particle are small compared to the charged particle's longitudinal velocity component. These results thus apply to physical systems beyond plasmons in graphene, including other surface plasmons such as those in silver and gold, and layered systems of metal-dielectric containing plasmon modes. In addition, although electrons are used as an example, the above results apply to any charged particle when the corresponding values for charge and rest mass are used in Q and m respectively.
For a group of N charged particles of the same species having a distribution W(x,y), a replacement can be made in Equation (21), where it is assumed that the particles radiate in a completely incoherent fashion.
E02→NE0s2∫0∞W(x,y)exp(−2K0rx)dx (24)
Note that the exponential factor in the integrand arises from the exponential decay of the GP fields away from the surface, highlighting the importance of working with flat, low-emittance electron beams traveling as close as possible to the graphene surface. This can be especially important when n is large.
If a uniform random distribution of N charged particles (of the same species) is considered extending from x=x1 to x=x2 (0<x1<x2), the replacement becomes:
where Δx=x1−x2.
Owing to the high field enhancement of the GPs, fields on the order of several GV/m can be achievable from conventional continuous-wave (CW) lasers of several Watts, or pulsed lasers in the pJ-nJ range. Ultra-short laser pulses may allow access to even larger electric field strengths, thereby further enhancing output intensity. The use of pulses can benefit from synchronizing the arrival of the photon pulse with that of the electron pulse.
Assuming that the incident radiation excites a standing wave comprising counter-propagating GP modes—one of which co-propagates with the electrons—the output peak frequency as a function of device parameters and output angle θ is:
where ω±=ω0(1±nβ) and ω0 is the central angular frequency of the driving laser. In Equation (26), ωph+ is due to electron interaction with the counter-propagating GP, whereas ωph− is due to interaction with the co-propagating GP. Note that the rightmost expression in Equation (1) reduces to ωph+(ωph−) when θi=π (θi=0).
The spectrum of the emitted radiation as a function of its frequency ω, azimuthal angle ϕ and polar angle θ, making the assumption of high confinement factors n>>1 to achieve a completely analytical result:
where ε0 is the permittivity of free space, L is the spatial extent (intensity FWHM) of the GP, E0s is the peak electric field amplitude on the graphene, βg is the GP group velocity normalized to c, K≈nω0/c is the GP out-of-plane wavevector, Q is the electron charge (although the theory holds for any charged particle), and W(x,y) is the electron distribution in the beam (x is the distance from the graphene, as in
The first and second terms between the square brackets of Equation (27) correspond to spectral peaks associated with the counter-propagating (ωph+) and co-propagating (ωph−) parts of the standing wave, respectively.
More specifically,
The resulting 20 keV photons in
Space Charge and Electron Beam Divergence
This section examines the effect of space charge, i.e., inter-electron repulsion, and electron beam divergence on the output of the GP radiation source. To this end, regular circular beams and electron beams with elliptical cross-sections are used. These elliptical, or “flat”, charged-particle beams are of general scientific interest as they can transport large amounts of beam currents at reduced intrinsic space-charge forces and energies compared to their cylindrical counterparts. Elliptical electron beams can also couple efficiently to the highly-confined graphene plasmons, which occupy a relatively large area in the y-z plane, but can decay rapidly in the x-dimension.
The elliptical charged-particle beam has semi-axes X in the x-dimension and Y in the y-dimension and travels in the z-direction with the beam axis oriented along the z-axis (see inset of
where ρ′ is the charge density in the rest frame (primes are used to denote rest frame variables throughout this section). A beam current of I in the lab frame gives a lab frame charge density of ρ=I/(πXYv), where v is the speed of the charged particles in the z-direction, and a corresponding rest frame charge density of ρ′=ρ/γ, where γ is the relativistic Lorentz factor. According to the Newton-Lorentz equation, the resulting electromagnetic force in the lab frame gives the second-order differential equation for the evolution of the beam semi-axes:
where C=QI/(2πmε0γ3v3), Q and m are the charge and rest mass respectively of each particle, and z is the position along the beam in the z-direction, z=0 being the point of zero beam divergence (i.e. the focal plane of the charged particle beam), where X=X0, Y=Y0, and dX/dz=dY/dz=0. Note that the factor of γ3 in the denominator of C implies that the effect of space charge diminishes rapidly as the charged particles become more and more relativistic.
Equation (31) is accurate as long as the transverse velocity is small compared to the longitudinal velocity, and the transverse beam distribution remains approximately uniform. Equation (31) can be solved to get:
which is an implicit expression for X as a function of z. The beam divergence angle is:
The corresponding value of Y is given by: Y=X−X0+Y0.
Varying the parameter X in Equation (32) and then inverting z=z(X) to X=X(z) can get the solutions for X(z), which also gives Y(z) and θd(z) from Equation (33). In this way, the divergence angle and the semi-axes as a function of z along the charged-particle beam can be plotted, as shown in
As can be seen from the
When X-X0<<(X0+Y0)/2, as is the case in the plots of
Equation (34) holds for θd<<1. The appearance of Y0 in the denominator of terms in Equation (34) shows that, for a given X0, a more elliptical charged-particle beam profile can ameliorate the beam expansion and divergence due to space charge. The approximations in Equation (34) are useful analytical expressions for modeling the propagation of elliptical charged-particle beams.
The divergence of the electron beam (e.g., due to space charge and energy spread of the source) can be accounted for by performing multi-particle numerical simulations for beams with angular divergences of 0.1° and 1° relative to the z axis as shown in
For the 100 eV electron beam, a 0.1° divergence (
Ponderomotive Deflection of Electrons
In deriving Equation (27), it is assumed, first, that transverse and longitudinal electron velocity modulations are small enough that γ is approximately constant throughout the interaction and, second, that the beam centroid is displaced negligibly in the transverse direction, both of which are very good approximations in most cases of interest. Details of the derivation are already provided above, where the general problem of radiation scattered by electrons interacting with GP modes of arbitrary n (not just n>>1) is addressed. In addition, an expression is also derived below for the threshold beyond which our approximations break down due to ponderomotive deflection.
An advantage of a GP's large confinement factor in our scheme is to generate photons of relatively high energy with electrons of relatively low energy. When the relativistic mass of an electron is very small, however, the electron may be readily deflected away from the graphene surface by radiation pressure: the time-averaged ponderomotive force that pushes charged particles from regions of higher intensity to regions of lower intensity. This deflection potentially shortens the GP-electron interaction, resulting in lower output power than if the electron experienced an undeflected trajectory.
An important implication of the results in
In the interest of maximizing output spectral intensity, it is desirable to have as large an E0 as possible. However, too large an E0 may cause the electron to significantly deviate from its intended trajectory, resulting in a smaller effective interaction duration. One way to overcome the problem of ponderomotive deflection without having to decrease the GP intensity can use a symmetric configuration of graphene-coated dielectric slabs (i.e., a slab waveguide configuration), in which the electrons are confined to the minimum of an intensity well formed by surface plasmon-polaritons above and below the electron bunch. Recent advances in creating graphene heterostructures might make this configuration desirable for a GP-base radiation source device.
Full Electromagnetic Simulation
This section describes full electromagnetic simulations that also include the electrons dynamics. The presented results are for two particular set of parameters that both lead to hard X-ray radiation. Both options are simulated for an electron beam going parallel to the side of a graphene sheet placed on a silicon substrate.
Frequency Down-Conversion and THz Generation
This section describes a frequency down-conversion scheme to generate compact, coherent, and tunable terahertz light. Demand for terahertz sources is being driven by their usefulness in many areas of science and technology, ranging from material characterization to biological analyses and imaging applications. Free-electron methods of terahertz generation are typically implemented in large accelerator installations, making compact alternatives desirable.
Approaches described in this section use a configuration in which light co-propagates with the electron. The phase velocity of the light can be slower than the speed of light in vacuum, which may be achieved with the cladding mode of a dielectric waveguide (e.g., cylindrical, rectangular, planar etc.) or using a surface plasmon polariton with a squeezing factor n>1 (phase velocity of the SPP is then c/n). The field in the waveguide may be oscillating at optical or infrared frequencies (technically, any frequency is possible).
The output frequency may be tuned by adjusting the energy of the input electron pulse. Down-converted radiation is collected in the forward direction. The on-axis output frequency v is given by:
v=v0(1−nβ0)/(1−β0) (35)
where v0 is the frequency of the electromagnetic wave that excites the SPP field and β0 is the initial speed of the electron in the +z direction.
Electrons Beam Oblique to 2D Systems
In previous sections, electrons are generally propagating substantially parallel to graphene layers. In contrast, this section describes the situations in which electrons are propagating at an oblique angle with respect to the graphene layers or photonic crystals.
The interaction of electron beams launched perpendicularly (or with some angle) onto a layered structure can have several promising applications for the creation of new sources of radiation. This type of radiation is generally referred to as transition radiation. Transition radiation is a form of electromagnetic radiation emitted when a charged particle passes through inhomogeneous media, such as a boundary between two different media. This is in contrast to Cerenkov radiation. The emitted radiation is the homogeneous difference between the two inhomogeneous solutions of Maxwell's equations of the electric and magnetic fields of the moving particle in each medium separately. In other words, since the electric field of the particle is different in each medium, the particle has to “shake off” the difference of energy when it crosses the boundary.
The total energy loss of a charged particle on the transition depends on its Lorentz factor γ=E/mc2 and is mostly directed forward, peaking at an angle of the order of 1/γ relative to the particle's path. The intensity of the emitted radiation is roughly proportional to the particle's energy E. The characteristics of transition radiation make it suitable for particle discrimination, particularly of electrons and hadrons in the momentum range between 1 GeV/c and 100 GeV/c. The transition radiation photons produced by electrons have wavelengths in the X-ray range, with energies typically in the range from 5 to 15 keV.
Conventional transition radiation systems are normally based on bulky and expensive systems, thereby limiting the usefulness and widespread adoption. However, with new materials, new fabrication methods, and new theoretical techniques from nano-photonics, there are a lot of new possibilities to make revolutionary applications. One such application can be a table-top x-ray source based on the principle of transition radiation that can be made possible
Coherent Light Generation and Light-Matter Interaction in IR-Visible-UV Regime Using Resonant Transition Radiation
In this regime strong effects on the emitted photons can emerge from the theory of photonic crystals. A variety of different multilayer structures (isotropic photonic crystal, anisotropic photonic crystal, or metamaterials, etc.) can be used. Creating a resonance in the emitted spectrum can produce monochromatic radiation, and can create a new way to generate coherent light. In one example, using one dimensional photonic crystal angular selective behavior can be achieved. With this property, beam steering of created IR-visible-UV light can be achieved. In another example, a laser can be created from the multilayer structure, where there is no need for a gain material—the electron beam can be used instead of or in addition to gain.
Resonant Transition Radiation Near Plasma Frequency Regime
In this regime, the effective dielectric constant of materials can drop below 1 to zero, and even to negative values. This opens up many possibilities—usually considered unique to metamaterials—that can now be realized here. For example, metamaterials with refractive index less than 1 (or negative) can be used to make very thin absorbers, electrically small resonators, phase compensators, and improved electrically small antennas. These might be used for an enhanced slowing down of the electron, for controlling its velocity, energy spread, or even its wave function. Since the transition radiation spectrum is broadband, the light generated in that frequency regime can see a system that is very different from visible light in photonic crystals. This can lead to a new state of matter and many new applications, including slow light, light trapping, nanoscale resonators and possibly light cloaking.
X-Ray and Soft-X-Ray Generation
The transition radiation from a stack of very thin layers (several nanometers to several tens of nanometers) can cause an electron beam to emit x-ray. This does not require a highly relativistic electron beam. Moderately relativistic electron beams (several hundreds of KeVs to several MeVs), even with slower electrons over several tens of KeVs) can still produce x-ray in this way. Significant improvements in fabrication methods in recent years now allow for the fabrication of such stacked structures. Structures in higher dimensions (2D and 3D photonic crystals, and metallic photonic crystal) can be even more suitable for x-ray generation. The resulting radiation can be emitted at a wavelength that is close to the layer thickness divided by γ—the effect of γ may not be significant here, because it is close to 1. Still, the radiation is in the x-ray thanks to the layers being very thin.
In the past, the limitations on fabrication methods allowed only for thick layers, in turn requiring very energetic electron beams to achieve radiation in the x-ray regime. The possibility of making very thin layers allows X-ray generation without high energy electron beams. It is worth noting that previously, very large scale (and expensive) electron acceleration systems were needed in order to accelerate electrons to MeV or GeV energies and produce X-ray radiation. However, if electron energy can be reduced to tens or hundreds of KeVs, it would be much easier and cheaper to generate such electrons. Consequently, the system size cost for an x-ray source would be significantly reduced.
Multiple 2DEG Layers
By Placing a Graphene Sheet (or Several Sheets) in Between Each of the Layers, or by placing other metallic layers that support surface plasmons, one can increase the efficiency of the transition radiation. The result is producing higher intensity radiation. For most materials the transition radiation becomes smaller when the layer thickness is smaller than the formation length. This limit can disappear when the surface of the layer supports surface plasmons. These surface plasmons can enhance the transition radiation, so that even very thin layers (thinner than the formation length) can still cause significant transition radiation to be emitted. This can potentially reduce the size and cost of an x-ray source even more.
This approach can also operate with 2DEG systems on the interface between different materials other than graphene layers. There are several other scenarios where the physics of 2DEG is found. For example, the interface between BaTiO3 and LaAlO3, or the interface between lanthanum aluminate (LaAlO3) and strontium titanate (SrTiO3) can be used as 2DEG systems. In another example, layers of ferromagnetic materials can also be used to construct 2DEG.
The multiple 2DEG layer structure can include a couple of tens of dielectric (or metallic) layers. A higher number of layers can generally improve the result such as increasing the output intensity and/or improving the monochromatic quality.
The multiple 2DEG layer structure can be further improved by adding small holes within the stack of layers. If the holes are smaller than the wavelength, they normally do not affect the emission of radiation, while the electrons can pass through them. In this way, the electrons can propagate through a longer distance in the stack structure before they slow down and stop emitting radiation. A longer penetration depth (also a longer mean free path) can allow more layers to take part in the radiation emission.
Cerenkov-Like Effect
This section describes graphene-based devices that emits radiation through a Cerenkov-like effect, induced from current flowing through the graphene sheet (suspended on dielectric or not). This approach does not require any external source of electromagnetic radiation, and is therefore highly attractive for on-chip CMOS compatible applications.
This approach can achieve direct coupling between electric current and SPPs in graphene. These SPP can be coupled to radiation modes in several ways, including creating defects on graphene, making a grating (1D or 2D) on graphene, making a grating (2D or 2D) from graphene (by patterning the graphene sheet), modulating the voltage applied on graphene to create a periodic refractive index that can allow tunable control of the radiation, fabricating almost any photonic crystal (any periodic dielectric structure) as the substrate of the graphene, specially designed photonic crystal that has high density of states at a particular frequency above the light cone, which can be achieved by employing one or more unique band structure properties such as van-Hove singularities, flat bands around Dirac points, or super-collimation contours.
To improve the efficiency of the effect, the electric current can be configured to include electrons that have the smaller velocity spread (i.e., more uniform velocity distribution). This is possible to graphene due to its Dirac cone band structure. In addition, the graphene can be doped to have high enough mobility so that the phase velocity of the graphene SPP can be lower than the velocity of the electrons. This can be seen by comparing the “squeezing factor” n from above, which has to be larger than the ratio between the speed of light and the electron velocity. A proper design of the electron current can create electrons moving at the Fermi velocity, which can be 300 times slower than the speed of light. This means that n>300 can already create the desired effect. Such values of n are achievable as shown in above sections.
The radiation can be emitted in four possible regimes, each requiring a different kind of structure. For example, Terahertz radiation can be created without doping the graphene. Infrared radiation can be achieved by doping the graphene. Visible light can be created by high doing of graphene, while UV light can be created based on additional plasmonic range in the UV region.
The phenomenon of a Cerenkov-like coupling between electron current and SPPs in graphene can be the first occurrence of Cerenkov radiation from bounded electrons in nature. This is bound to lead to more attractive applications based on the same phenomenon, since it bridges the gap between photonics and electronics.
A related effect exists in existing methods, in which a periodic structure interacts with flowing electrons. The difference between this existing idea and the approach described herein is that the existing idea is based on a Smith-Purcell radiation, and does not use the SPP modes of the system, which can be important for an efficient process.
The electron beam can be sent in the air/vacuum near the graphene sample. It can be beneficial for the free electron beam to pass very close to the sample (on the order of nanometers—similar to the wavelength of the graphene SPP). The advantage of this technique is that the velocity of the electron beam can be fully controlled and does not depend on graphene properties.
Since the Cerenkov-like effect can directly couple DC current to light (in the form of plasmons), it can have several other applications, including measurement the distribution of velocities in the graphene, measurement the conductivity, integrating optics with electronics for on-chip photonic capabilities, feedback effects where external light (coupled to plasmons) changes the properties of the plasmon excitations to influence the current (inverse Cerenkov) that can accelerate the electrons and also change the resistivity.
The same approach can be implemented in other 2DEG systems or even in other plasmonic systems. Notice that even in regular plasmonic systems, the Cerenkov-like generation of plasmons was never studied nor used to any of the applications we proposed here.
Quantum Čerenkov Effect from Hot Carriers in Graphene
Achieving ultrafast conversion of electrical to optical signals at the nanoscale using plasmonics can be a long-standing goal, due to its potential to revolutionize electronics and allow ultrafast communication and signal processing. Plasmonic systems can combine the benefits of high frequencies (1014−1015 Hz) with those of small spatial scales, thus avoiding the limitation of conventional photonic systems, by using the strong field confinement of plasmons. However, the realization of plasmonic sources that are electrically pumped, power efficient, and compatible with current device fabrication processes (e.g. CMOS), can be challenging.
This section describes that under proper conditions charge carriers propagating within graphene can efficiently excite GPs, through a 2D Čerenkov emission process. Graphene can provide a platform, on which the flow of charge alone can be sufficient for Čerenkov radiation, thereby eliminating the need for accelerated charge particles in vacuum chambers and opening up a new platform for the study of ČE and its applications, especially as a novel plasmonic source. Unlike other types of plasmon excitations, the 2D ČE can manifest as a plasmonic shock wave, analogous to the conventional ČE that creates shockwaves in a 3D medium. On a quantum mechanical level, this shockwave can be reflected in the wavefunction of a single graphene plasmon emitted from a single hot carrier.
The mechanism of 2D ČE can benefit from two characteristics of graphene. On the one hand, hot charge carriers moving with high velocities
are considered possible, even in relatively large sheets of graphene (10 μm and more). On the other hand, plasmons in graphene can have an exceptionally slow phase velocity, down to a few hundred times slower than the speed of light. Consequently, velocity matching between charge carriers and plasmons can be possible, allowing the emission of GPs from electrical excitations (hot carriers) at very high rates. This can pave the way to new devices utilizing the ČE on the nanoscale, a prospect made even more attractive by the dynamic tunability of the Fermi level of graphene. For a wide range of parameters, the emission rate of GPs can be significantly higher than the rates previously found for photons or phonons, suggesting that taking advantage of the ČE allows near-perfect energy conversion from electrical energy to plasmons.
In addition, contrary to expectations, plasmons can be created at energies above 2Ef—thus exceeding energies attainable by photon emission—resulting in a plasmon spectrum that can extend from terahertz to near infrared frequencies and possibly into the visible range.
Furthermore, tuning the Fermi energy by external voltage can control the parameters (direction and frequency) of enhanced emission. This tunability also reveals regimes of backward GP emission, and regimes of forward GP emission with low angular spread; emphasizing the uniqueness of ČE from hot carriers flowing in graphene.
GP emission can also result from intraband transitions that are made possible by plasmonic losses. These kinds of transitions can become significant, and might help explain several phenomena observed in graphene devices, such as current saturation, high frequency radiation spectrum from graphene, and the black body radiation spectrum that seems to relate to extraordinary high electron temperatures.
Conventional studies, which generally focus on cases of classical free charge particles moving outside graphene, have revealed strong Čerenkov-related GP emission resulting from the charge particle-plasmon coupling. In contrast, this work focuses on the study of charge carriers inside graphene, as illustrated in
A quantum theory of ČE in graphene is developed. Analysis of this system gives rise to a variety of novel Čerenkov-induced plasmonic phenomena. The conventional threshold of the ČE in either 2D or 3D (v>vp) may seem unattainable for charge carriers in graphene, because they are limited by the Fermi velocity v≤vf, which is smaller than the GP phase velocity vf<vp, as shown by the random phase approximation calculations. However, quantum effects can come into play to enable these charge carriers to surpass the actual ČE threshold. Specifically, the actual ČE threshold for free electrons can be shifted from its classically-predicted value by the quantum recoil of electrons upon photon emission. Because of this shift, the actual ČE velocity threshold can in fact lie below the velocity of charge carriers in graphene, contrary to the conventional predictions. At the core of the modification of the quantum ČE is the linearity of the charge carrier energy-momentum relation (Dirac cone). Consequently, a careful choice of parameters (e.g. Fermi energy, hot carrier energy) allows the ČE threshold to be attained—resulting in significant enhancements and high efficiencies of energy conversion from electrical to plasmonic excitation.
The quantum ČE can be described as a spontaneous emission process of a charge carrier emitting into GPs, calculated by Fermi's golden rule. The matrix elements can be obtained from the light-matter interaction term in the graphene Hamiltonian, illustrated by a diagram like
For the case of low-loss GPs, the calculation reduces to the following integral:
Where Mk
The GP momentum q=(qy, qz) satisfies ω2/vp2=qy2+qz2, with the phase velocity vp=vp(ω) or vp(q) obtained from the plasmon dispersion relation as vp=ω/q. The momenta of the incoming (outgoing) charge carrier ki=(kiy, kiz) (kf=(kfy, kfz)) correspond to energies Ek
Where
is the fine structure constant, c is the speed of light, and
It can be further defined that the angle φ for the outgoing charge and θ for the GP, both relative to the z axis, which is the direction of the incoming charge. This notation allows simplification of the spinor-polarization coupling term [SP] for charge carriers inside graphene to |SP|2=cos2(θ−φ/2) or |SP|2=sin2(θ−φ/2) for intraband or interband transitions respectively. The delta functions in Equation (38) can restrict the emission to two angles θ=±θČ (a clear signature of the ČE), and so we simplify the rate of emission to:
By setting →0 in the above expressions, one can recover the classical 2D ČE, including the Čerenkov angle cos(θČ)=vp/v, that can also be obtained from a purely classical electromagnetic calculation. However, while charge particles outside of graphene satisfy ω<<Ei, making the classical approximation almost always exact, the charges flowing inside graphene can have much lower energies because they are massless. Consequently, the introduced terms in the ČE expression modifies the conventional velocity threshold significantly, allowing ČE to occur for lower charge velocities. e.g., while the conventional ČE requires charge velocity above the GP phase velocity (v>vp), Equation (39a) allows ČE below it, and specifically requires the velocity of charge carriers in graphene (v=vf) to reside between
Physically, the latter case involves interband transitions made possible when graphene is properly doped: when the charge carriers are hot electrons (holes) interband ČE requires negatively (positively) doped graphene.
The inequalities can be satisfied in two spectral windows simultaneously for the same charge carrier, due to the frequency dependence of the GP phase velocity (shown by the intersection of the red curve with the blue regime in
Several spectral cutoffs appear in
To incorporate the GP losses (as we do in all the figures), the matrix elements calculation can be modified by including the imaginary part of the GP wavevector qI=qI(ω), derived independently for each point of the GP dispersion curve. This is equivalent to replacing the delta functions in Equation (38) by Lorentzians with 1/γ width, defining γ(ω)=qR(ω)/qI(ω). The calculation can be done partly analytically yielding:
The immediate effect of the GP losses can be the broadening of the spectral features, as shown in
The interband ČE in
There exist several possible avenues for the observation of the quantum ČE in GPs, having to do with schemes for exciting hot carriers. For example, apart from photoexcitation, hot carriers have been excited from tunneling current in a heterostructure, and by a biased STM tip, therefore, GPs with the spectral features presented here (
In case the hot carriers are directional, measurement of the GP Čerenkov angle (e.g.
Hot carriers generated from a tunneling current or p-n junction may have a wide energy distribution (instead of a single Ei). The ČE spectrum corresponding to an arbitrary hot carrier excitation energy distribution is readily computed by integrating over a weighted distribution of ČE spectra for monoenergetic hot carriers. The conversion efficiency remains high even when the carriers energy distribution is broad, as implied by the high ČE efficiencies for the representative values of Ei studied here (
The ČE emission of GPs can be coupled out as free-space photons by creating a grating or nanoribbons—fabricated in the graphene, in the substrate, or in a layer above it—with two arbitrarily-chosen examples marked by the green dots in
The hot carrier lifetime due to GP emission in doped graphene is defined by the inverse of the total rate of GP emission, and can therefore be exceptionally short (down to a few fs). Such short lifetimes are in general agreement with previous research on the subject that have shown electron-electron scattering as the dominant cooling process of hot carriers, unless hot carriers of relatively high energies (Ei≈2Ef and above) are involved. In this latter case, one can expect single-particle excitations to prevail over the contribution of the plasmonic resonances. This is also in agreement with the fact that plasmons with high energies and momenta (in the electron-hole continuum, pink areas in
The high rates of GP emission also conform to research of the reverse process—of plasmons enhancing and controlling the emission of hot carriers—that is also found to be particularly strong in graphene. This might reveal new relations between ČE to other novel ideas of graphene-based radiation sources that are based on different physical principles.
It is also worth noting that Čerenkov-like plasmon excitations from hot carriers can be found in other condensed matter systems such as a 2D electron gas at the interface of semiconductors. Long before the discovery of graphene, such systems have demonstrated very high Fermi velocities (even higher than graphene's), while also supporting meV plasmons that can have slow phase velocities, partly due to the higher refractive indices possible in such low frequencies. The ČE coupling, therefore, can also be found in materials other than graphene. In many cases, the coupling of hot carriers to bulk plasmons is even considered as part of the self-energy of the carriers, although the plasmons are then considered as virtual particles in the process. Nonetheless, graphene can offer opportunities where the Čerenkov velocity matching can occur at relatively high frequencies, with plasmons that have relatively low losses. These differences can make the efficiency of the graphene ČE very high.
While various inventive embodiments have been described and illustrated herein, those of ordinary skill in the art will readily envision a variety of other means and/or structures for performing the function and/or obtaining the results and/or one or more of the advantages described herein, and each of such variations and/or modifications is deemed to be within the scope of the inventive embodiments described herein. More generally, those skilled in the art will readily appreciate that all parameters, dimensions, materials, and configurations described herein are meant to be exemplary and that the actual parameters, dimensions, materials, and/or configurations will depend upon the specific application or applications for which the inventive teachings is/are used. Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, many equivalents to the specific inventive embodiments described herein. It is, therefore, to be understood that the foregoing embodiments are presented by way of example only and that, within the scope of the appended claims and equivalents thereto, inventive embodiments may be practiced otherwise than as specifically described and claimed. Inventive embodiments of the present disclosure are directed to each individual feature, system, article, material, kit, and/or method described herein. In addition, any combination of two or more such features, systems, articles, materials, kits, and/or methods, if such features, systems, articles, materials, kits, and/or methods are not mutually inconsistent, is included within the inventive scope of the present disclosure.
The above-described embodiments can be implemented in any of numerous ways. For example, embodiments of designing and making the technology disclosed herein may be implemented using hardware, software or a combination thereof. When implemented in software, the software code can be executed on any suitable processor or collection of processors, whether provided in a single computer or distributed among multiple computers.
Further, it should be appreciated that a computer may be embodied in any of a number of forms, such as a rack-mounted computer, a desktop computer, a laptop computer, or a tablet computer. Additionally, a computer may be embedded in a device not generally regarded as a computer but with suitable processing capabilities, including a Personal Digital Assistant (PDA), a smart phone or any other suitable portable or fixed electronic device.
Also, a computer may have one or more input and output devices. These devices can be used, among other things, to present a user interface. Examples of output devices that can be used to provide a user interface include printers or display screens for visual presentation of output and speakers or other sound generating devices for audible presentation of output. Examples of input devices that can be used for a user interface include keyboards, and pointing devices, such as mice, touch pads, and digitizing tablets. As another example, a computer may receive input information through speech recognition or in other audible format.
Such computers may be interconnected by one or more networks in any suitable form, including a local area network or a wide area network, such as an enterprise network, and intelligent network (IN) or the Internet. Such networks may be based on any suitable technology and may operate according to any suitable protocol and may include wireless networks, wired networks or fiber optic networks.
The various methods or processes (outlined herein may be coded as software that is executable on one or more processors that employ any one of a variety of operating systems or platforms. Additionally, such software may be written using any of a number of suitable programming languages and/or programming or scripting tools, and also may be compiled as executable machine language code or intermediate code that is executed on a framework or virtual machine.
In this respect, various inventive concepts may be embodied as a computer readable storage medium (or multiple computer readable storage media) (e.g., a computer memory, one or more floppy discs, compact discs, optical discs, magnetic tapes, flash memories, circuit configurations in Field Programmable Gate Arrays or other semiconductor devices, or other non-transitory medium or tangible computer storage medium) encoded with one or more programs that, when executed on one or more computers or other processors, perform methods that implement the various embodiments of the invention discussed above. The computer readable medium or media can be transportable, such that the program or programs stored thereon can be loaded onto one or more different computers or other processors to implement various aspects of the present invention as discussed above.
The terms “program” or “software” are used herein in a generic sense to refer to any type of computer code or set of computer-executable instructions that can be employed to program a computer or other processor to implement various aspects of embodiments as discussed above. Additionally, it should be appreciated that according to one aspect, one or more computer programs that when executed perform methods of the present invention need not reside on a single computer or processor, but may be distributed in a modular fashion amongst a number of different computers or processors to implement various aspects of the present invention.
Computer-executable instructions may be in many forms, such as program modules, executed by one or more computers or other devices. Generally, program modules include routines, programs, objects, components, data structures, etc. that perform particular tasks or implement particular abstract data types. Typically the functionality of the program modules may be combined or distributed as desired in various embodiments.
Also, data structures may be stored in computer-readable media in any suitable form. For simplicity of illustration, data structures may be shown to have fields that are related through location in the data structure. Such relationships may likewise be achieved by assigning storage for the fields with locations in a computer-readable medium that convey relationship between the fields. However, any suitable mechanism may be used to establish a relationship between information in fields of a data structure, including through the use of pointers, tags or other mechanisms that establish relationship between data elements.
Also, various inventive concepts may be embodied as one or more methods, of which an example has been provided. The acts performed as part of the method may be ordered in any suitable way. Accordingly, embodiments may be constructed in which acts are performed in an order different than illustrated, which may include performing some acts simultaneously, even though shown as sequential acts in illustrative embodiments.
All definitions, as defined and used herein, should be understood to control over dictionary definitions, definitions in documents incorporated by reference, and/or ordinary meanings of the defined terms.
The indefinite articles “a” and “an,” as used herein in the specification and in the claims, unless clearly indicated to the contrary, should be understood to mean “at least one.”
The phrase “and/or,” as used herein in the specification and in the claims, should be understood to mean “either or both” of the elements so conjoined, i.e., elements that are conjunctively present in some cases and disjunctively present in other cases. Multiple elements listed with “and/or” should be construed in the same fashion, i.e., “one or more” of the elements so conjoined. Other elements may optionally be present other than the elements specifically identified by the “and/or” clause, whether related or unrelated to those elements specifically identified. Thus, as a non-limiting example, a reference to “A and/or B”, when used in conjunction with open-ended language such as “comprising” can refer, in one embodiment, to A only (optionally including elements other than B); in another embodiment, to B only (optionally including elements other than A); in yet another embodiment, to both A and B (optionally including other elements); etc.
As used herein in the specification and in the claims, “or” should be understood to have the same meaning as “and/or” as defined above. For example, when separating items in a list, “or” or “and/or” shall be interpreted as being inclusive, i.e., the inclusion of at least one, but also including more than one, of a number or list of elements, and, optionally, additional unlisted items. Only terms clearly indicated to the contrary, such as “only one of” or “exactly one of,” or, when used in the claims, “consisting of,” will refer to the inclusion of exactly one element of a number or list of elements. In general, the term “or” as used herein shall only be interpreted as indicating exclusive alternatives (i.e., “one or the other but not both”) when preceded by terms of exclusivity, such as “either,” “one of,” “only one of,” or “exactly one of” “Consisting essentially of,” when used in the claims, shall have its ordinary meaning as used in the field of patent law.
As used herein in the specification and in the claims, the phrase “at least one,” in reference to a list of one or more elements, should be understood to mean at least one element selected from any one or more of the elements in the list of elements, but not necessarily including at least one of each and every element specifically listed within the list of elements and not excluding any combinations of elements in the list of elements. This definition also allows that elements may optionally be present other than the elements specifically identified within the list of elements to which the phrase “at least one” refers, whether related or unrelated to those elements specifically identified. Thus, as a non-limiting example, “at least one of A and B” (or, equivalently, “at least one of A or B,” or, equivalently “at least one of A and/or B”) can refer, in one embodiment, to at least one, optionally including more than one, A, with no B present (and optionally including elements other than B); in another embodiment, to at least one, optionally including more than one, B, with no A present (and optionally including elements other than A); in yet another embodiment, to at least one, optionally including more than one, A, and at least one, optionally including more than one, B (and optionally including other elements); etc.
In the claims, as well as in the specification above, all transitional phrases such as “comprising,” “including,” “carrying,” “having,” “containing,” “involving,” “holding,” “composed of,” and the like are to be understood to be open-ended, i.e., to mean including but not limited to. Only the transitional phrases “consisting of” and “consisting essentially of” shall be closed or semi-closed transitional phrases, respectively, as set forth in the United States Patent Office Manual of Patent Examining Procedures, Section 2111.03.
This application claims priority to U.S. provisional application Ser. No. 62/111,180, filed Feb. 3, 2015, entitled “NOVEL RADIATION SOURCES FROM THE INTERACTION OF ELECTRON BEAMS WITH SURFACE PLASMON SYSTEMS,” which is hereby incorporated herein by reference in its entirety.
This invention was made with Government support under Grant No. W911NF-13-D-0001 awarded by the U.S. Army Research Office. The Government has certain rights in the invention.
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62111180 | Feb 2015 | US |