^■ TECHNICAL FIELD

The present invention is concerned with a laser based method and system for materials analysis and imaging.

BACKGROUND

Any references to methods, apparatus or documents of the prior art are not to be taken as constituting any evidence or admission that they formed, or form part of the common general knowledge.

Significant scientific effort has been invested in the realization of imaging and materials analysis systems over the past two decades. One outcome of this effort is that THz time- domain spectroscopy (TDS) has established itself as a significant tool for coherently probing solid-state, liquid, and gaseous systems at THz frequencies. Key to the success of THz TDS is its capability of measuring complex refractive indices of samples over baiidwidths as large as 1.00 THz, due to its intrinsic ability to resolve th electric field amplitude of broadband THz pulses coherently and with subpicosecond resolution, as well as its insensitivity to thermal, background radiation. However, THz TDS systems in general have signal-to-noise ratios (SNRs) that are practically useful only below -3 THz. Furthermore, their spectral resolution is typically limited to no better than ~-5 GHz (worse in high-bandwidth systems), and they are restricted to low THz powers on the order of 10-100 μψ for commonly used optically-pumped photoconductive emitters. Moreover, spectroscopic data acquisition is slow and the technique relies on bulky and expensive ultrafast laser sources for the generation and coherent detection of THz radiation.

Recently the THz quantum cascade laser (QCL) has emerged as the established laboratory source of high-power radiation in the frequency range -1-5 THz. THz QCLs have been show to exhibit remarkable spectral purity with quantum-limited linewidths, making them ideally-suited to coherent THz systems. Nevertheless, owing to the challenges of coherently detecting the emission from such sources, most system developments have focussed on incoherent approaches to imaging and materials analysis. Coherent detection schemes have, however, permitted the phase and/or frequency of the THz field to be resolved. By exploiting the heterodyne mixing between a free-running QCL and a local oscillator derived from a gas laser, high-resolution frequency-resolved gas spectroscopy has been reported. Phase-sensitive detectio using a heterodyne approach has also enabled coherent inverse synthetic aperture radar imaging. However, heterodyne systems generally suffer from the disadvantage that they are complex and bulky

It is an object of the invention to provide a laser based imaging or remote materials sensing system that is an improvement, or at least a useful alternative, to the aforementioned systems of the prior art.

SUMMARY OF THE INVENTIO

According to a first aspect of the present invention there is provided a method for investigating a target comprising the steps of:

directing a first beam of radiation from a laser at the target to thereby produce a second beam of laser radiatio by interaction of the first beam with the target wherein self-mixing of the first and second beams occurs with in the laser;

varying a parameter affecting the interaction of the first bea with the target; detecting a signal arising from the self-mixing; and

processing the signal to thereby determine phase and amplitude changes associated with material properties of the target .

Preferably the laser comprises a quantum cascade laser (QCL).

Alternatively, the laser may comprise any one of

an interband quantum cascade (ICL) laser; or

a Helium eon gas laser; or

a Carbon Dioxide laser; or

an optically pumped fiber laser.

Preferabl the laser is arranged to operate in the terahertz (THz) band. Alternatively, it may be arranged to operate in another frequency band such as the infrared band. Preferabl the step of detecting the signal involves measuring an electrical signal across term inal s of the laser.

Preferably the step of varying a parameter of the first beam of laser radiation includes applying a modulation to a current for driving the laser.

Preferably the modulation comprises a continuous wave frequency modulation of the laser beam frequency. For example, in the preferred embodiment of the invention the modulation comprises superimposing a modulating saw-tooth current signal onto a dc current supply for the semiconductor laser.

In a preferred embodiment of the invention the step of processing the signal includes detecting a first type of change of a waveform of the signal associated with a phase shift imparted by the interaction of the first beam with the target. For example the first type of change of the waveform may comprise a phase shift of the waveform.

Preferably the step of processing the signal further includes detecting a second type of change of the waveform of the signal associated with an attenuation imparted by the interaction of the first beam with the target. For example the second type of change may comprise a narrowing or widening of a peak of the waveform or a change in the ampli tude of the wa veform

In an alternative embodiment of the present invention the step of varying the parameter may comprise moving the target longitudinally relative to a source of the first beam of laser radiation.

The method may include processing the signal to thereby determine phase and amplitude changes associated with material properties of the target to derive a refractive index (n) and an extinction coefficient ( A) of the target.

Where the method includes processing the signal to determine the refractive inde («) and extinction coefficient (k) of the target the method will preferably further involve causing the first beam of laser radiation to interact with a portion of the target having known properties. Preferably the method includes fitting a mathematical model of the laser self-mixing to data for each of a number of positions of the target to obtain a set of parameter values for each of the positions. The method may include applying known values of n and A of two materials from said portion of the target to thereby derive n and A' of a third material of the target, being a material under test.

The method may include mechanically scanning the target by moving the target relative to the laser to thereby sense variations in the properties of the target as a function of location thereof.

The method may include processing tire sensed variations in the properties of the target to produce an image of the target.

In a preferred embodiment of the invention the method includes measuring variations in the si gnal at each of a number of positions during the mechanical scanning.

Preferabl the method includes removing the effect of power modulation of the laser from each of said measurements. For example, the step of removing the effect of power modulation may comprise subtracting a reference slope from measurements made at each of the positions. in a preferred embodiment of the invention the measurements are taken to avoid the effect of transients at the edges of the modulation period of the laser.

For example, the method may itvciude processing only a central portion of each period of the signal at each scanning position. In a preferred embodiment of the invention the method includes determining a reflection coefficient of the target at each position.

The step of determining the reflection coefficient may be based o the integral of the absolute value of the signal over time . The method may include producing an image from the target by fitting time domai traces of the signal to a mathematical model of the laser feedback self-mixing to thereby calculate variations in a feedback parameter of the model wherein the image is generated by plotting the feedback par ameter for each of a number of the positions.

According to a further embodiment of the present invention there is provided a system for investigating a target comprising:

a laser;

a target assembly arranged to return a beam from the laser to the laser after interaction with a target of said assembl y:

a data acquisition assembly responsive to electrical terminals of the laser; and a computational device responsive to the data acquisition assembly, wherei the computational device is programmed to determine phase and amplitude changes associated with the target and imparted on to the beam by interaction therewith.

Preferably the laser is under control of the computational device for operation of the laser and variation of its operating parameters.

Preferabl the system further includes a translation assembly arranged to impart a relative motion between the laser and the target.

In a preferred embodiment of the invention the translation assembly includes one or more actuators under control of the computational device wherein the computational device is programmed to operate the translation assembly for data acquisition at each of a number of positions of the target. According to a tint hoc aspect of the present invention there is provided a computer software product comprising a media, for example an optical, magnetic or solid state data storage device, bearing tangible machine readable instructions for an electronic processor to:

operate a laser to direct a laser beam at a target assembly;

acquire electrical data being a function of self-mixing of the laser beam with a reflection thereof from the target assembly; and

determine phase and amplitude changing properties of a target portion of the target assembly on the basis of the acquired electrical data.

BRIEF DESCRIPTION OF THE DRAWI NGS

Preferred features, embodiments and variations of the invention may be discerned from the followin Detailed Description which provides sufficient information for those skilled in the art to perform the invention. The Detailed Description is not to be regarded as limiting the scope of the preceding Summar of the Invention in any way. The Detailed Description will make reference to a number of drawings as follows;

Figure 1 is a schematic diagram showing an intensity, and frequency modulated, self- mixing laser interferometer according to a preferred embodiment of the present invention.

Figure IB is a graph of a self-mixing signal observed through variation in laser terminal voltage as a function of time wherein the broken line represents a reference slope and the solid line represents typical voltage signal due to the self-mixing.

Figure IC is a graph of a single period T of the self-mixing signal showing the effect of increasing refractive index n of the target. The waveform narrows with increasing n, and the peak shifts to a later time. Figure I D is a graph of a single period T of the self-mixing signal showing the effect of increasing extinction coefficient k of the target which mainly translates the waveform to a later time. Figure 2A is a graph of a current stimulus signal applied to the QCL of Figure 2C. The current range was selected to sweep the laser frequency through three external cavity resonances in the region where the laser was most sensitive to optical feedback. Figure 2B is a graph corresponding to that of Figure 2A hut of the voltage signal measured across the laser terminals. For illustrative purposes, the magnitude of the self- mixing signal has been increased ten-fold.

Figure 2C depicts a system according to a preferred embodiment of the present invention for imaging of a reflective target wherein a QCL is driven by a sawtooth current signal and the QCL terminal voltage variations are acquired using a PC-based data acquisition card (ADC). A pair of parabolic mirrors focuses the beam onto a remote target assembly including a remote target containing materials under test, mounted on a computer- controlled translation stage.

Figure 2D depicts a version of the system of Figure 2C adapted for analysis of a light transmissive sample. In Figure 2D, flat mirror 42b is used instead of parabolic reflector 42 in figure 2C. Figure 3 A is a photograph of the front surface of a target of Figure 2C discussed during an explanation of the use of the system. The three circular regions are materials under test embedded in an aluminium holder, namely PA6 PVC and POM.

Figure 3.B is a two-dimensional representation of time domain self-mixing signals acquired along representative line 70 in Figure 3A, each showing three fringes. The vertical axis represents the temporal evolution of the signal whilst horizontal axis shows their spatial dependence.

Figure 3C shows an amplitude-like image wherein a pseudo-colour plot represents the effective aggregate differenc between the time domain trace relative to the reference slope. Figure 3D shows a phase-like image wherein a pseudo-colour plot is based on the temporal location of the representative peak of the sel f-m ixing signal relati ve to the edge of the modulation waveform. Figure 3E depicts a representative time domain waveforms for one spatial pixel on the target per material (solid lines) with corresponding model fits (broken lines). The common reference slope has been removed,

DETAILE D DESCRIPTION OF PREFERRED EMBODI M ENTS

A preferred embodiment of the present invention comprises a method for coherent imaging and materials analysis using a THz QCL feedback interferomete 2 in reflection mode. At the heart of this scheme is the realization that a portion 1.4 of the emitted TBz radiation, returning from an external target 10, when re-injected into the laser cavity 5, yields information about both amplitude and phase change properties of the remote target that are discernible through changes in laser operating parameters. Using this scheme, the inventors concurrently obtain two-dimensional amplitude-like and phase-like images with minimal signal processing, which are indicative of the refractive inde distribution and variation in absorption respectively. Tire inventors demonstrate that this coherent detection method enables extraction of the refractive index and absorption coefficient of materials under test. Key to a preferred embodiment of the invention is the implementation of a THz swept-frequency delayed self-homodyning ('self-mixing') scheme that enables phase-sensitive detection of the THz field emitted by a QCL source. As well as phase-stability, the use of a QCL as the THz source affords the benefit of high output power spectral density, several orders of magnitude better spectral resolution than TDS, and the potential for high-speed measurements.

The basic structure and operating principles of a self-mixing interferometer according to a preferred embodiment of the present invention are shown in Fig. la. The re-injected light 14 interferes ('self-mixes') with the mtra-cavity electric field, causing small variations in the fundamental laser parameters including the threshold gain, emitted power, lasing spectrum, and laser terminal voltage. The interferometer includes a laser 3 which may for example, and without limitation, be a Quantum Cascade Laser (QCL), an Interband Cascade Laser (ICL , a Helium Neon laser a Carbon Dioxide laser or an optically pumped fiber laser. As will be understood from the subsequent discussion of preferred embodiments of the invention, other types of laser may also be used provided that they have sufficiently low phase noise.

Whichever particular type of laser is used it includes a gain medium that is sandwiched between two mirrors 4, 6 and which has an exit facet 8 located an external a distance 13 from a target 10. In use the laser emits a first laser beam 12 which is returned to the laser from the target 10 in the form of a second returned beam 14. As the beam interacts with the target .10 (or as it is sometimes referred to herein "the sample") the target imparts phase and amplitude changes due to its material properties. Consequently the second, returned beam 14 has a phase and an amplitude that differs from that of the emitted beam 12. The returned beam 14 interacts vith the emitted beam 12 in the gain medium of the laser 3 thereby causing "self-mixing" which results in measurable variations in tire operating parameters of the laser.

The above explanation emphasizes a ray model of the interaction of the emitted laser beam with the target and Figure 1 A shows the emitted beam 12 and the returned beam 14 displaced a distance d from each other. Those skilled in the ait will realize that this is a convention for explanatory purposes and that the emitted beam and the returned beam are not in fact displaced but rather are collinear and that they produce a standing wave between the target and the laser. Whilst optical feedback affects almost all laser parameters., the two that are most conveniently monitored are the emitted optical powe and the voltage across the laser terminals. Of these, monitoring the laser terminal voltage is preferred as it removes the need for an external terahertz detector. The small voltage variation (referred to as the "self-mixing signal') depends on both the amplitude and phase of the electric field of the reflected laser beam. This configuration thus creates a compact, coherent sensor that can probe information about the complex reflectivity or complex refractive inde of the external target. The homodyne (coherent.) nature of a self-mixing scheme inherently provides very high sensitivity detection, potentially at the quantum noise limit, and therefore a high signal- to-noise ratio can be expected in the self-mixing signal. Furthermore, the maximum speed of response to optical feedback is determined by the frequency of relaxation oscillations in the laser itself. In the case of THz QCLs, the l ifetime of the upper state of the losing transition is limited by elastic and inelastic scattering mechanisms to a few picoseconds enabling response frequencies on. the order of tens of GHz,

The inventors use a three mirror model to describe the laser system under feedback which is equivalent to the steady-state solution to the model proposed by Lang and obayashi. in this model, only one round-trip in the external cavity is considered. The phase shift in the external cavi ty is composed of the transmission phase shift arising from the optical path length as well as the phase change on reflection from the target. The reflectivity of the target together with the phase change on reflection form a complex pair which is equivalent to the complex refractive index of the target.

When the external target is displaced longitudinally, the laser syste is swept through a set of compound cavity resonances. The equivalent effect may be obtained by changing the laser frequency, which is accomplished in a preferred embodiment of the invention by applying a linear modulation of the laser driving current. The primary effect of this current sweep is a modulation of both the emitted laser power and the voltage developed across the laser terminals. The secondar effect, which is of most importance here, is a linear change of the lasing frequency with current (frequency chirp). This approach in essence constitutes a continuous-wave (cw) frequency-modulated system for coherently probing the remote target. During the frequenc sweep, the self-mixing signal is observed as set of periodic perturbations embedded in the modulated voltage signal 22 (see Fig. l b). The temporal separation between the peaks of the self-mixing signal waveform 24, as well as its shape and phase, depends on the length of the external cavity and the complex reflectivity of the target. This is illustrated in Figs. I c and Id which considers one period 27 (identified in Fig, I B) of the self-mixing waveform with the linear ramp 26 removed. Figure ic shows the effect of increasing the real part of the complex refractive index n, leading principally to a narrowing 28 of the wa veform due to stronger feedback. On the other hand, an increase in the imaginary part of the complex refractive inde (extinction coefficient) ' predominately produces a phase shift 30 in the waveform whilst leaving the shape of the waveform unchanged, as shown i Fig. Id. This effect is mainly due to the strong link between k and the phase-shift on reflection.

Thus, through analysis of the shape and phase of the self-mixing waveform, the complex reflectivity of the target may be deduced. The way in which informatio about n and k affects the self-mixing signal is suitably described through the well-known steady-state solution to the Lang and Kobayashi model. In particular, infomiation about the complex refracti ve index of the target enters the Lang and Kobayashi model through the feedback parameter C, the effective external cavity length Z _¾xt , and the phase change on reflection R,

Embodiments of the inventio are equally applicable to extracting values for n and k of a material under test, and for high-contrast imaging of spatial variation in these quantities across a target,

An example of a preferred embodiment of the invention will be described with reference to a custom-designed composite target consisting of an aluminium cylinde 1 inch in diameter with three cylindrical bores containing different plastics, namely polyoxymethylene (POM, also known, as acetal), polyvinyl chloride (PVC) and nylon 6 (PA6, als known as polycapr lactam). A further target containing the plastics polycarbonate (PC), and two samples of high-density polyethylene (HDPE and HDPE Black) has also been characterised,

A. schematic diagram of the experimental apparatus used is shown in Fig. 2e. The THz. QCL 36 (operating at 2.59 THz) consisted of a 1 1 ,ό-μ ^η ι-thick GaAs/AlGaAs bound-to- continuum active-region that was processed into a semi-insulating surface-plasmon ridge waveguide with dimensions 1.78 mm x 140 μηα (see Methods). The QCL was mounted onto the cold finge of a continuous-flow eryostat fitted with a polythene window 38 and operated in cw mode at a heat sink temperature of 15 K. Radiation from the QCL was coUimated using 2 inch diameter, 4 inch focal length off-axis parabolic reflector 40 and focused onto the target using a second identical mirror 42. The total optical path between source and object was 568.2 mm through an ambient (unp urged) atmosphere. In Figures 2C and 2D, the modulation input to the signal generator 62 is labeled as 62b. The Self mixin signal sent to computer 64 is labeled as 66b. The temperature setting that is sent to the temperature controller .58 is labeled as 58b, The optical, magnetic or solid state disk bearing instructions for computer 64 to implement the method according to preferred embodiment of th present invention is labeled as 64b.

The laser 36 was driven by a current source in the form of laser driver 60 at &.· =0.43 A, slightly above the threshold (Ah = 0.4 A), where the sensitivity to optical feedback is at a maximum. A modulating saw-tooth current signal 32, illustrated in Fig. 2a, having a 50 mA peak-to-peak amplitude was superimposed on the dc current. This leads to a linear f equency sweep of 600 MHz. Owing to optical feedback from the material under test, the self-mixing waveform containing information about the target is embedded in the voltag signal 34 (illustrated in Fig. 2b ) that is measured across the laser terminals 61 a and 61b and digitized by ADC 66 for delivery to computer 64 and subsequent processing. For image acquisition, the target sample 46, which is supported by target assembly 45, was raster-scanned in two dimensions using a two-axis computer- controllable translation stage 48 (see Fig. 3a for an image of the front surface of the target 46). The translation stage 48 includes actuators that are responsiv to control signals on line 43 from the computational device in the for of PC 64. Alignment feedback signals are delivered back to the PC 64 from the translation stage 48 on line 45 to assist the PC in accurately positioning the target. Time domain traces were acquired at each of a plurality of positions, namely at each node of a 181 x 181 square grid superimposed on the target with spatial resolution of 100 μπα. For each spatial pixel of the target, the voltage signal was recorded as the average of 128 time-domain traces.

Therefore the complete set of experimental data contains 181 x 181 time-domain waveforms, eac corresponding to one spatial pixel on the target.

Embodiments of the invention encompass at least two processing procedures. First, a range of high-contrast TBz images can be created by processing the self-mixing signals . Second, it is possible to extract absolute values for n and A' for any region on the target, provided precise values of n and k are known at two other positions on the target. IMAGING

To obtain high-contrast THz images, the first step is to take each voltage signal and subtract a reference slope, thereby removing the effect of power modulation of the laser; stronger feedback leads to more pronounced departure of the voltage signal from the reference slope.

The effect of transients present around the edges of the modulation period of the laser is removed by using only the central 80% of each self-mixing trace. Figure 3b shows a two-dimensional representation of the set of time-domain self-mixing signals 74 acquired along the representative horizontal line 70 in Fig. 3a, with die vertical axis showing temporal evolution of the sell-mixing signal and the horizontal axis showin its spatial dependence. The shading quantifies the instantaneous amplitude of the self- mixing signal (reference slope already removed). One should bear in mind that due to the coherent nature of the detection scheme tire signal strength at a particular point in time cannot be simply related to the reflection coefficient of the target; rather, it is the integral of the absolute value of the signal over time that is proportional to the reflectivity of the target. Furtiier, this quantity is indicative of the strength of the self-mixing signal, with stronger feedback yielding a large value. In Fig, 3c, this stronger feedback is spatially represented to an observer by the resulting image 73a of the target having a copper- colour end 72 of the pseudocolor range, corresponding to the aluminium part of the target. Weaker feedback regions, corresponding to plastic insets 68 in the aluminium target, are visible as black circles. Due to the strong reflection from aluminium and similar reflectivity of the three plastics at 2.59 THz, contrast between the three plastic insets is not visually discernible in Fig. 3c. However, it is perfectly preserved in the time domain signal, as can be seen from the exemplar time domain traces 76 plotted in Fig. 3e corresponding to each of the three plastic regions.

The amplitude-like codification of self-mixing signal (Fig. 3c) is exploiting just one part of the information embedded in it. Another ^" possible representation relates to the phase, or equivalentl the temporal position, of the peaks of the self-mixing signal relative to the edge of the modulating sawtooth signal. Different materials impose different phase- shifts on the incident THz wave according to their comple refractive index, dominated by its imaginary part. This phase-like representation of the effect of the target on the self- mixing signal is shown in the image 73b of the target that is presented in Fig. 3d. Whilst visually this does not show the obvious contrast of the amplitude-like representation, it is interesting to note that these two pieces of information can be likened to the change in the magnitude and the. phase of the complex reflectivity, respectively. These two reductions of the information contained in the self-mixing signal are by no means the only ones possible. For instance, by fitting these time-domain traces to the steady-state solution of the Lang and obayashi model, one obtains images through plotting the spatial variations in feedback parameter C.

Materials Analysis: While the signal, processing for creating images in Fig. 3(c,d) is quite straight forward,the procedure for extracting optical constants of materials under test requires multiple steps, including fitting. As discussed earlier, the target used in this study contains three plastic materials 68 embedded in an aluminium holder 72 (Fig. 3a). For this procedure, it is assumed that the complex refractive indices of two of these materials are known in order to determine the third. To establish the self-consistency of the scheme, this approach is adopted for each of the three materials in turn. In order to exclude the effects of the boundary between the materials and the aluminium holder measurements are nsed from inside the circles superimposed on the photograph in Fig. 3a to determine the complex refractive inde of each material under test. Referring to Fig. la, the total phase delay in the external cavity 13 ca be decomposed into the transmission phase delay arising from the round-trip 15 through the cavity and the phase change on reflection from the target, which is material dependent. The second order effect of the linear current sweep is a linear chirp of the lasing frequency (600 MHz), leading t a linear dependence of transmission phase with time. Therefore the external phase delay (interferometric phase) φ over one frequency modulation period T as a function of time is of the form

<p(t) φο + ί - θΒ (1 ) where<¾(½ i the round-trip transmission phase delay in the external cavity at the start of the frequencysweep ₅ <i½ is the interferometric phase deviation caused by the current (frequency) sweep,and 0 _R is the phase change on reflection from the material under test. Clearly,^) is a function ofthe instantaneous laser frequency, which depends on the level of feedback in the laser system. According to the Lang and Kohayashi model for a semiconductor laser under optical feedback in a steady state the laser frequency satisfies the phase condition (sometimes called the excess phase equation) (p _s — <p _FB = Csm ^' (q) _FB + arctan (2)

where <p _FB represents the total external round-trip phase at the perturbed laser frequency, <¾ represents the total external round-trip phase at the ^■ solitary laser frequency, C is the feedback parameter that depends on the amount of light reflected back into the laser cavity, mda is the line width enhancement factor. Solutions to equation (2) are not possible in closed form and therefore require numerical solution. The tnterferometric phase change is directl observable through the change in emitted optical power, or equivalently through the change i voltage across the laser tenninals.as i used in the presently described preferred embodiment of the invention. The self-mixing signal embedded in the modulated voltage signal is related to the phase change through

V == V ₀ + β cosi _FB ) (3) where Vis the voltage waveform obtained after the removal of the common slope, Vo is a dc component of this signal (corresponding to a material-dependent voltage offset from the reference slope), and β is the modulation index. Note that, for the modulation scheme used here, V is a function of time through its dependence on the interferometric phase

ΨΡΒ ·

Thus a parametric model is obtained, based directly on the steady state solution to the Lang and obayashi model, that describes well the set of experimentally acquired time domain traces. Equations (i)-(3) form a model with six key parameters, namely C, , 9 _R , Φ _Δ , Foand β .The information about the comple refractive index to be extracted is encoded mainly in C, a, and B _R . To extract these parameters, fit the model to data in the least-squares sense, for each spatial pixel of the target. This provides a set of parameter values for each pixel inside the coloured circles in Fig. 3a.

If n and A' of two of the materials are known, it is then possible to exploit their relationship to the parametric model and thereby derive n and k of the third material (the material under test— see Methods). esults for six materials under test obtained from two different targets are tabulated in Table 1 and compaied against reference values from the literature.

Estimated n Reference n Estimate oe k

FGM 1.66 1.66 0,011 0.012

PVC 1.66 1,68 0.063 0.062

PAS 1.80 .67 0.11 0.1 1

PC 1.62 1.62 0.011 011 1

HOPE B c 158 1.58 0.01 § 11018

HOPE 154 1.54 0.0022 0,0020

Table 1: Results for six materials under test obtained from two different targets compared against reference values from the literature. In summary, a preferred embodiment of the present invention provides a feedback interferometric approach to the optical analysis of materials at THz frequencies. Using this simple, robust approach, both intensity- and phase-like images of materials are acquired concurrently. This technique enables the user to interrogate regions of the target and extract precise values for refractive index and absorption coefficient within these defined areas. Such characterisation of the optical properties of substances at THz frequencies enhance the identification and discrimination in the materials science. METHODS

Laser Fabrication and Operation: The TFiz QCL heterostructure was based on a GaAs/AlGaAsbound-to-continuuiri active region design operating at 2.59 THz. The wafer was grow on a semi -insulating GaAs substrate by molecular beam epitaxy, with an active region thickness of 1 1.6 pm,consisting of 90 repetitions of the gain medium. The active region stack was sandwiched between doped upper 80-nm-thick. = 5 x 10 ^s cm ^"3 ) and lower 700-nm-thick (n = 2 x 1Q ¹⁸ cm ^"3 ) GaAs contact layers. The wafer was processed into a surface plasmon ridge waveguide using optical lithography and wet chemical etching with confinement of the waveguide mode being ensured by the lower doped layer. Optical lithography was used for defining ohmic contacts, the thicknesses of the Au Ge/Ni bottom and top contacts being 200 nm and 100 nm, respectively. The thickness of the Ti/Au overlayer was 20 nra/200 nm and the substrate was thinned to a thickness of -200 μηι.Α 140 pm ridge width was used and the cleaved device facets were left uncoated.

The device was mounted on a copper bar using indium foil to provide thermal contact, and was then wire bonded. In all experiments, the laser was operated using a constant current source at Lie - 0.43 A. A modulating saw-tooth current signal (50 mA peak-to- peak ampiitude)was superimposed on the dc current, leading to a linear sweep of the lasing frequency of 600 MHz.

System and Measurement Calibration: The refractive index n and the extinction coefficient k of the target directly affect the self-mixing voltage in our model through the phase-shift on reflection^. Moreover, the reflectance of the target i? is directly linked to the model parameters C md athrough the definition of the feedback parameter C, kno wn in the literature as: c

ν'β o (4)

To account for external reflections other tha that from the target (including reflections from theeryostat shield and the window), v¾s written as

(5) whereVi?' ⁴ is the actual reflectance of the material unde test, a ₈ and b _s are unknown parameters to be determined. is representative of the material's

measured, but unea! ibrated reflectance.

Along similar lines, to account for systematic phase changes, 9 _R te expressed as eg = a _e + b _e e$ (6) where£?j _¾ is the actual phase shift on reflection, < and bgam unknown parameters to be determined,and B is representative of the i calibrated phase shift on reflection.

Equations (5) and (6) contain four unknown parameters, i½, b _R , cig and b , which can be determined fr m two measurements on materials with known ( //? ^Λ , θ$ } values, which can be viewed as a set of four linear equations with four unknowns. Denoting the calibration pairs of measured and actual refiectances and phase-shifts for the two standards as (ft , R( _jt ) and (R , respectively, the set of our linear equations are

^βξ = a _R + ^fkl (7b)

¾ (7c)

¾ ₂ - + ¾ ₂ (7d) The solution of this system of equations is straightforward and provides values for a _R , b _R , a _$ and b _$ . Once these values have been obtained using (5) and (6) actual values for B _R aid # ^Λ for the material under test can be readily calculated. The relationship between (A ³ , f¾') and (n, k) is given through the pair of relations l+:ff -2V¾OS (#R )

This procedure is applied to the three materials embedded in the target (see Fig. 3a). Values from the literature for optical constants for two of the materials were used, treating them as standards in this procedure to obtain values for the unknowns a _R , b _R , i¾ and b _e .

USE FOR THE INVENTION

An example of the use of a preferred embodiment of the mvention will now be provided with reference to Figure 2C. It will be realised that the steps outlined below may also be applied in an entirel analogous manner to the transmission sample setup of Figure 2D.

1.Setting up sample

a. Put prepared sample 46, i.e. the target, to be imaged½ialyse in sample holder on the 3-axis motorised stage 48.

b. Adjust position (tilt and X.YZ) using the CCD camera 50 to align sample surface to the focal plane of the THz beam 52.

2. Preparing THz QCL for operation

a. Connect vacuum pump to cryostat 54.

b. Evacuate vacuum chamber of cryostat (using vacuum pump). c. Disconnect vacuum pump.

d. Insert cryogen transfer line into the Dewar 56 and cryostat allowing cryogen to flow into cryostat and begin cooling the laser. e. Turn on temperature controller 58 and adjust the set poi t to 15K (optimal operating temperature for this particular THz QCL),

f Wait until cryostat is stable at 15 .

g. Turn on Laser driver 60 at DC current bias (typically 0.43 A (again for this particular THz QCL)).

h. Setup signal generator 62 to generate a modulating sawtooth wave (typical 1 V at 1 KHz) and feed into the laser driver (1 V modulation input = 50mA output to laser. (So laser drive current is 0.43 to 0,48 A in a ramp))

i. Enable output of signal generator. j. Wait for laser temperature to stabilise.

k. The T z QCL is now ready and emitting the measurement beamure Target

a. Setup XY raster scan of target area (Χ-Ύ translation (typ- 18 mm x 18 mm), step size (typ. 100 μηι) controlled via computer 64) to scan through a plurality of positions. Initial position is centre point of scan. b. Start Scan

i. Motorised stage moves to a pixel position

ii. Take several measurements (via the ADC 66) of the terminal voltage of the THz QCL (typical 128 Averages, of K of samples at IM sampler's).

iii. Save average sample to tlie workstation.

iv. Translate sample to next imaging pixel & repeat (i-iti).

c. When scan finished move back to the starting positio (centre of scanned area).

down measurement

a. Turn off Laser driver and signal generator.

b. Shut off cryogen flow and remove cryogen transfer line from the cryostat. e. Turn off temperature controller.

ssing Data

a. Waveforms are processed usin the workstation.

b. Prepare waveforms for fitting

i. Remove the power ramp (average ramp of signals)

ii. Trim ends (-100 data points) to avoid edge transients.

iii. Optionally adjust for known tilt of the sample surface.

c. For each spatial pixel, fit excess phase SM model to data (typically in least-squares sense) and extract ^(amplitude reflectivity proxy) & 0jf (phase proxy) as functions of fitted SM model parameters.

d. Images showing the relative change in (for example) reflectivity proxy, phase proxy, or SM model parameters across the surface of the target can then be produced.

e. For absolute parameter extraction i. At least two known materials have been scanned (at the same time) in addition to the. unknown sample.

ii. All material samples He on the same known surface (typically a plane).

hi. System error coefficients are calibrated based on measured and known pairs.

iv. Materia! parameters of the unknown sample can then be estimated using measured values and known system error coefficients. POTENTIAL APPLICATIONS FOR THE INVENTION

Detection of skin malignancy in vim -

Work using time domain spectroscopy based imaging of skin tissue samples has shown the ability to discriminate basal cell carcinoma (BCC) from surrounding healthy tissue. In a series of 15 excised cases, THz contrast always exceeded visible contrast upon which the conventional imaging diagnosis is made. Clearly, the molecular composition of cancerous tissue will differ, giving rise to differing vibrational modes within the THz range, and thereby a contrast in complex permittivity. The orientation of micro-structure (i.e. fiber orientation, cellular arrangement) is also perturbed in tumour tissue, which can be detected through measurement of the interaction of T Hz irradiation. The exact nature of these responses of various cancer types to THz interrogation are of value as the basis for discrimination tools for non-invasive in-vivo THz imaging of human skin.

Discrimination of disease states i biological specimens and tissue biopsy samples using THz based image contrast and spectroscopic data is also possible using the techniques described herein. Prepared specimens of fluids, or solid tissue can be interrogated for differences in THz characteristics based on the complex permittivity information gained. Changes in the chemical constitution and structural changes associated with acquired disease will be the primary- sources of discrimination between normal and pathological specimens. The differences observed may not necessarily be present when examined at frequencies outside the THz band. This application will however require ex vivo specimens in contrast to the above application, which is aimed at in vivo diagnosis. Pharma _. centicals

Analysis and mon itoring of pharmaceutical materials in production processes is possible using the techniques described herein. The characterisation and control of all possible polymorphic forms of pharmaceutical, ingredients (e.g. i tablet formulations) is a key factor in the pharmaceutical industry. Experiments have demonstrated that THz spectroscopic techniques can distinguish between different, polymorphic forms of pharmaceutical solids (for example carbamazepine, enalaprii maleate, suliathiazole amongst, others), by virtue of structural differences (and hence differences in the intermoleculaf vibrations) in these polymorphs. Thus, preparedpharmaceutical samples can be interrogated for differences in THz characteristics based on the complex permittivity information gained. This application has the potential for production -line monitoring, including monitoring through capsules. Alternative techniques for monitoring such structural differences, such as X-ray powder diffraction, are considerably slower. Furthermore, near- and mid-infrared spectroscopies are generally less sensitive to polymorphic changes.

Embodiments of the invention may be used to detect explosives (e.g. RDX, PETN, TNT, HMX), weapons and the like and so may assist in postal and packaging inspections.

Detection/sensing of crystalline explosives (for example RDX, PETN, TNT, HMX) and illicit drugs (for example cocaine, methamphetamine, heroin) is possible using the techniques described herein. Experiments have demonstrated that such materials can be readily identified using THz spectroscopic techniques. Thus, prepared explosive/drug samples can be interrogated for differences in THz characteristics based on the complex permittivity information gaine&THz radiation also penetrates many packaging materials, enabling identification of concealed illicit compounds (for example in postal inspection). in compliance, with the statute, the invention has been described in language more or less specific to structural or methodical features. The term "comprises" and its variations, such as "comprising" and "comprised of is used throughout in an inclusive sense and not to the exclusion of any additional features, it is to be understood that the invention is not limited to specific features shown or described since the means herein described compri ses preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms Or modifications within the proper scope of the appended claims appropriately interpreted by those skilled in the art.

Throughout the specification and claims (if present), unless the context requires otherwise, the term ' ^' substantially" or "about" will be understood to not be limited to the value for the range qualified by the terms.

Any embodiment of the invention is meant to be illustxative only and is not meant to be limiting to the invention. Therefore, it should be appreciated that various other changes and modifications can be made to any embodiment described without departing from the spirit and scope of the invention.

Features, integers, characteristics, compounds, chemical moieties or groups described in conjunction with a particular aspect, embodiment or example of the invention are to be understood to be applicable to any other aspect, embodiment or example described herein unless incompatible therewith.