太赫兹技术的分子光谱表征TERAHERTZ INSTRUMENTATIONTerahertz technology enables systems for molecular characterization英文版.pdf

1、 TERAHERTZ INSTRUMENTATION:Terahertz technology enables systems for molecular characterization Smart terahertz scanning reflectometer and spectrometer systems exploit the ability of terahertz radiation to penetrate nonmetallic objects and sense the vibrational,rotational,and translational motions of

2、 molecules.ANIS RAHMAN and AUNIK K.RAHMAN Close In addition to its nonionizing nature and its ability to penetrate nonmetallic objects,terahertz radiation is sensitive to the motions(vibrational,rotational,torsional,and translational)of molecules,allowing high-sensitivity spectral probing of molecul

3、ar events in areas of practical importance.Applied Research&Photonics has leveraged these attributes to utilize broadband(approximately 30 THz),high-power(5 mW)continuous-wave(CW)terahertz radiation generated from an electro-optic dendrimer that enables smart spectrometer and scanning reflectometer

4、systems for molecular characterization.Electro-optic terahertz generation The electro-optic(EO)method of terahertz generation is advantageous because the pump-terahertz conversion is not limited either by emission saturation or heat dissipation.The EO route main mechanisms include EO rectification(E

5、OR)and difference frequency generation(DFG).Of these,EOR depends on the introduction of an ultrafast(femtosecond)laser pulse into the lattice of an electro-optically active material;the lattice acts as a rectifier to convert the very high frequency derived from the ultrafast laser pump to a relative

6、ly lower frequency pulse that falls in the terahertz rangethe so-called EOR effect.The EOR method usually uses an 800 nm pulsed femtosecond laser,although other wavelengths such as 1064 nm may be used.The difficulty here is that two vital parametersoutput power and the terahertz rangeare completely

7、dependent on the characteristics of the femtosecond laser.As a result,only low average power and a range of several terahertz(up to 5 THz)has been possible,making it difficult to uniquely characterize many materials systems.In contrast,the DFG techniques not only eliminates the use of an expensive f

8、emtosecond laser,but can also produce both CW and pulsed terahertz radiation,as well as higher output power and broad-range tunability.Nobel Laureate Robert F.Curl,Jr.and colleagues reported generation of tunable far-infrared(IR)radiation by means of two singlemode laser diodes by focusing the overl

9、apped beam in silver gallium sulfide(AgGaS2)crystal.1 Our earlier work showed that chromophore-doped and-poled poly(amido amine)dendrimer can produce approximately 3.4 mW of terahertz power(PTHz)when pumped by two fiber-coupled laser diodes with a combined pump power of around 5.5 W(Ppump).2 Thus th

10、e terahertz figure of merit PTHz/(Ppump)2 of this source is 1.124 10-4 W-1.This value was achieved by means of the higher EO coefficient of the EO dendrimer:130 pm/V.Using DFG,the resulting terahertz frequencies are given by the difference of the pump laser frequencies,or THz is proportional to 1-2,

11、meaning one can choose appropriate pump frequencies to obtain the desired output terahertz bandwidth.In practice,however,both 1 and 2 are not single-frequency lasers because laser diodes always have a bandwidth distribution around their main peaks;that is,when a stationary beam of the generated tera

12、hertz radiation is scanned by a moving beam derived from the same source,a wide frequency distribution will result.This mechanism is a variation of two-photon excitation.3 The terahertz scanning reflectometer Measurement of the concentration gradient of a biological or other fluid in a noninvasive(a

13、nd nondestructive)fashion is important in several areas,including penetration of an active ingredient through human skin or other tissues.But to our knowledge,there was no direct methoduntil nowto obtain two critical factors in such studies:1)the concentration gradient of the permeating ingredient a

14、cross the thickness of a substrate and 2)the kinetics(or rate)of such permeation.These two factors are essential for quantitative analysis,for example,via Ficks laws of diffusion.4 In one dimension,Ficks first law relates the flux,J,directly to the concentration gradient via J=-D(C/x),where C is the

15、 concentration and D is the diffusion coefficient.Ficks second law relates the kinetics of diffusion with the second derivative of concentration gradient or C/t=D(2C/x2).Therefore,direct measurements of the quantities C/x and C/t are possible.Our terahertz scanning reflectometer(TSR)is therefore cap

16、able of measuring both the concentration gradient and the kinetics of diffusion in real time,enabling life science and physical science advances in cell characterization,transdermal drug delivery,personal care products,and substrate/active ingredient characterizations where the effect of an active s

17、ubstance on a substrate is important.For our TSR,CW terahertz radiation is generated from an electro-optic dendrimer via the DFG method(see Fig.1).The terahertz beam is focused onto the specimen at a 90 angle using an off-axis parabolic reflector(normal incidence).The beam reflected by the substrate

18、 is directed to the detection system using a beamsplitter/combiner and the specimen cell is comprised of a scanning platform that is controlled by a one-dimension motion FIGURE 1.An experimental setup shows the terahertz scanning reflectometer.A fine-pitch,one-dimensional motion control system is us

19、ed to move the substrate(sample holder)in and out of the focal point while the detection system acquires data in real time.For kinetics measurements,the specimen is kept fixed and focused.To make a direct measurement,the off-axis parabolic reflector is adjusted such that(initially)the terahertz beam

20、 remains focused on the substrate surface.At this position,the motion controller is engaged to scan the substrate and interrogate the reflectance across its thickness;this gives the C/x parameter when the blank substrate reflectance is subtracted from the reflectance of the same substrate treated wi

21、th a desired ingredient.However,when the beam remains focused at the surface and the motion control is locked at that position,then the ingredient is applied on the substrate to let it permeate across the thickness while the reflectance is measured in real time.In this case the reflectance is direct

22、ly proportional to the rate of permeation of the ingredient across the substrate,or C/t.Terahertz scanning reflectometer measurements of the stratum corneumthe outermost layer of the skins epidermiswere characterized to obtain the permeation parameters for N-0915,a chemical known as a permeation ret

23、arder(see Fig.2).First,the reflectance is measured for a blank stratum corneum and then,for the stratum corneum treated with N-0915.The difference of the two profiles determines the gradient C/x and thus is a direct measurement of the concentration FIGURE 2.Concentration gradient C/x(triangles)is ob

24、tained for an ingredient(N-0915)across the stratum corneum,calculated from the difference between the blank stratum corneum measurement(diamonds)and the same stratum corneum treated with N-0915(squares).(Skin sample courtesy of Dr.Bozena Michniak-Kohn of Rutgers University)We also measured the diffu

25、sion kinetics of water into photographic paper.The paper was mounted on the reflectometer and 25 L of deionized water were dispensed(see Fig.3).Here,the kinetics of penetration was measured in real time.The time-dependent change of reflectance is assumed to be a direct measure of the penetration kin

26、etics,thus quantifying C/t.Knowing both C/t and C/x,the diffusion coefficient can be calculated directly from Ficks second law.All measurements are controlled from the front-end user interface with a Windows-based personal computer.FIGURE 3.A terahertz scanning reflectometer measures the kinetics of

27、 penetration of deionized water into a photographic paper substrate(a).Using the same technique,water applied to the top surface of two separate paper substrates shows the clear demarcation between the two layers in the permeation graph(b).Terahertz spectroscopy In common techniques such as Raman or

28、 IR spectroscopy,a sample is illuminated with a laser beam and the light is collected by a lens and passed through a monochromator.Wavelengths close to the laser line,due to elastic Rayleigh scattering,are filtered out while the rest of the collected light is dispersed onto a detector.Modern Raman i

29、nstruments use notch or edge filters for laser rejection and spectrographseither axial transmissive(AT),Czerny-Turner(CT)monochromator,or Fourier transform(FT)spectroscopy basedand CCD detectors.But because spontaneous Raman scattering is typically very weak,it is difficult to resolve the weak,inela

30、stically scattered light from the intense Rayleigh-scattered laser light.This fundamental limitation of Raman spectroscopy makes it difficult to resolve many molecules,especially those with closely spaced spectral lines.When terahertz radiation interacts with molecules,it may stimulate many resonanc

31、es such as molecular vibrations,phonons,and/or other resonances in the system,affecting the terahertz photons by characteristic amounts based on a specific interaction or event.The change in energy and/or frequency yields information about the molecular nature of the interaction.While IR and Raman s

32、pectroscopy yield similar information,they cannot detect as many resonant states as can terahertz spectrometers because terahertz photons are sensitive to the vibrational states of the entire molecule as opposed to just a bond or charge state.Molecular simulation,especially molecular dynamics,reveal

33、s the numerous vibrational and conformational states possible when a molecule is not at its lowest energy state.Because most material remains at its lowest energy state under normal and steady state conditions,terahertz perturbation will stimulate possible available states in these regions.For examp

34、le,terahertz spectroscopy can be used to analyze the single nucleotide polymorphism(SNP)of two single-stranded DNA molecules;SNP is a DNA sequence variation that occurs when a single nucleotide(A,T,C,or G)in the genome differs between members of a biological species or paired chromosomes in an indiv

35、idual(see Fig.4).FIGURE 4.A terahertz spectrometry system measures two single-stranded DNA molecules(spectra A and spectra B).The absorbance spectra exhibit clear differences when thymine(T)is substituted by guanine(G),as shown by the A+C and B+C hybridized state spectra.Characteristic spectral peak

36、s allow distinguishing between the hybridization states without The detection of SNP has major implications in diagnostics and personalized medicine:It has been discovered that if ones gene has one kind of SNP then certain drugs will be effective,whereas the lack of that SNP type means that the same

37、 drug will not work.If a doctor is able to easily identify the presence or absence of a given SNP in ones gene,then they can prescribe the right drug.Scientific studies reveal that DNA always goes through a process of switching between single-and double-stranded modes to create new proteins or to in

38、teract with enzymes/other proteins.The terahertz spectrometer is so sensitive,it can discern between single-stranded DNA and double-stranded(hybridized)DNA,making the instrument crucial to a number of biological studies.REFERENCES 1.U.Simon et al.,Opt.Lett.,18,13,1062(1993).2.A.Rahman,“Stimulated em

39、ission of terahertz radiation from electro-optic Dendrimer,”Proc.SPIE 7601:Terahertz Technol.and Applications III,San Francisco,CA,76010C(Feb.18,2010).3.A.Rahman,“Dendrimer Based Terahertz Time-Domain Spectroscopy and Applications in Molecular Characterization,”J.Molecular Structure,1006,5965(2011).

40、4.E.De la Barrera,Nat.Structural&Molecular Bio.,12,280(2005).Anis Rahman is CEO and CTO and Aunik K.Rahman is a senior engineer at Applied Research&Photonics(ARP),470 Friendship Rd.,Ste.10,Harrisburg,PA 17111;e-mail:;.More Laser Focus World Current Issue Articles More Laser Focus World Archives Issue Articles