Noise minimised high resolution digital holographic microscopy applied to surface topography Текст научной статьи по специальности «Физика»

NOISE MINIMIZED HIGH RESOLUTION DIGITAL HOLOGRAPHIC MICROSCOPY APPLIED TO SURFACE TOPOGRAPHY

E. Achimova1, V. Abaskin1, D. Claus2, G. Pedrini2,1. Shevkunov3'4, V. Katkovnik 4 1Institute of Applied Physics, the Academy of Sciences of Moldova, Chisinau, Moldova, 2Institut fur Technische Optik, the University of Stuttgart, Stuttgart, Germany, 3St. Petersburg State University, St. Petersburg, Russia, 4Department of Signal Processing, Technology University of Tampere, Tampere, Finland

Abstract

The topography of surface relief gratings was studied by digital holographic microscopy. The applicability of the method for quantitative measurements of surface microstructure at nanoscale was demonstrated. The method for wavefront reconstruction of surface relief from a digital hologram recorded in off-axis configuration was also applied. The main feature is noise filtration due to the presence of noise in the recorded intensity distribution and the use of all orders of the hologram. Reconstruction results proved a better effectiveness of our approach for topography studying of relief grating patterned on a ChG As2S3 - Se nanomultilayers in comparison with standard Fourier Transform and Atom Force Microscope methods.

Keywords: digital holography; digital image processing; diffraction gratings.

Citation: Achimova E, Abaskin V, Claus D, Pedrini G, Shevkunov I, Katkovnik V. Noise minimized high resolution digital holographic microscopy applied to surface topography. Computer Optics 2018; 42(2): 267-272. DOI: 10.18287/2412-6179-2018-42-2-267-272.

Acknowledgments: We express our gratitude to the Materials for Photovoltaic and Photonics Laboratory of the Institute of Applied Physics of the Academy of Sciences of Moldova for the samples preparing. Funding of work: the H2020-TWINN-2015 HOLO-project (687328); the Academy of Finland project 287150, 2015-2019.

Introduction

Diffractive optical elements (DOE) are indispensable in a variety of optical applications, including measurement instruments and imaging devices. Advanced nanotechnol-ogies and nanophysics use chalcogenide glasses (ChG) as basic components in the engineering of DOE [1]. Optical properties of ChG films, such as absorption coefficient and refractive index, can be changed by light or e-beam exposure. The direct formation of micro and nano-relief on the ChG surface under the polarized coherent radiation is a phenomenon, both of applied and scientific importance [2, 3]. From the application point of view, the phenomenon is useful for the production of a variety of high-performance DOE without any additional/wet development and its scientific significance lies in discovering a new feature interaction of light and the ChG.

The topography of surface relief gratings (SRG) is the main feature determining the success of SRG application. The optical quality of the relief surface is very important for designing DOE by recording, printing or master hologram realizing. However, sometimes it is possible to perform direct thermal printing on polymer film from DOE of a large number of copies without master [4]. Finding the methods appropriate for the study of each unit of DOE topography is a priority task.

Due to the high resolution required, the profile and surface of SRG are conventionally measured via Atom Force Microscopy (AFM) or Scanning Electron Microscopy (SEM) [5, 6]. Each of the above methods has advantages and disadvantages. AFM is a precision technology giving detailed images of the sample's surface, but it is to be pointed out that the field of view in AFM is restricted, which allows one to view only a limited part of the surface. In addition, due to the nature of AFM tip, the topography

of sinusoid-like surface structure cannot be measured exactly, which leads to the appearance of the artefacts distorting the surface presentation. To create a SEM image, the incident electron beam is scanned line by line in a raster pattern across the sample surface. The SEM method requires an electrode deposited on the surface that would irreversibly change the transmission or damage the surface profile of the lithographically manufactured DOE. In case of e-beam sensitive medium, the electron irradiation can greatly influence the DOE recording. AFM and SEM are time consuming scanning methods, requiring expensive equipment and complicated software.

Digital holographic microscopy (DHM) is a non-contact full-field technique, which can partially eliminate the negative effects of other methods. DHM is a powerful interference technique having several features that make it an interesting alternative to conventional microscopy. It is worth mentioning that conventional microscopy can easily generate two dimensional images of a sample surface but cannot measure the vertical dimension (profile) of the sample. The main characteristic of DHM is the capability to retrieve amplitude and phase information of a wavefront reflected/transmitted by a microscopic object. DHM can be used for the measurement of 3D microstructure, moreover it has also been applied in many fields including topography examination, morphological monitoring of biology objects, particle studying, etc. [7]. The phase information allows one to make the surface topography measurements with nano-meter vertical resolution [8]. Deformations can be measured by evaluating the changes between the phases recorded at two states of the sample [9]. Based on the double exposure principle, phase aberrations, which may emerge in a single off-axis holographic reconstruction, can be compensated, as discussed in [10].

Theory and experimental setup

In this paper we use DHM together with the noise suppression iterative sparse technique for the 3D high accuracy reconstruction of SRG pattern on a ChG As2S3 -Se nanomultilayers (NML). We are concentrated on the image-plane holography because it better demonstrates the advantages of the sparse modelling of the wavefront than the other holographic methods.

ChG As2S3 - Se NML was produced by a computer controlled cyclic thermal vacuum deposition through the mask [11]. The technology enables film deposition control within the whole sample thicknesses in the range from 0.005 |im to 3.0 |im. Thermal depositions occur at rather low temperatures (400-600°C). Rotating the sample over a heater of the condensed zones decreases the local sample temperature and prevents interlayer diffusion in NML. Otherwise the deposited nanolayers turn into monolayer. The NML sample contains alternating As2S3 nanolayers with the thickness of 15 nm and Se nanolayers with the thickness of 10 nm. The total number of the nanolayers was 200, the thickness modulation period of the pair As2S3 - Se layers was about 25 nm. The last-mentioned parameter is critical in the recording process for obtaining high quality surface relief.

When a laser beam with photon energy equal or above the band gap energy irradiates the ChG thin film, a strong interaction of the light with the material takes place. Due to the photosensitivity of the ChG different pho-to/thermo-induced structural transformations occur under laser irradiation. The induced structural transformations depend on: the material properties, wavelength, intensity, and polarization of the laser beam. At relatively low intensity levels (hundreds of mW per cm2) predominantly photoinduced phenomena, such as photo-polymerization, photo-viscosity, etc. take place [2]. An interferometric procedure for producing a step grating relief the SRG on the As2S3 - Se NML has been described [12], where a CW laser with wavelength X = 532 nm and average spot power density on the sample from 150 to 350 mW/cm2 have been used for recording. The holographic surface gratings with a period of A = 1|im were recorded by two cross-polarized (± 45°) laser beams with respect to the fringe of the grating. AFM measurements of the sample surface after recording show that the depth of grooves is about 120 nm.

An off-axis DHM bright-field configuration in transmission mode has been employed for the measurement of the SRG topography. The approach to recover the complex amplitude distribution transmitted by the sample includes: a method to filter the twin image and the zero diffraction order, a numerical reference calculation, and a numerical reconstruction of sample's image [13].

The DHM setup is shown in Fig. 1. In order to obtain an environmentally robust and compact setup the laser beam was coupled in a monomode Y-coupler. The spot diameter on the sample was adjusted by the fiber/sample distance. An oil immersion objective with magnification 100x and NA = 1.25 has been used. The oil was introduced between the cover slip (0.13 mm thickness) and the

first objective lens. The first diffraction order of the SRG (39°) was accepted by the aperture angle (55°) of the objective. The CCD sensor was located at the distance of 195 mm from the objective for minimum aberrations in the image. The light source had a wavelength X = 633 nm and thus the resolution of DHM was about 506 nm (the smallest resolvable object detail). The camera resolution was 2592x1944 pixel with pixel size 2.2x2.2 |im. The period of the SRG was A = 1^m, it was twice as large as the resolution limit.

Fig. 1. Setup of the DHM: 1- He-Ne laser (X = 0,633 ¡m, power = 10 mW), 2 - single-mode fiber launch device, 3 - 2x2 polarization-maintaining single-mode fiber optic coupler, 4,

5 -object and reference beams, 6 - sample with surface diffraction grating, 7 - coverslip (n = 1,51), 8 - immersion

liquid (n = 1,51), 9 - immersion microscope objective, 10 - mirror and 11 - CCD-camera. I, II show two positions of object illuminations beams, namely, I - throughout the grating on NML and II - throughout the NML

The topography of the SRG was determined by comparing the phases obtained from the reconstructions of a reference object and the sample [13]. In our experiment, the holograms recorded from parts of the NML sample not exposed and with surface grating, were used as reference and the object holograms, respectively. The phases of the two reconstructions were subtracted to obtain the phase map A^(x, y) which by knowing the wavelength X and the refraction index n can be converted into the topography:

A9 (x, y)

r (xy ) = M^T)1.

(1)

The considered optical setup is clear from Fig. 1. Here the microscope objective (9) projects the object on the CCD-plane (11). In this way we arrive to the so-called image-plane holography, where the object image is reconstructed at the sensor plane.

The light emitted by a laser is split into two beams by a beam splitter: one beam is directed towards the surface of an object under study; the other beam is directed towards a mirror which introduces a controllable phase shift. The intensity of the sum of these two beams (hologram) is then measured by a sensor array. The complex-valued wavefront at the sensor plane is given by

= B>exP (j%)+A exp (jqr),

(2)

where uo = B0exp(j^0) and ur = Arexp(j^r) are the object and reference wavefronts, respectively. For the off-axis

u

scenario and the spherical reference wavefront the reference phase is defined in the form

9r = 2%jl (V X2 + Jo2 + R +

y - yo )2 +(x - Xo)

(3)

0/ - R 2 ,

where xo and yo are variables dependent on angles of the reference beam with respect to the optical axis z, (x; y) are coordinates in the sensor plane, R is a curvature radius of the spherical wave, and X is the wavelength.

The beam intensity of this beam (hologram) is defined as

(4)

I = |fi0 exp (jy0) + Ar exp (jqr )| =

= B2 + A^ + 2Bo Ar cos (9o - ).

It is assumed in the image processing that the measurements are noisy and given as

Y = I + oe, (5)

where o is the standard deviation of the noise and e is the standard i.i.d. zero-mean Gaussian noise, e ~N(0; 1). Gaussian noise sources in digital holography arise during hologram acquisition process mainly due to camera noises.

Two methods have been used for data processing and the profile reconstruction. The first conventional one is based on the Fourier Transform (FT) [14]. In this method the first order items of FT corresponding to BoArexp(j(<$o-9r)) is extracted. After the inverse FT of this item the phase (^o-^r) is calculated and the object phase is reconstructed provided known the reference phase This estimate of is FT filtered, and in this way one arrives to the final estimate. Thus, FT filtering reconstructs the object phase and additionally suppresses the noise.

As alternative technique we use the variational approach originated from [15]. Following [15] we introduce auxiliary variables: U = IBol2+IArl2 and Z = uoAr. The key point of this replacement is that the intensity I, originally quadratic with respect to the amplitudes Bo and Ar becomes linear function on the new variables U and Z. Then I can be rewritten as

i = u + (v * + z v),

(6)

where V = exp(j^r) and then uo=Z/Ar.The idea of this approach is to optimize the lost function minimizing the deviation of the estimate from the measurements. The technique is based on the assumption that the variables Bo, Ar are invariant in a small neighborhood Xm of each m - th pixel of the observations and the criterion is of the least square form

= I w(q)[y(q)-1 ].

(7)

qeXm

Where w(q), 'Lqexmw(q) = 1, is a weight function applied to the variables in the neighborhood of Xm.

Contrary to the FT method the above variational approach allows one to use full power of the hologram (in Fourier domain it means the use of all orders of the hologram). That is the principal advantage of the variational approach potentially guaranteeing a better accuracy and a better resolution of imaging. The criterion (7) is highly

nonlinear with respect to unknown quantities Bo, 9o, Ar, but with introduced auxiliary variables V and Z, the varia-tional problem becomes much simpler [16].

Further development of that technique was produced in the recent paper [18]. The key idea of the new algorithm is the application of the sparse approximation technique [17] for modelling the object amplitude and phase as functions of the coordinates. The sparsity hypothesis assumes the existence of such functions. Moreover, both the phase and amplitude can be approximated by a series of a small number of those functions. This compact approximation enables good noise suppression and the robustness of the estimates with resecting various disturbances.

The details of this iterative algorithm referred as Sparse Phase and Amplitude Reconstruction (SPAR) can be seen in [18]. In this paper a number of modifications have been made in the algorithm in according with features of experiment and sample under investigation. First, a spherical reference wavefront as well as a plane one are incorporated in (7) contrary to the linear wavefront which is only exploited in [18]. Second, the operating window dimensions xm are 20-by-20 pixels, and Gaussian standard deviation is 5, which have been produced to improve the reconstruction results. The windows define the square for the reconstruction around the pixel of interest. Window 20-by-20 means the using 20x20 = 400 equations in a minimization problem for each pixel.

Results

To discuss our approach let us start with the result obtained by FT technique.

The conventional DHM imaging technique uses a FT algorithm followed by a filtering and an inverse FT. Topography map and a profile along one line perpendicular to the grating are shown in Fig. 2. A small part of all surface of grating (12x12 |jm2) is chosen for a quick estimation of calculation algorithm. The total field of view is 40x40 |im2. The profile along a line shows the maximal amplitude of about 120 nm. Due to the high noise the grating period (which is supposed to be A = 1 |m) cannot be precisely determined. Nevertheless, the SRG data coincide with the optical measurements of SRG recorded on the As2S3 - Se NML [12]. Note that DHM approach is the full field express method which can be used without additional sample preparation.

Topo graphy, nm '

0 12 3 4 Topography, nm 150-

100

50

8 9 \un Distance

V-j T

V V \

0 1 2 3 4 5 6 7 8^9 10 11

Distance, \im

Fig. 2. Topography map (top) and cross-section (bottom) of grating at image plane obtained by FT technique

However, it is impossible to see the sinusoidal surface relief definitely. The calculated profile of lines is shown the maximal sweep of amplitudes being about 130 nm. The period of grating is not seen clearly because of the high level of noises. In comparison with the calculated period of grating (A = 1 |m) during holographic recording the period of grating is corrupted by noises and is not clearly seen. Thus, the obtained information about the surface relief is not sufficient.

Fig. 3 shows the SPAR reconstructions of SRG. The SPAR reconstructions clearly demonstrate the denoised images in comparison with quite noisy reconstructions obtained by standard FT shown in Fig. 2. The cross sections show in Fig. 3 (bottom) that the SPAR algorithm eliminates the noise and preserves important profile details.

Topography, nm

300 200 100

■/7 Vv / /

v/////////

0 12 3 Topography, nm 150

100 50

4 5 6 7 8 9 \xm Distance

% -fV- % \ x "Xl Xi a/

V/ 1/ V \J \J V V

0

? 9 10 11 Distance, \im

Fig. 3.Topography map (top) and cross-section (bottom) of grating at image plane obtained by SPAR technique

Compare the results obtained by DHM using the SPAR algorithm with the ones of the AFM technique presented in Fig. 4.

The cross-section of the DHM data (Fig. 3) matches with the cross-section of the AFM data (Fig. 4). The differences are visible in the topography maps. The noisier 3D-map in the SPAR reconstruction may result from the data presentation in different spaces in these methods. The SPAR reconstructs the phase map whilst the AFM measures the surface directly. Moreover, unlike the AFM technique in our DHM configuration the object beam passes through the glass substrate volume and residual thickness of the NML (2.5 |m), thereby embedding uncontrolled noises/phases in the topography map of SRG.

Topo graphy, nm

\xm Distance

Topography, nm

40 20 0 -20 -40 -60

-4 —f —/ 7"

-A U

0 1 2 3 4 5

Distance, \xm

Fig. 4. Topography map (top) and cross-section (bottom) of grating at image plane obtained by AFM technique

Conclusion

To sum up, the followings results are presented in this paper:

Surface relief gratings on As2S3 - Se NML patterned by one-step direct holographic recording have been measured by DHM.

The applicability of the DHM method for quantitative measurements of surface microstructure at nanoscale has been demonstrated. In order to obtain a more effective and practical solution, two holograms corresponding to two locations on the sample's surface have been compared to extract the relief of grating.

The SPAR algorithm for wavefront reconstruction from a digital hologram recorded in off-axis configuration of DHM has been applied with modifications developing for NML studying. The reconstruction results demonstrated a better effectiveness of our approach in comparison with standard FT.

We may conclude that the high resolution off-axis configuration of the DHM setup is applicable for SRG nanoscale investigation. The novel variational algorithm developed for the digital off-axis holography is able to produce a high-quality imaging for quite noisy data. Moreover, the surface depth and relief of grating are guaranteed in processing.

Comparing the data of surface relief recovered by DHM with those recovered by AFM one can clearly see that the SPAR reconstruction gives the results qualitatively and quantitatively coinciding with the AFM data. The proposed off-axis configuration of DHM with the developed SPAR algorithm for hologram processing may be an effective express method. Moreover, it is a good complement to the AFM and the SEM.

Our results demonstrate that the application of the DHM and the developed SPAR algorithm for image processing obviously reveal the topography of diffraction grating on As2S3 - Se NML in the presence of experimental noises on digital images.

The potential impact of the paper consists in the development of the advanced optical techniques for diffrac-tive structures investigations at nanoscale. The proposed approach has been tested on measuring SRG of As2S3 -Se NML patterned by direct, one-step holographic recording.

References

[1] Tanaka K, Shimakawa K. Amorphous chalcogenide semiconductors and related materials. New York: Springer; 2011. ISBN: 978-1-4419-9509-4.

[2] Voynarovych I, Schroeter S, Poehlmann R, Vlcek M. Surface corrugating direct laser writing of microstructures in ternary chalcogenide films using a continuous-wave superbandgap laser. J Phys D: App Phys 2015; 48(26): 265106. DOI: 10.1088/0022-3727/48/26/265106.

[3] Gerbreders A, Bulanovs A, Mikelsone J, Traskovskis K, Potanina E, Vembris A, Teteris J. Photoinduced mass transport in low molecular organic glasses and its practical application in holography. J Non-Crystalline Solids 2015; 421: 48-53. DOI: 10.1016/j.jnoncrysol.2015.04.040.

[4] Sakai T. Hologram copy using amorphous films as a master. Opt Commun 1978; 24: 47-50. DOI: 10.1016/0030-4018(78)90264-X.

[5] Bohdan R, Molnar S, Kokenyesi S. Methods comparing peculiarities of surface-relief recording in amorphous chal-cogenides. Phys Status Solidi A 2015; 212(10): 2186-2190. DOI: 10.1002/pssa.201532288.

[6] Molnara S, Bohdana R, Csarnovicsa I, Burunkovab I, Kokenyesi S. Amorphous chalcogenide layers and nano-composites for direct surface patterning. Proc SPIE 2015; 9359: 935908. DOI: 10.1117/12.2076470.

[7] Kreis T. Handbook of holographic interferometry: Optical and digital methods. Veinheim: Wiley-VCH Verlag GmbH & Co. KGaA; 2005. ISBN: 978-3-527-40546-6.

[8] Cuche E, Bevilacqua F, Depeursinge C. Digital holography for quantitative phase-contrast imaging. Opt Lett 1999; 24(5): 291-293. DOI: 10.1364/OL.24.000291.

[9] Schnars U. Direct phase determination in hologram interferometry with use of digitally recorded holograms. JOSA A 1994; 11(7): 2011-2015. DOI: 10.1364/JOSAA. 11.002011.

[10] Claus D, Watson J, Rodenburg J. Analysis and interpretation of the Seidel aberration coefficients in digital holography. Appl Opt 2011; 50(34): H220-H229. DOI: 10.1364/AO.50.00H220.

[11] Stronski A, Achimova E, Paiuk A, Abashkin V, Meshalkin A, Prisacar A, Triduh G, Lytvyn O. Surface relief formation in Ge5As37S58-Se nanomultilayers. J Non-Cryst Solids 2015; 409: 43-48. DOI: 10.1016/j.jnoncrysol.2014.11.010.

[12] Achimova E, Stronski A, Abaskin V, Meshalkin A, Paiuk A, Prisacar A, Oleksenko P, Triduh G. Direct surface relief formation on As2S3-Se nanomultilayers in dependence on polarization states of recording beams. Opt Mater 2015; 47: 566-572. DOI: 10.1016/j.optmat.2015.06.044.

[13] Osten W, Faridian A, Gao P, Korner K, Naik D, Pedrini G, Singh AK, Takeda M, Wilke M. Recent advances in digital holography. Appl Opt 2014; 53(27): G44-G63. DOI: 10.1364/AO.53.000G44.

[14] Osten W, Baumbach T, Juptner W. Comparative digital holography. Opt Lett 2002; 27(20): 1764-1766. DOI: 10.1364/OL.27.001764.

[15] Kujawinska M, Wojciak J. High accuracy Fourier transform fringe pattern analysis. Optics and lasers in engineering 1991; 14(4): 325-339.

[16] Liebling M, Blu T, Unser M. Complex-wave retrieval from a single off-axis hologram. JOSA A 2004; 21(3): 367-377. DOI: 10.1364/JOSAA.21.000367.

[17] Dabov K, Foi A, Katkovnik V, Egiazarian K. Image de-noising by sparse 3-D transform-domain collaborative filtering. IEEE Trans Image Process 2007; 16(8): 2080-2095. DOI: 10.1109/TIP.2007.901238.

[18] Katkovnik V, Shevkunov IA, Petrov NV, Egiazarian K. Wavefront reconstruction in digital off-axis holography via sparse coding of amplitude and absolute phase. Opt Lett 2015; 40(10): 2417-2420. DOI: 10.1364/OL.40.002417.

[19] Katkovnik V, Astola J. High-accuracy wave field recon-

struction: decoupled inverse imaging with sparse modeling of phase and amplitude. JOSA A 2012; 29(1): 44-54. DOI: 10.1364/JOSAA.29.000044.

Author's information

Elena Achimova received her Master in Physics from the State University of Chisinau in 1981 and Candidate of Sciences in Physics and Mathematical Sciences (equivalent of PhD) from the Institute of Applied Physics, ASM in 1989. From 1989 to 2003, she was employed at the Institute of Applied Physics, Chisinau, making investigations in recording media for holography. From 2003 to 2009, she was employed at the Polytechnic University of Ancona (Italy) as the scientific researcher of the Mechanical department where she received PhD degree in Mechanical Engineering in 2006. The field of the scientific interests is non-crystalline physics, optoelectronics and optical sensors, holography, holographic interferometry. E-mail: achimova@phys.asm.md .

Vladimir Abaskin received his Master in Physics from the State University of Chisinau in 1971 and Candidate of Sciences in Physics and Mathematical Sciences (equivalent of PhD) from the Institute of Applied Physics, ASM in 1983. From 2001 to 2009, he was employed at the Polytechnic University of Ancona (Italy) as the scientific researcher of the Mechanical department where he received PhD degree in Mechanical Engineering in 2005. The field of the scientific interests is non-crystalline physics, optoelectronics and optical sensors, optical fibers, optical interferometry systems design by optical codes. E-mail: vabaskin@yahoo.com .

Daniel Claus received his Master in Engineering from the Technical University of Ilmenau in 2006 and his PhD from the University of Warwick (Great Britain) in 2010. During the past 7 years his activities were related to the development of quantitative phase imaging techniques such as digital holography and ptychography with major applications in surface metrology and biomedical imaging. E-mail: claus@ito.uni-stuttgart.de .

Giancarlo Pedrini received his Master in Physics from the Swiss Federal Institute of Technology of Zurich (ETH) in 1982 and his PhD from the University Neuchatel (Switzerland) in 1990. He is the leader of the Coherent Optical Metrology Group. During the past 23 years his activities were related to the development of optical full field techniques for the metrology and imaging of microscopic samples. E-mail: pedrini@ito.uni-stuttgart.de .

Igor Shevkunov received his Master in Physics from the Saint Petersburg State University, Russia in 2008 and his PhD in Optics from the Saint Petersburg State University, Russia, in 2012. His main research interests are digital holography, interferometry, atomic and molecular physics, and lasers. E-mail: Shevkunov Igor@mail.ru .

Vladimir Katkovnik received his Master in Physics from the Saint Petersburg Technical University, Russia in 1960 and his PhD from the Saint Petersburg Technical University, Russia, in 1964 and Doctor of Science from 1974, Saint Petersburg Technical University, Russia in 1974. He is a Senior Research Fellow of Signal processing laboratory, Tampere University of Technology. His research interests include stochastic signal processing, linear and nonlinear filtering, nonparametric estimation, imaging, nonstationary systems, and time-frequency analysis. He published 6 books and over 300 papers. E-mail: Vladimir.katkovnik@tut.fi .

Code of State Categories Scientific and Technical Information (in Russian - GRNTI)): 29.31.29.

Received July 19, 2017. The final version - February 13, 2018.