key: cord-0854873-r9yiqspj authors: Karelits, Matityahu; Zalevsky, Zeev; Karsenty, Avi title: Nano polarimetry: enhanced AFM-NSOM triple-mode polarimeter tip date: 2020-10-01 journal: Sci Rep DOI: 10.1038/s41598-020-72483-9 sha: af4a3cd6478de5b5d30722ab0f191de94afc0985 doc_id: 854873 cord_uid: r9yiqspj A novel application of a combined and enhanced NSOM-AFM tip-photodetector system resulted in a nanoscale Polarimeter, generated by four different holes, each sharing a different shape, and enabling that the four photonic readouts forming the tip will be the four Stokes coefficients, this in order to place the polarization state in the Poincare sphere. The new system has been built on standard Atomic Force Microscope (AFM) cantilever, in order to serve as a triple-mode scanning system, sharing complementary scanning topography, optical data analysis and polarization states. This new device, which has been designed and simulated using Comsol Multi-Physics software package, consists in a Platinum-Silicon drilled conical photodetector, sharing subwavelength apertures, and has been processed using advanced nanotechnology tools on a commercial silicon cantilever. After a comparison study of drilled versus filled tips advantages, and of several optics phenomena such as interferences, the article presents the added value of multiple-apertures scanning tip for nano-polarimetry. | (2020) 10:16201 | https://doi.org/10.1038/s41598-020-72483-9 www.nature.com/scientificreports/ mechanical topography (AFM), (2) electro-optical info (NSOM), and (3) polarization states (i.e. four apertures), we may progress step-by-step, and first present the combined approach of AFM and NSOM, which have progressed a lot in parallel since the last decades. As a stand-alone analysis, each one of these well-known methods presents solid data analysis advantages. The design and the simulation of new tips towards fabrication 11 , as well as the manufacturing process itself of new tips using new processed methods 12, 13 , has largely progressed. With time, the idea of combining several methods was developed and studied, such as the organic light-emitting devices (OLEDs) with micro-machined silicon cantilevers 14 . In our specific case, the idea of combining AFM and NSOM measurement capabilities, into one dual-mode based on silicon tip, is quite unique and presents several advantages and features: dual-mode in one tip, low-cost starting material (standard commercial AFM tip), easy six-steps-based process, energetic efficiency combined with multi-functionality, accurate and direct light acquisition from the sample surface itself, and of course a good SNR (Signal to Noise Ratio). The concept of the improved system is presented in Fig. 1 with two separated configurations: Filled tip-photodetector ( Fig. 1a,b) , and drilled-tip-photodetector (Fig. 1c,d) . In the second configuration, the truncated photo-detector is placed instead the regular silicon tip, at the end of the cantilever (Fig. 1c) . filled vs. drilled tip-photodetector. As presented in previous publication 15 , there is a clear advantage in drilled photodetector, since it enables a direct reading from the surface reflection. In this approach, the first advantage is the light collection process, which will be directly performed from the surface of the sample. Some lock-in amplifier can be added to detect the small current signals (in the pA range). As mentioned above, the main advantages are related to the capability of our proposed NSOM-AFM dual mode system to enable both multi-functionality in one device, and also to have increased energetic collection efficiency (due to the fact that reflected light is directly converted to intensity readout at the tip and does not have to be coupled and guided through the collection fiber as done in the case of conventional NSOM system). finite elements method and sensor structure. In order to perform a complete and accurate numerical study of the proposed device, the platform of Comsol Multi-Physics software package 16 was used. This platform's approach is based on the Finite Elements Method (FEM) 17, 18 . The combined and enhanced NSOM-AFM tipphotodetector system, which we propose, consists of a silicon Schottky photo diode sharing a sub-wavelength aperture at the top of the tip 19 . In such a way, a nanoscale electro-optical sensor, placed on a commercial AFM cantilever's tip, would enable (1) the collection of the topography (AFM), (2) the collection of the optical data (NSOM), and later on the collection of the four Stokes Criteria (Polarization) when drilling four apertures at its top, creating a triple-mode measurement system, for nano-polarimetry. In the past, electrical and optical www.nature.com/scientificreports/ responses, were studied and optimized while scanning a laser beam, and high resolution of order of the detector's aperture was obtained 19 . Since this device structure is quite complex and challenging, in particular in the nanoscale range, the tip-photodetector was first simulated separately, and then combined to simulated standard silicon-based cantilever. As shown below in Figs. 2 and 3, the nano-polarimeter shares a 3D structure of a truncated conical-shaped photodetector device. With a height of 1.6 μm, a top radius of 75 nm (at this stage), and a bottom radius determined by the silicon plane cutting slope, equal to 57° which gives 1 μm for the corresponding height, the device presents several challenges. One of them is the mesh complexity, and therefore the corresponding simulation run time (the more complex the web of elements, the longer the run time). When compared to the commercial tip, sharing a height of 16 μm, the height considered here for simulation was in the range of 1/10 of the real AFM silicon tip's height. Set-up and parameters: concerns and considerations. The initial set-up for a representative simulation of the reflected light from a surface is presented in Fig. 4 . At this stage of the preliminary simulations, no photodetector is added, and the light is directly reflected and captured from the surface. Comsol Multi-Physics Software Package enables to create the simulation inside a virtual box, which serves as the medium of the measurements. For convenience and much more rapid simulations, the box itself was placed in different angles instead of the beam. Of course, there is no limitation to change the angle of the beam on a horizontal surface. Stepping a leap ahead, the aim of the next following studies was to establish a forecast of the optimized parameters to be used during the scanning of a surface when an incident illumination is reflected with a specific angle, and captured by a photodetector. The difference in the measured photocurrents ΔI is presented as a function of several parameters, such as: • α-the illumination incidence and reflection angle, • a-the height of the photodetector and the scanned surface (contact or proximity mode), • λ-the wavelength of the illumination, • ϕ-The work function of the photodetector external layer, and more. The chosen parameters are summarized in Table 1 below. In Fig. 5 , the representative simulation of the reflected light, directly captured from the surface in the photodetector, is presenting the measured photocurrent for an angle of 45°. photo-current as a function of the illumination angle. As presented in the two following figures, the next step was to check the influence of the angle of the illumination beam and to identify the optimized one. Figure 6 presents the different angle positions when Fig. 7 presents the corresponding photocurrents. www.nature.com/scientificreports/ Measured photocurrent as a function of the distance from the surface. Since the new NSOM-AFM photo-detection will be used to scan the surface of materials, it was important to evaluate the optimized distance a of the tip from the surface. Series of simulations were performed when varying the distance from 5 nm (almost contact mode) till 50 nm (proximity mode). Two devices were tried and compared, in order to assure the dual-mode existence of AFM and of NSOM capabilities: First, the surface scanning was performed using a filled tip-photodetector (Fig. 8 )-e.g. no open cylinder inside the tip as shown in Fig. 1a ,b-as a regular AFM tip. In other words, in this case, the check was of the answer of a regular Schottky diode. Then the NSOM mode was checked ( Fig. 9 ), when this time the photodetector, sharing the same dimensions of previous used one, was drilled, as presented in Fig. 1c ,d. It was clearly observed that if for regular filled device, the curves are continuous, for the truncated one, the curves present discrete steps. Such steps in current can definitely be interpreted by the amounts of absorbed photocurrent inside the cylinder of the truncated device, but this time with constructive and destructive interferences, as well observed in Fig. 10 . Finally, it is important to clarify that for convenience purpose of user friendly simulations, some assumptions were taken in consideration: If the photodetector structures were built in 3D, as shown in the top-left inserts of Figs. 8 and 9, the electro-optical simulations themselves were performed in 2D, as shown in the curves of Figs. 8 and 9. Measured photocurrent as a function of the aperture diameter. In order to better identify the optimal aperture diameter for such a scanning photodetector, series of simulations have been performed when varying the aperture diameter from 0 nm (e.g. filled device) to 150 nm (wavelength limit), by steps of 30 nm, as shown in Fig. 11 . The simulation of the measured photocurrent as a function of the scanning distance d, and of the aperture radius R cylinder is presented in Fig. 12 . Based on different apertures (Fig. 11 ), the measured photocurrent curves present clear steps (Fig. 12 ) as a function of the radius. Except one curve, representing a photodetector sharing a radius of 0 nm (e.g. filled Schottky diode), all the other curves present the step-function phenomena. This can be explained by some diffraction and perhaps interference phenomena of the wave functions entering an aperture smaller than the wavelength. In Fig. 12 , one can assume that the photocurrent values decrease with the increase of the aperture radii, since there is less silicon for light absorption, and since destruc- www.nature.com/scientificreports/ tive interferences increase with the drilled aperture. In Fig. 13 , one can assume that the photocurrent values decrease with the increasing wavelength, since we are working with sub-wavelength apertures. The higher is the wavelength, the smaller remains the aperture. www.nature.com/scientificreports/ Measured photocurrent as a function of the incident wavelength. Another necessary study was to check the influence of the incident wavelength on the measured photocurrent. For this purpose, simulations ran series of wavelengths, in a range of 500-600 nm (Fig. 13 ). The lower is the wavelength the higher is the measured photocurrent. In this experiment, the distance a from the surface is varying from 5 to 50 nm, and the angle α of the beam is 45°. The surface scanning is performed on a distance d of 1 µm. Multiple-apertures tip rationale. Moving forward with the drilled tip idea, an interesting and novel application to study would be to simultaneously generate four different holes, each sharing a different shape: one oval in X (s state polarizing), one in Y (p state polarizing) etc. such that the four photonic readouts forming the tip will be the four Stokes coefficients, in order to place the polarization state in the Poincare sphere. In such a Table 1 . www.nature.com/scientificreports/ its total intensity (I), (fractional) degree of polarization (p), and the shape parameters of the polarization ellipse. The effect of an optical system on the polarization of light can be determined by constructing the Stokes vector for the input light and applying Mueller calculus, to obtain the Stokes vector of the light leaving the system. The original Stokes paper was discovered independently by Perrin 22 and by Chandrasekhar 23 , who named it as the Stokes parameters. The relationship of these Stokes parameters S 0 , S 1 , S 2 , S 3 to the intensity and the polarization ellipse parameters is presented in below equations: where Ip , 2ψ and 2χ are the spherical coordinates of the three-dimensional vector of cartesian coordinates ( S 1 , S 2 , S 3 ). I is the total intensity of the beam, and p is the degree of polarization, constrained by 0 ≤ p ≤ 1 . The factor of two before ψ represents the fact that any polarization ellipse is indistinguishable from one rotated by 180°, while the factor of two before χ indicates that an ellipse is indistinguishable from one with the semi-axis lengths swapped accompanied by a 90° rotation. The phase information of the polarized light is not recorded in the Stokes parameters. The four Stokes parameters are sometimes denoted I, Q, U and V, respectively. Scanning tip for nano-polarimetry. In order to measure the exact position of a polarization state on the Poincare sphere, one needs estimate the four Stokes parameters. Those parameters are defined as follows: While the degree of polarization (DOP) can be computed out of the 4 Stokes parameters as: Measured photocurrent as function of the distance d, presented for several wavelengths between 500 and 600 nm. The distance a is 5 nm, and the angle α is 45°. Chosen representative radius of the drilled aperture is 35 nm. All other parameters are presented in Table 1 www.nature.com/scientificreports/ where P 0 • and P 90 • are the powers measured after linear horizontal and vertical polarizers respectively, P +45 • and P −45 • are the powers measured after linear +45 • and −45 • polarizers respectively and P +45 • ; /4 and P −45 • ; /4 are the powers measured after /4 retarder and linear polarizers at +45 • and −45 • , respectively. is the optical wavelength. The seven measurements are related to each other and actually it is enough to measure only four measurements: P 0 • , P 90 • , P +45 • and P +45 • ; /4 from which the four Stokes parameters can extracted as: www.nature.com/scientificreports/ experimental realizations. The four measurements expressed above, and which are required in order to extract the polarization state and to allocate the position of the polarization state on the Poincare sphere, can be measured in two possible configurations. One main configuration involves measuring the four parameters with the scanning nano tip while integrating into it the required components as depicted in Fig. 14a : • P 0 • , P 90 • and P +45 • are realized by generating oval slits at the end of the tip. The tip is coated with metallic coating and by generating three different oval slits at 0 • , 90 • and +45 • the three polarizers are achieved. The oval slits have one narrow dimension which is about /10 and one long dimension which is above one . • P +45 • ; /4 can be realized by putting Yttrium Orthovanadate YVO4 (birefringent material) on the tip while the material is having sufficient width to realize /4 retarder (given its birefringence the required width will be about 2.5 ). Later on, the signal being collected from the fiber is passed through a polarized at +45 • . All the four parameters are realized by properly fabricating the scanning tip and properly analyzing the collected intensities at the four detectors positioned on the other side of the scanning fiber. Another proposed configuration for realizing the measurement includes coating of periodic layers of birefringent material on the edge of the scanning tip. Such coating could realize polarizer as well as /4 waveplate. The proposed configuration is seen in Fig. 14b . The coating could be obtained by putting several layers of YVO4 coated in the right crystal axes in respect to the axes of the incident light. One possible way of computing the structures of such layers could be by using Rouard's method 24 . The method is based on sectioning the grating into a set of thin layers, each treated as a layer with fixed index of refraction. Making use of Fresnel reflection and transmission coefficients enables the computation of a transfer matrix for each layer. For example, for the k'th layer, this matrix will have the form: with R k and S k being the forward and backward traveling fields respectively. r k and t k are the Fresnel reflection and transmission coefficients which satisfy: (15) r k = n k − n k+1 n k + n k+1 (16) t k = 2n k n k + n k+1 www.nature.com/scientificreports/ n k and n k+1 are the refraction indexes in two sequential layers of the Bragg structure. As shown in Fig. 14b the Bragg structure has axial periodicity of two materials with different refraction indexes. Those two refraction indexes are denoted as n k and n k+1 . The phase φ k represents the phase shift in the k'th section: where δz k is the width of the section: Thus, as seen in the figure, one polarization at wavelength of 630 nm is back reflected almost completely while the second will not see the periodic Bragg structure of the layers and will be transmitted through the generated structure. Thus, the simulation validates a realization of an optical polarizer that transmits only the horizontal polarization and back reflects the vertical polarization. The proposed configuration is seen in Fig. 14b . The bright blue is a birefringent material and the white blocks are non-birefringent material. Thus, as in the case of Fig. 14a the realization includes four channels with four detectors positioned as part of the proposed tip. However, in contrast to Fig. 14a no oval sub wavelength holes are needed. The three upper channels are the three polarizers of at 0°, 90° and + 45° while they are built as Bragg gratings while the vertical axis in which the Bragg is realized and where the polarizing effect occurs (the vertical axes is back reflected) is rotated at 0°, 90° and + 45° in respect to the vertical axis. The 4th channel has the Bragg based polarizer (the vertical axis of the schematic sketch is rotated at + 45°) while before that a birefringent material realizing /4 waveplate is deposited on the edge of the tip. This /4 wave plate is realized by deposing a birefringent material with width of: which is approximately 0.708 μm for wavelength of 630 nm. www.nature.com/scientificreports/ COMSOL architecture and design. In order to implement the four holes on the top of the tip, it was first necessary to design the structure of the nanoscale polarimeter, as well as the mesh of its different parts. Using again the Finite Elements Method (FEM), 2D and 3D silicon truncated-shaped conical photodetector has been designed, sharing subwavelength pin hole apertures. Then, at the top of the cone, four different shapes, round and ovals, have been selected to serve as the four photonic readouts, as presented in Fig. 16 . The necessity for an accurate mesh of finite elements is presented, when the density of the finite elements is varying from standard parts (Fig. 16c) to extra-fine parts (Fig. 16d) . Since there is a need for accurate simulations, special boxes have been created (Fig. 16e,f) . preliminary experimental validation fabrication of tip-photodetectors. In order to show preliminary experimental validation, we have fabricated an AFM-NSOM combined tip. We took a passive commercial silicon AFM tip which we transformed into an active photodetector at its top, such that the photonic readout could be provided directly. One of the main advantages of this AFM-NSOM dual-mode photodetector concept, is the fact that the fabrication process is quite simple, short (few hours overall), and starts from a commercial tip. The six-step rapid process has been largely presented in the past 15 , when starting from standard commercial (FESP-V2 model from Bruker) 25 AFM silicon-based tips. Moreover, additional studies of such tip-photodetector have been presented as well 26 . The profile and the dimensions of the commercial cantilever and of the commercial tip are respectively presented in Fig. 17a-c. In Fig. 18 we show now the next three fabrication steps, after processing them with a Focused Ion Beam (FIB) system: the ablation of the tip top (Fig. 18a) , the Platinum deposition needed to generate the conductance (Fig. 18b) , and the drilling of the cone (Fig. 18c,d) . These three steps were all processed using the Field Electron and Ion company (FEI) Helios 600 FIB system. Several important considerations came up in the choice of this specific equipment: First, its main advantage remains its dual-beam component, enabling combined Scanning Electron Microscopy (SEM) and FIB technologies, in addition to large diversity in gas chemistries, detectors, and manipulators. The second reason is more related to ions' type used in the process. In fact, there are two main types of ions used in such a FIB: Ga+ ions and He ions. For this specific drilling process, it appears that the He www.nature.com/scientificreports/ ions beam is not strong enough to enable a well-done truncated tip, and the Ga+ ions become necessary. On the other hand, there is a concern when using Ga+ ions, since they are capable to cause a significant degradation of the initial silicon crystalline structure, and as a consequence, to affect the electro-optic measurements. Since the Ga+ ions are implanted into the Silicon structure during the FIB processing part, and since they theoretically can be be located in the critical area where there is a need to detect a photo current, they may influence the Signal-to-Noise Ratio (SNR). This concern is reinforced when compared to the implantation process for regular ions, there is no annealing step or any thermal post-recovery process after the drilling stage. In order to assure the quality of the electrode and of the Schottky contact, several checks were performed, and the parts were found functional. non-altered AfM spatial high resolution. It is well known that the high spatial resolution of the atomic force microscopy depends on the probe size, i.e. the contact surface. Generally, standard AFM probes share a tip radius of less than 10 nm. A priori, when a tip is blunt, it becomes difficultly possible to measure the details on the topography of a substrate in picometer or nanometer ranges. A priori, one could argue that our AFM-NSOM probe is blunt, when the contact surface is ten times larger than a commercial tip's contact diameter. In order to assure that the AFM measurement technique is still relevant, we already presented preliminary experimental results 15 for surface topography of materials scanned with these blunt AFM-NSOM probes, in order to show how the AFM imaging capability is not altered. Multi-truncated tips. Looking forward, the next step, which could not be performed yet due to the undefined COVID-19 confinement period, would be to perform the ablation of the tip at different heights, this in order to enable larger contact surfaces in which the FIB will drill this time several apertures on the same plane, as presented above in Figs. 16 and 18. This part will consist in progressive work, with series of samples, sharing different numbers of apertures (from two to four), and different diameters of apertures. Such proposed tip, combining high spatial resolution together with polarimetric capability, is very novel, and has better been demonstrated before. Moreover, it has high applicability in scanning microscopy to be used for improved mapping of functionality of nano photonics devices. The novelty is related to the fact the proposed probe, when scanning nano photonic devices, could provide topography readout together with electro-magnetic intensity distribution, as in NSOM, but together with its polarization state in every sampled point. Such capability yields functionality significantly enhancing the characterization abilities of nano devices, and better understanding their operability. The added value of this specific paper is the capability of combining three modalities together, allowing not only to readout the intensity with nanometric resolution, but also to extract its polarization state. In this article, a new concept of improved scanning system was presented. The new system has been built on standard Atomic Force Microscope (AFM) cantilever, in order to serve as a triple-mode scanning system, sharing complementary scanning mechanical topography (AFM), optical data analysis (NSOM), and polarization states (four multiple apertures as four Strokes criteria). This win-win combining probing system enabling light collection through a very sensitive silicon-based photo-detector, has been designed and simulated using Comsol Multi-Physics software package, and consists in a Platinum-Silicon drilled conical photodetector, sharing subwavelength apertures. It has been processed using advanced nanotechnology tools on a commercial silicon cantilever. After a comparison study of drilled versus filled tips advantages, and of several optics phenomena such as interferences, the article presented the added value of multiple-apertures scanning tip for nano-polarimetry. Such advanced system will enable crossing information of mechanical, optical and polarization results during the samples' scanning process, and thorough and more accurate analysis of the observed results. The importance of using a drilled photodetector when compared to a filled one was discussed. Unfortunately, due to the COVID-19 unlimited unknown confinement period, the next steps will need to be part of an additional research and publication. Near-field scanning optical microscopy (NSOM), development and biophysical applications Nanoscale characterization of gold colloid monolayers: A comparison of four techniques Local energy transfer in self-assembled polyelectrolyte thin films probed by near-field optics Near-field plasmonic probe with super resolution and high throughput and signal-to-noise ratio Differential near-field scanning optical microscopy NSOM investigations of the spectroscopy and morphology of self-assembled multilayered thin films AFM, and NSOM studies of 3D crystallites in mixed Langmuir−Blodgett films of N,N′-Bis(2,6-dimethylphenyl)-3,4,9,10-perylenetetracarboxylic diimide and stearic acid Product review: The Saga of AFM, a journey into a hot analytical market Product review: Shedding light on NSOM Design of mems based microcantilever using comsol multiphysics Tip-enhanced infrared nanospectroscopy via molecular expansion force detection Near field phase mapping exploiting intrinsic oscillations of aperture NSOM probe Localized current injection and submicron organic light-emitting device on a pyramidal atomic force microscopy tip Advanced surface probing using dual-mode NSOM-AFM siliconbased photo-sensor Comsol Multi-Physics Software Package Computer algebra challenges in nanotechnology: Accurate modeling of nanoscale electro-optic devices using finite elements method computer algebra in nanotechnology: modelling of nano electro-optic devices using finite element method (FEM) Electro-optical study of nanoscale Al-Si truncated conical photodetector with subwavelength aperture On the composition and resolution of streams of polarized light from different sources Polarization of light scattered by isotropic opalescent media The transfer of radiation in stellar atmospheres Analysis of waveguide gratings: Application of Rouard's method FESP-V2 probes website Time-spectral based polarization-encoding for spatial-temporal superresolved NSOM readout M.K. performed all the Comsol simulations, and prepared the corresponding figures. He also participated in writing the description of these figures. Z.Z. is co-author of the manuscript's text and simulations and leads the Bar-Ilan University (BIU) labs. A.K. is the supervisor and the initiator of this research, the team leader of the ALEO labs, the author of the main manuscript text. In addition to the writing of text itself, he also worked on the figures explanations. All authors reviewed the manuscript. The authors declare no competing interests. Supplementary information is available for this paper at https ://doi.org/10.1038/s4159 8-020-72483 -9.Correspondence and requests for materials should be addressed to A.K.Reprints and permissions information is available at www.nature.com/reprints.Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons license, unless indicated otherwise in a credit line to the material. 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