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1. In-chip microstructures and photonic devices fabricated by nonlinear laser lithography deep inside silicon

Author

Tokel, O., Turnali, A., Makey, G., Elahi, P., Ilday, S., Çolakoğlu, T., Ergeçen, E., Yavuz, Ö., Hübner, R., Borra, M. Z., Pavlov, I., Bek, A., Turan, R., Tozburun, S., and Ilday, F. Ö.

Subjects
Physics - Optics
Abstract

Silicon is an excellent material for microelectronics and integrated photonics with untapped potential for mid-IR optics. Despite broad recognition of the importance of the third dimension, current lithography methods do not allow fabrication of photonic devices and functional microelements directly inside silicon chips. Even relatively simple curved geometries cannot be realized with techniques like reactive ion etching. Embedded optical elements, like in glass, electronic devices and better electronic-photonic integration are lacking. Here, we demonstrate laser-based fabrication of complex 3D structures deep inside silicon using 1 micrometer-sized dots and rod-like structures of adjustable length as basic building blocks. The laser-modified Si has a different optical index than unmodified parts, which enables numerous photonic devices. Optionally, these parts are chemically etched to produce desired 3D shapes. We exemplify a plethora of subsurface, i.e., "in-chip" microstructures for microfluidic cooling of chips, vias, MEMS, photovoltaic applications and photonic devices that match or surpass the corresponding state-of-the-art device performances.

Published
2014

2. In-Volume Laser Direct Writing of Silicon - Challenges and Opportunities

Author

Chambonneau, M., Grojo, D., Tokel, O., Ilday, F.Ö., Tzortzakis, S., Nolte, S., and Publica

Subjects
laser direct writing, laser-matter interaction, Infrared / Materials, nonlinear propagation
Abstract

Laser direct writing is a widely employed technique for 3D, contactless, and fast functionalization of dielectrics. Its success mainly originates from the utilization of ultrashort laser pulses, offering an incomparable degree of control on the produced material modifications. However, challenges remain for devising an equivalent technique in crystalline silicon which is the backbone material of the semiconductor industry. The physical mechanisms inhibiting sufficient energy deposition inside silicon with femtosecond laser pulses are reviewed in this article as well as the strategies established so far for bypassing these limitations. These solutions consisting of employing longer pulses (in the picosecond and nanosecond regime), femtosecond-pulse trains, and surface-seeded bulk modifications have allowed addressing numerous applications.

Published
2021

3. Subsurface Engineering of Silicon for 3D Devices

Author

Tokel, O., Turnali, A., Makey, G., Elahi, P., Ilday, S., Colakoglu, T., Yavuz, O., Hübner, R., Zolfaghari, M., Pavlov, I., Bek, A., Turan, R., and Ilday, O.

Abstract

Recently we have demonstrated a new 3D-laser-fabrication method which enabled, for the first time, creating highly-controlled subsurface structural modifications (structural imperfections, or defects) buried deep inside Silicon (Si) wafers [1]. Characterizing the material properties of these subsurface Si structures are very critical towards enabling new optical and micro-mechanical applications inside chips [2,3]. Here, we present optical, chemical and microscopic analysis of these buried structures. Specifically, Transmission Electron Microscopy (TEM) studies, Optical Birefringence Analysis and Selective Chemical Etching analysis of the modifications will be presented. Infrared Transmission Microscopy will be shown to be applicable for subsurface imaging, providing a diagnostic tool without damaging the samples. Material properties of the disruptions in the crystal lattice are then exploited for fabricating various micro-devices. For instance, oxidation-reduction chemistry on laser-induced modifications enables the creation of highly-controllable, uniform and large-area micropillar arrays for solar cell applications, embedded microfludic channels for chip cooling and thru-Si vias for electrical interconnects in Si. These elements, which are challenging to form with conventional methods, can find use in various MEMS and electronics applications. The optical properties (refractive index change) of the structures are used to fabricate functional components such as lenses and gratings buried in chips. Further, the birefringence effect induced in Si may lead to holograms and other photonic applications, such as creating wave plates and polarizers. These functional optical and MEMS elements created inside Si, may find use in imaging and sensing in the near- and mid-infrared wavelength range, as well as in micro-devices towards micro-surgical tools, micro-motors, and micro-resonators. Thus, these capabilities are leading to a new fabrication approach in Si, which is fully CMOS compatible, rapid and mechanically robust, and builds on the optical,electrical and chemical properties of the modified volumes in Si. [1] Tokel et. al., arxiv.org/abs/1409.2827 [2] Tokel et. al, Direct Laser Writing of Volume Fresnel Zone Plates in Silicon., CLEO/Europe - EQEC, Munich, Germany, 2015. [3] Tokel et. al., 3D Functional Elements Deep Inside Silicon with Nonlinear Laser Lithography, APS March Meeting, Baltimore, USA, 2016.

Published
2017

4. Photodissociation channels for N2O near 130 nm studied by product imaging.

Author

Lambert, H. M., Davis, E. W., Tokel, O., Dixit, A. A., and Houston, P. L.

Subjects
PHOTODISSOCIATION, NUCLEAR reactions, DISSOCIATION (Chemistry), ANGULAR correlations (Nuclear physics), SCATTERING (Physics), IMAGING systems
Abstract

The photodissociation of N2O at wavelengths near 130 nm has been investigated by velocity-mapped product imaging. In all, five dissociation channels have been detected, leading to the following products: O(1S)+N2(X 1Σ), N(2D)+NO(X 2Π), N(2P)+NO(X 2Π), O(3P)+N2(A 3Σ+u), and O(3P)+N2(B 3Πg). The most significant channel is to the products O(1S)+N2(X1Σ), with strong vibrational excitation in the N2. The O(3P)+N2(A,B):N(2D,2P)+NO branching ratio is measured to be 1.4±0.5, while the N2(A)+O(3PJ):N2(B)+O(3PJ) branching ratio is determined to be 0.84±0.09. The spin-orbit distributions for the O(3PJ), N(2PJ), and N(2DJ) products were also determined. The angular distributions of the products are in qualitative agreement with excitation to the N2O(D 1Σ+) state, with participation as well by the 3Πv state. [ABSTRACT FROM AUTHOR]

Published
2005
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5. O([super 1]D) + [N.sub.2]O reaction: NO vibrational and rotational distributions

Author

Tokel, O., Chen, J., Ulrich, C. K., and Houston, P. L.

Subjects
Deuterium -- Chemical properties, Lasers -- Usage, Molecular beams -- Usage, Nitric oxide -- Chemical properties, Nitric oxide -- Optical properties, Ozone -- Chemical properties, Photolysis -- Analysis, Laser, Chemicals, plastics and rubber industries
Published
2010

11. Click to download data: an event study of Internet access to economic statistics

Author

Tokel, O. Emre and Yucel, M. Eray

Subjects
jel:G14, jel:C50, Data access, Macroeconomic data, Market efficiency, Event study, jel:G10
Abstract

This study examines the online access statistics of the Central Bank of Turkey’s Electronic Data Delivery System within an event study framework. The comparisons of pre-event and post-event statistics suggest that announcements of both the policy interest rates and the consumer price data considerably affect society’s data access behavior. The timing and amplitude of these effects are further studied with respect to inflation expectations and surprise content of events; yet no solid pattern was revealed.

Published
2009

17. Direct laser writing of volume fresnel zone plates in silicon

Author

Ahmet TURNALI, Tokel, O., Pavlov, I., Ilday, F. Ö, Turnalı, Ahmet, Tokel, Onur, Pavlov, Ihor, and İlday, F. Ömer

Abstract

Date of Conference: 21–25 June 2015 Conference Name: 2015 European Conference on Lasers and Electro-Optics - European Quantum Electronics Conference Functional optical elements fabricated on silicon (Si) constitute fundamental building blocks of Si photonics [1]. For the fabrication of these elements, conventional lithography and etching techniques are used. In spite of the success of these techniques, a functional optical element embedded inside silicon simply does not exist. Here, we present a maskless, one-step laser writing technique for creating phase-type Fresnel zone plates in the bulk of Si. Due to their effectiveness over a broad spectra, Fresnel zone plates (FZPs) are widely used in various micro-imaging applications [2]. Similar lenses have been fabricated inside silica [3,4], but are limited to the transparency window of silica. The silicon counterpart of these elements have been impossible to fabricate so far. By exploiting nonlinear absorption within the focal volume of a tightly focused laser, we generated permanent refractive index changes in Si. The imprinted high-index contrast was then used to fabricate a FZP inside Si. This three dimensional (3D) method can allow for alignment-free multilens systems. Moreover, using silicon as the lens material is fully CMOS compatible and applicable to silicon integrated optics, including single and array detectors.

18. Two-photon excitation of quantum dots in 3D via stacked fresnel hologram algorithm

Author

Denizhan Koray Kesim, Makey, G., Yavuz, O., Tokel, O., and O¨mer Ilday, F.

Subjects
Algorithm, Quantum dots, Fresnel hologram, Three dimensional, Holograms
Abstract

Date of Conference: 25-29 June 2017 Conference Name: European Conference on Lasers and Electro-Optics and the European Quantum Electronics Conference, CLEO/Europe - EQEC 2017 Quantum dots are engineered to have nanometers dimensions. The ability to specify the diameter and the material of the quantum dots allow us tune the absorption and emission properties. This results in extensive capabilities for imaging and display applications. Further, with two photon absorption and high peak power laser they can be excited at any point in 3D locally.

19. Laser nanofabrication inside silicon with spatial beam modulation and anisotropic seeding.

Author

Asgari Sabet R, Ishraq A, Saltik A, Bütün M, and Tokel O

Abstract

Nanofabrication in silicon, arguably the most important material for modern technology, has been limited exclusively to its surface. Existing lithography methods cannot penetrate the wafer surface without altering it, whereas emerging laser-based subsurface or in-chip fabrication remains at greater than 1 μm resolution. In addition, available methods do not allow positioning or modulation with sub-micron precision deep inside the wafer. The fundamental difficulty of breaking these dimensional barriers is two-fold, i.e., complex nonlinear effects inside the wafer and the inherent diffraction limit for laser light. Here, we overcome these challenges by exploiting spatially-modulated laser beams and anisotropic feedback from preformed subsurface structures, to establish controlled nanofabrication capability inside silicon. We demonstrate buried nanostructures of feature sizes down to 100 ± 20 nm, with subwavelength and multi-dimensional control; thereby improving the state-of-the-art by an order-of-magnitude. In order to showcase the emerging capabilities, we fabricate nanophotonics elements deep inside Si, exemplified by nanogratings with record diffraction efficiency and spectral control. The reported advance is an important step towards 3D nanophotonics systems, micro/nanofluidics, and 3D electronic-photonic integrated systems., (© 2024. The Author(s).)

Published
2024
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20. Laser-written wave plates inside the silicon enabled by stress-induced birefringence.

Author

Saltik A and Tokel O

Abstract

Laser writing enables optical functionality by altering the optical properties of materials. To achieve this goal, efforts generally focus on laser-written regions. It has also been shown that birefringence surrounding the modified regions can be exploited for achieving functionality. The effect has been used to fabricate wave plates in glass, with significant potential for other materials. Here, we establish analogous stress control and birefringence engineering inside silicon. We first develop a robust analytical model enabling the prediction of birefringence maps from arbitrary laser-written patterns. Then, we tailor three-dimensional laser lithography to create the first, to the best of our knowledge, polarization-control optics inside silicon.

Published
2024
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21. High-Efficiency Multilevel Volume Diffraction Gratings inside Silicon.

Author

Bütün M, Saylan S, Asgari Sabet R, and Tokel O

Abstract

Silicon (Si)-based integrated photonics is considered to play a pivotal role in multiple emerging technologies, including telecommunications, quantum computing, and lab-chip systems. Diverse functionalities are either implemented on the wafer surface ("on-chip") or recently within the wafer ("in-chip") using laser lithography. However, the emerging depth degree of freedom has been exploited only for single-level devices in Si. Thus, monolithic and multilevel discrete functionality is missing within the bulk. Here, we report the creation of multilevel, high-efficiency diffraction gratings in Si using three-dimensional (3D) nonlinear laser lithography. To boost device performance within a given volume, we introduce the concept of effective field enhancement at half the Talbot distance, which exploits self-imaging onto discrete levels over an optical lattice. The novel approach enables multilevel gratings in Si with a record efficiency of 53%, measured at 1550 nm. Furthermore, we predict a diffraction efficiency approaching 100%, simply by increasing the number of levels. Such volumetric Si-photonic devices represent a significant advance toward 3D-integrated monolithic photonic chips., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published
2023
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22. Breaking crosstalk limits to dynamic holography using orthogonality of high-dimensional random vectors.

Author

Makey G, Yavuz Ö, Kesim DK, Turnalı A, Elahi P, Ilday S, Tokel O, and Ilday FÖ

Abstract

Holography is the most promising route to true-to-life 3D projections, but the incorporation of complex images with full depth control remains elusive. Digitally synthesised holograms1-7, which do not require real objects to create a hologram, offer the possibility of dynamic projection of 3D video8,9. Extensive efforts aimed 3D holographic projection10-17, however available methods remain limited to creating images on a few planes10-12, over a narrow depth-of-field13,14 or with low resolution15-17. Truly 3D holography also requires full depth control and dynamic projection capabilities, which are hampered by high crosstalk9,18. The fundamental difficulty is in storing all the information necessary to depict a complex 3D image in the 2D form of a hologram without letting projections at different depths contaminate each other. Here, we solve this problem by preshaping the wavefronts to locally reduce Fresnel diffraction to Fourier holography, which allows inclusion of random phase for each depth without altering image projection at that particular depth, but eliminates crosstalk due to near-orthogonality of large-dimensional random vectors. We demonstrate Fresnel holograms that form on-axis with full depth control without any crosstalk, producing large-volume, high-density, dynamic 3D projections with 1000 image planes simultaneously, improving the state-of-the-art12,17 for number of simultaneously created planes by two orders of magnitude. While our proof-of-principle experiments use spatial light modulators, our solution is applicable to all types of holographic media., Competing Interests: Competing interests The authors declare no competing financial interests.

Published
2019
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23. In-chip microstructures and photonic devices fabricated by nonlinear laser lithography deep inside silicon.

Author

Tokel O, Turnali A, Makey G, Elahi P, Çolakoğlu T, Ergeçen E, Yavuz Ö, Hübner R, Borra MZ, Pavlov I, Bek A, Turan R, Kesim DK, Tozburun S, Ilday S, and Ilday FÖ

Abstract

Silicon is an excellent material for microelectronics and integrated photonics1-3 with untapped potential for mid-IR optics4. Despite broad recognition of the importance of the third dimension5,6, current lithography methods do not allow fabrication of photonic devices and functional microelements directly inside silicon chips. Even relatively simple curved geometries cannot be realised with techniques like reactive ion etching. Embedded optical elements, like in glass7, electronic devices, and better electronic-photonic integration are lacking8. Here, we demonstrate laser-based fabrication of complex 3D structures deep inside silicon using 1 µm-sized dots and rod-like structures of adjustable length as basic building blocks. The laser-modified Si has a different optical index than unmodified parts, which enables numerous photonic devices. Optionally, these parts are chemically etched to produce desired 3D shapes. We exemplify a plethora of subsurface, i.e. , " in-chip" microstructures for microfluidic cooling of chips, vias, MEMS, photovoltaic applications and photonic devices that match or surpass the corresponding state-of-the-art device performances.

Published
2017
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24. Rich complex behaviour of self-assembled nanoparticles far from equilibrium.

Author

Ilday S, Makey G, Akguc GB, Yavuz Ö, Tokel O, Pavlov I, Gülseren O, and Ilday FÖ

Abstract

A profoundly fundamental question at the interface between physics and biology remains open: what are the minimum requirements for emergence of complex behaviour from nonliving systems? Here, we address this question and report complex behaviour of tens to thousands of colloidal nanoparticles in a system designed to be as plain as possible: the system is driven far from equilibrium by ultrafast laser pulses that create spatiotemporal temperature gradients, inducing Marangoni flow that drags particles towards aggregation; strong Brownian motion, used as source of fluctuations, opposes aggregation. Nonlinear feedback mechanisms naturally arise between flow, aggregate and Brownian motion, allowing fast external control with minimal intervention. Consequently, complex behaviour, analogous to those seen in living organisms, emerges, whereby aggregates can self-sustain, self-regulate, self-replicate, self-heal and can be transferred from one location to another, all within seconds. Aggregates can comprise only one pattern or bifurcated patterns can coexist, compete, endure or perish.

Published
2017
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25. Portable microfluidic integrated plasmonic platform for pathogen detection.

Author

Tokel O, Yildiz UH, Inci F, Durmus NG, Ekiz OO, Turker B, Cetin C, Rao S, Sridhar K, Natarajan N, Shafiee H, Dana A, and Demirci U

Subjects
Antibodies, Bacterial chemistry, Buffers, Dialysis Solutions, Equipment Design, Humans, Point-of-Care Systems, Colony Count, Microbial instrumentation, Escherichia coli isolation & purification, Lab-On-A-Chip Devices, Staphylococcus aureus isolation & purification, Surface Plasmon Resonance instrumentation
Abstract

Timely detection of infectious agents is critical in early diagnosis and treatment of infectious diseases. Conventional pathogen detection methods, such as enzyme linked immunosorbent assay (ELISA), culturing or polymerase chain reaction (PCR) require long assay times, and complex and expensive instruments, which are not adaptable to point-of-care (POC) needs at resource-constrained as well as primary care settings. Therefore, there is an unmet need to develop simple, rapid, and accurate methods for detection of pathogens at the POC. Here, we present a portable, multiplex, inexpensive microfluidic-integrated surface plasmon resonance (SPR) platform that detects and quantifies bacteria, i.e., Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) rapidly. The platform presented reliable capture and detection of E. coli at concentrations ranging from ~10(5) to 3.2 × 10(7) CFUs/mL in phosphate buffered saline (PBS) and peritoneal dialysis (PD) fluid. The multiplexing and specificity capability of the platform was also tested with S. aureus samples. The presented platform technology could potentially be applicable to capture and detect other pathogens at the POC and primary care settings.

Published
2015
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27. Nanoplasmonic quantitative detection of intact viruses from unprocessed whole blood.

Author

Inci F, Tokel O, Wang S, Gurkan UA, Tasoglu S, Kuritzkes DR, and Demirci U

Subjects
HIV physiology, Humans, Polystyrenes chemistry, Reproducibility of Results, Viral Load, Biosensing Techniques methods, Blood virology, HIV isolation & purification, Nanotechnology methods
Abstract

Infectious diseases such as HIV and hepatitis B pose an omnipresent threat to global health. Reliable, fast, accurate, and sensitive platforms that can be deployed at the point-of-care (POC) in multiple settings, such as airports and offices, for detection of infectious pathogens are essential for the management of epidemics and possible biological attacks. To the best of our knowledge, no viral load technology adaptable to the POC settings exists today due to critical technical and biological challenges. Here, we present for the first time a broadly applicable technology for quantitative, nanoplasmonic-based intact virus detection at clinically relevant concentrations. The sensing platform is based on unique nanoplasmonic properties of nanoparticles utilizing immobilized antibodies to selectively capture rapidly evolving viral subtypes. We demonstrate the capture, detection, and quantification of multiple HIV subtypes (A, B, C, D, E, G, and subtype panel) with high repeatability, sensitivity, and specificity down to 98 ± 39 copies/mL (i.e., HIV subtype D) using spiked whole blood samples and clinical discarded HIV-infected patient whole blood samples validated by the gold standard, i.e., RT-qPCR. This platform technology offers an assay time of 1 h and 10 min (1 h for capture, 10 min for detection and data analysis). The presented platform is also able to capture intact viruses at high efficiency using immuno-surface chemistry approaches directly from whole blood samples without any sample preprocessing steps such as spin-down or sorting. Evidence is presented showing the system to be accurate, repeatable, and reliable. Additionally, the presented platform technology can be broadly adapted to detect other pathogens having reasonably well-described biomarkers by adapting the surface chemistry. Thus, this broadly applicable detection platform holds great promise to be implemented at POC settings, hospitals, and primary care settings.

Published
2013
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