Publikationer av Ilja Sytjugov

Refereegranskade

Artiklar

[1]

H. Ohlin et al., "Comparing metal assisted chemical etching of N and P-type silicon nanostructures," Micro and Nano Engineering, vol. 19, 2023.

[2]

X. Lu et al., "Luminescent solar concentrator efficiency versus edge solar cell coverage," Optics Letters, vol. 48, no. 16, s. 4197-4200, 2023.

[3]

Y. Yang et al., "Plasmon-Enhanced Fluorescence of Single Quantum Dots Immobilized in Optically Coupled Aluminum Nanoholes," Journal of Physical Chemistry Letters, vol. 14, no. 9, s. 2339-2346, 2023.

[4]

A. Samanta et al., "Charge Regulated Diffusion of Silica Nanoparticles into Wood for Flame Retardant Transparent Wood," Advanced Sustainable Systems, vol. 6, no. 4, s. 2100354-2100354, 2022.

[5]

H. Chen et al., "Color-Switchable Nanosilicon Fluorescent Probes," ACS Nano, vol. 16, no. 9, s. 15450-15459, 2022.

[6]

J. Huang et al., "Large-Area Transparent “Quantum Dot Glass” for Building-Integrated Photovoltaics," ACS Photonics, vol. 9, no. 7, s. 2499-2509, 2022.

[7]

H. Chen et al., "Photon Walk in Transparent Wood: Scattering and Absorption in Hierarchically Structured Materials," Advanced Optical Materials, 2022.

[8]

J. Zhou et al., "Low-Cost Synthesis of Silicon Quantum Dots with Near-Unity Internal Quantum Efficiency," Journal of Physical Chemistry Letters, vol. 12, no. 37, s. 8909-8916, 2021.

[9]

A. Samanta et al., "Reversible dual-stimuli responsive chromic transparent wood bio-composites for smart window applications," ACS Applied Materials and Interfaces, vol. 13, s. 3270-3277, 2021.

[10]

I. Sychugov, "Geometry effects on luminescence solar concentrator efficiency : analytical treatment," Applied Optics, vol. 59, no. 19, s. 5715-5722, 2020.

[11]

H. Chen et al., "Refractive index of delignified wood for transparent biocomposites," RSC Advances, vol. 10, s. 40719-40724, 2020.

[12]

A. Fucikova, I. Sychugov och J. Linnros, "The shell matters : one step synthesis of core-shell silicon nanoparticles with room temperature ultranarrow emission linewidth," Faraday discussions, vol. 222, no. 0, s. 135-148, 2020.

[13]

M. O. Nestoklon et al., "Tight-binding calculations of the optical properties of Si nanocrystals in a SiO(2)matrix," Faraday discussions, vol. 222, no. 0, s. 258-273, 2020.

[14]

M. Höglund et al., "Transparent Wood Biocomposites by Fast UV-Curing for Reduced Light-Scattering through Wood/Thiol-ene Interface Design," ACS Applied Materials and Interfaces, vol. 12, no. 41, s. 46914-46922, 2020.

[15]

J. Huang et al., "Triplex Glass Laminates with Silicon Quantum Dots for Luminescent Solar Concentrators," Solar RRL, vol. 4, no. 9, 2020.

[16]

H. K. Gatty et al., "Wafer-level fabrication of individual solid-state nanopores for sensing single DNAs," Nanotechnology, vol. 31, no. 35, 2020.

[17]

J. Zhou et al., "Wafer-scale fabrication of isolated luminescent silicon quantum dots using standard CMOS technology," Nanotechnology, vol. 31, no. 50, 2020.

[18]

I. Sychugov, "Analytical Description of a Luminescent Solar Concentrator Device," Optica, vol. 6, s. 1046-1049, 2019.

[19]

L. Liu et al., "Cation effect on excitons in perovskite nanocrystals from single-dot photoluminescence of CH3NH3PbI3," Physical Review B, vol. 100, no. 19, 2019.

[20]

E. Vasileva et al., "Effect of transparent wood on the polarization degree of light," Optics Letters, vol. 44, no. 12, s. 2962-2965, 2019.

[21]

M. Greben et al., "Non-exponential decay kinetics: Correct assessment and description illustrated by slow luminescence of Si nanostructures," Applied spectroscopy reviews (Softcover ed.), vol. 54, s. 758-801, 2019.

[22]

I. Sychugov, M. Zhang och J. Linnros, "Non-stationary analysis of molecule capture and translocation in nanopore arrays," Journal of Chemical Physics, vol. 150, no. 8, 2019.

[23]

L. Liu et al., "Photodegradation of Organometal Hybrid Perovskite Nanocrystals : Clarifying the Role of Oxygen by Single-Dot Photoluminescence," Journal of Physical Chemistry Letters, vol. 10, no. 4, s. 864-869, 2019.

[24]

J. Zhou et al., "Photoluminescence Intensity Enhancement of Single Silicon Quantum Dots on a Metal Membrane with a Spacer," Physica Status Solidi (A) Applications and Materials Science, 2019.

[25]

L. Liu et al., "Size-Dependent Phase Transition in Perovskite Nanocrystals," Journal of Physical Chemistry Letters, vol. 10, no. 18, s. 5451-5457, 2019.

[26]

H. Chen et al., "Thickness Dependence of Optical Transmittance of Transparent Wood : Chemical Modification Effects," ACS Applied Materials and Interfaces, vol. 11, no. 38, s. 35451-35457, 2019.

[27]

T. Chulapakorn et al., "Impact of H-uptake by forming gas annealing and ion implantation on photoluminescence of Si-nanoparticles," Physica Status Solidi (a) applications and materials science, vol. 215, no. 3, 2018.

[28]

E. Vasileva et al., "Light Scattering by Structurally Anisotropic Media : A Benchmark with Transparent Wood," Advanced Optical Materials, vol. 6, no. 23, 2018.

[29]

T. Chulapakorn et al., "Luminescence of silicon nanoparticles from oxygen implanted silicon," Materials Science in Semiconductor Processing, vol. 86, s. 18-22, 2018.

[30]

Y. Li et al., "Optically Transparent Wood : Recent Progress, Opportunities, and Challenges," Advanced Optical Materials, vol. 6, no. 14, 2018.

[31]

F. Pevere et al., "Rapid Trapping as the Origin of Nonradiative Recombination in Semiconductor Nanocrystals," ACS Photonics, vol. 5, no. 8, s. 2990-2996, 2018.

[32]

M. Zhang et al., "Thermophoresis-Controlled Size-Dependent DNA Translocation through an Array of Nanopores," ACS Nano, vol. 12, no. 5, s. 4574-4582, 2018.

[33]

F. Pevere et al., "X-ray radiation hardness and influence on blinking in Si and CdSe quantum dots," Applied Physics Letters, vol. 113, no. 25, 2018.

[34]

J.-W. Luo et al., "Absence of redshift in the direct bandgap of silicon nanocrystals with reduced size," Nature Nanotechnology, vol. 12, no. 10, s. 930-932, 2017.

[35]

G. Omanakuttan et al., "Epitaxial lateral overgrowth of GaxIn1-xP toward direct GaxIn1-xP/Si heterojunction," Physica Status Solidi (a) applications and materials science, vol. 214, no. 3, 2017.

[36]

T. Chulapakorn et al., "Influence of swift heavy ion irradiation on the photoluminescence of Si-nanoparticles and defects in SiO2," Nanotechnology, vol. 28, 2017.

[37]

E. Vasileva et al., "Lasing from Organic Dye Molecules Embedded in Transparent Wood," Advanced Optical Materials, vol. 5, no. 10, 2017.

[38]

A. Marinins et al., "Light Converting Polymer/Si Nanocrystal Composites with Stable 60-70% Quantum Efficiency and their Glass Laminates," ACS Applied Materials and Interfaces, vol. 9, no. 36, s. 30267-30272, 2017.

[39]

Y. Li et al., "Luminescent Transparent Wood," Advanced Optical Materials, vol. 5, no. 1, 2017.

[40]

I. Sychugov, J. Valenta och J. Linnros, "Probing silicon quantum dots by single-dot techniques," Nanotechnology, vol. 28, no. 7, 2017.

[41]

Y. Hormozan, I. Sychugov och J. Linnros, "High-resolution x-ray imaging using a structured scintillator," Medical physics (Lancaster), vol. 43, no. 2, s. 696-701, 2016.

[42]

T. Chulapakorn et al., "MeV ion irradiation effects on the luminescence properties of Si-implanted SiO2-thin films," Physica Status Solidi (C) Current Topics in Solid State Physics, vol. 13, no. 10-12, s. 921-926, 2016.

[43]

A. Marinins et al., "Photostable Polymer/Si Nanocrystal Bulk Hybrids with Tunable Photoluminescence," ACS Photonics, vol. 3, no. 9, s. 1575-1580, 2016.

[44]

I. Sychugov et al., "Single-dot absorption spectroscopy and theory of silicon nanocrystals," Physical Review B, vol. 93, no. 16, 2016.

[45]

I. Sychugov et al., "Strong Absorption Enhancement in Si Nanorods," Nano letters (Print), vol. 16, no. 12, s. 7937-7941, 2016.

[46]

F. Pevere et al., "Biexciton Emission as a Probe of Auger Recombination in Individual Silicon Nanocrystals," The Journal of Physical Chemistry C, vol. 119, no. 13, s. 7499-7505, 2015.

[47]

F. Pevere et al., "Effect of X-ray irradiation on the blinking of single silicon nanocrystals," Physica Status Solidi (a) applications and materials science, vol. 212, no. 12, 2015.

[48]

Z. Yang et al., "Evolution of the Ultrafast Photoluminescence of Colloidal Silicon Nanocrystals with Changing Surface Chemistry," ACS Photonics, vol. 2, no. 5, s. 595-605, 2015.

[49]

T. Schmidt et al., "Nanopore arrays in a silicon membrane for parallel single-molecule detection : fabrication," Nanotechnology, vol. 26, no. 31, 2015.

[50]

M. Zhang et al., "Nanopore arrays in a silicon membrane for parallel single-molecule detection : DNA translocation," Nanotechnology, vol. 26, no. 31, 2015.

[51]

F. Sangghaleh et al., "Near-Unity Internal Quantum Efficiency of Luminescent Silicon Nanocrystals with Ligand Passivation.," ACS Nano, vol. 9, no. 7, s. 7097-7104, 2015.

[52]

T. Chulapakorn et al., "Si-nanoparticle synthesis using ion implantation and MeV ion irradiation," Physica Status Solidi (C) Current Topics in Solid State Physics, 2015.

[53]

B. Bruhn et al., "Blinking Statistics and Excitation-Dependent Luminescence Yield in Si and CdSe Nanocrystals," The Journal of Physical Chemistry C, vol. 118, no. 4, s. 2202-2208, 2014.

[54]

M. Zhang et al., "Oxidation of nanopores in a silicon membrane : self-limiting formation of sub-10nm circular openings," Nanotechnology, vol. 25, no. 35, s. 355302, 2014.

[55]

I. Sychugov et al., "Ultranarrow Luminescence Linewidth of Silicon Nanocrystals and Influence of Matrix," ACS Photonics, vol. 1, no. 10, s. 998-1005, 2014.

[56]

B. Bruhn et al., "Transition from silicon nanowires to isolated quantum dots : Optical and structural evolution," Physical Review B. Condensed Matter and Materials Physics, vol. 87, no. 4, s. 045404, 2013.

[57]

I. Sychugov et al., "Exciton localization in doped Si nanocrystals from single dot spectroscopy studies," Physical Review B. Condensed Matter and Materials Physics, vol. 86, no. 7, s. 075311, 2012.

[58]

I. Sychugov et al., "Photoluminescence measurements of zero-phonon optical transitions in silicon nanocrystals," Physical Review B. Condensed Matter and Materials Physics, vol. 84, no. 12, s. 125326, 2011.

[59]

I. Sychugov, Y. Nakayama och K. Mitsuishi, "Manifold Enhancement of Electron Beam Induced Deposition Rate at Grazing Incidence," Nanotechnology, vol. 21, no. 2, s. 025303, 2010.

[60]

I. Sychugov, Y. Nakayama och K. Mitsuishi, "Sub-10 nm crystalline silicon nanostructures by electron beam induced deposition lithography," Nanotechnology, vol. 21, no. 28, s. 285307, 2010.

[61]

I. Sychugov, Y. Nakayama och K. Mitsuishi, "Composition Control of Electron Beam Induced Nanodeposits by Surface Pretreatment and Beam Focusing," The Journal of Physical Chemistry C, vol. 113, no. 52, s. 21516-21519, 2009.

[62]

I. Sychugov, Y. Nakayama och K. Mitsuishi, "Measuring interface electrostatic potential and surface charge in a scanning electron microscope," Journal of Vacuum Science & Technology B, vol. 27, no. 6, s. 2357-2360, 2009.

[63]

H. Omi et al., "New Microscope Combines Optical and Electrical Excitation into a Single Scanning Tunneling Microscope Unit for Simultaneous Characterization of Near-Field Luminescence from Individual Nanostructures," Kenbikyo, vol. 44, s. 174, 2009.

[64]

I. Sychugov et al., "Optical and Electrical Characterization at the Nanoscale by a Transparent Tip of a Scanning Tunneling Microscope," Nanotechnology, vol. 20, no. 14, s. 145706, 2009.

[65]

I. Sychugov et al., "Modeling Tip Performance for Combined STM-luminescence and aperture-SNOM Scanning Probe : Spatial Resolution and Collection Efficiency," Applied Surface Science, vol. 254, no. 23, s. 7861-7863, 2008.

[66]

I. Sychugov, H. Omi och Y. Kobayashi, "On the Role of Substrate in Light Harvesting Experiments," Optics Letters, vol. 33, no. 16, s. 1807-1809, 2008.

[67]

I. Sychugov et al., "Effect of photonic bandgap on luminescence from silicon nanocrystals," Optics Letters, vol. 32, no. 13, s. 1878-1880, 2007.

[68]

D. Sprunken et al., "Influence of the Local Environment on Determining Aspect-Ratio Distributions of Gold Nanorods in Solution Using Gans Theory," The Journal of Physical Chemistry C, vol. 111, s. 14299, 2007.

[69]

N. Elfström et al., "Surface Charge Sensitivity of Silicon Nanowires : Size Dependence," Nano letters (Print), vol. 7, no. 9, s. 2608-2612, 2007.

[70]

I. Sychugov et al., "Effect of substrate proximity on luminescence yield from Si nanocrystals," Applied Physics Letters, vol. 89, no. 11, s. 111124, 2006.

[71]

I. Sychugov et al., "Light emission from silicon nanocrystals: probing a single quantum do," Applied Surface Science, vol. 252, no. 15, s. 5249-5253, 2006.

[72]

I. Sychugov et al., "Structural imaging of a Si quantum dot: Towards combined PL and TEM characterization," Journal of Luminescence, vol. 121, no. 2, s. 353, 2006.

[73]

I. Sychugov et al., "Luminescence blinking of a Si quantum dot in a SiO₂ shell," Physical Review B. Condensed Matter and Materials Physics, vol. 71, no. 11, s. 115331-1-115331-5, 2005.

[74]

I. Sychugov et al., "Narrow luminescence linewidth of a silicon quantum dot," Physical Review Letters, vol. 94, no. 8, s. 087405 (1)-087405 (4), 2005.

[75]

I. Sychugov et al., "Single dot optical spectroscopy of silicon nanocrystals: Low temperature measurements," Optical materials (Amsterdam), vol. 27, no. 5, s. 973-976, 2005.

Konferensbidrag

[76]

A. Marinins et al., "All-Optical Intensity Modulation in Polymer Waveguides Doped with Si Quantum Dots," i 2018 conference on lasers and electro-optics (CLEO), 2018.

[77]

A. Marinins et al., "All-optical intensity modulation in polymer waveguides doped with si quantum dots," i Optics InfoBase Conference Papers, 2018.

[78]

S. Popov et al., "Polymer photonics and nano-materials for optical communication," i 2018 17TH WORKSHOP ON INFORMATION OPTICS (WIO), 2018.

[79]

G. Omanakuttan et al., "Epitaxial lateral overgrowth of GaxIn1-xP towards coherent GaxIn1-xP/Si heterojunction by hydride vapor phase epitaxy," i 2016 Compound Semiconductor Week, CSW 2016 - Includes 28th International Conference on Indium Phosphide and Related Materials, IPRM and 43rd International Symposium on Compound Semiconductors, ISCS 2016, 2016.

[80]

I. Sychugov et al., "Luminescent silicon nanocrystals as downconverters for photovoltaic and lighting applications," i Asia Communications and Photonics Conference, ACP, 2016.

[81]

E. Vasileva et al., "Transparent wood as a novel material for non-cavity laser," i 2016 Asia Communications and Photonics Conference, ACP 2016, 2016.

[82]

M. Zhang et al., "Optical detection of two-color-fluorophore barcode for nanopore DNA sensing," i Conference on Nanotechnology VII, MAY 04-06, 2015, Barcelona, SPAIN, 2015.

[83]

I. Sychugov, "Luminescent silicon nanocrystals as downconverters for photovoltaic and lighting applications," i Optics InfoBase Conference Papers, 2014.

[84]

E. Vasileva et al., "Transparent wood as a novel material for non-cavity laser," i Optics InfoBase Conference Papers, 2014.

[85]

F. Sangghaleh et al., "Optical absorption cross section and quantum efficiency of a single silicon quantum dot," i Nanotechnology VI, 2013, s. 876607.

Kapitel i böcker

[86]

I. Sychugov och J. Linnros, "Optical Properties of a Silicon Nanocrystal," i Nanocrystals : Properties, Preparation and Applications, Hongquig Hu red., New York : Nova Science, 2009, s. 197-216.

Icke refereegranskade

Artiklar

[87]

L. Berglund et al., "Modification of transparent wood for photonics functions," Abstracts of Papers of the American Chemical Society, vol. 255, 2018.

Avhandlingar

[88]

I. Sychugov, "Synthesis and properties of single luminescent silicon quantum dots," Doktorsavhandling Stockholm : KTH, Trita-ICT/MAP, 2007:1, 2006.

Övriga

[89]

B. Bruhn et al., "Transition fromsilicon nanowires to isolated quantum dots : Optical and structural evolution," (Manuskript).

[90]

F. Sangghaleh et al., "Non-radiative decay in Si/SiO₂quantum dots in transition from dark to bright exciton states," (Manuskript).

Patent

[91]

I. Sychugov, "Synthesized thin shell passivated silicon nanocrystals with a narrow photoluminescence linewidth," us 10287494 B2 (2019-05-14), 2019.

Senaste synkning med DiVA:

2024-04-16 00:15:02