NanoFrazor Library
Explore our NanoFrazor library
We are thrilled to provide you with a collection of references to NanoFrazor related literature, including fact sheets, research papers, whitepapers, posters and other documents. Our poster library is designed to serve as a valuable resource for anyone seeking information about our NanoFrazor systems, their applications, and the technology behind it. Not only do we publish our own information here, but we also feature joint documents produced with partners and papers by other authors using our systems. Some links may lead to external sources.
How to use our library
- Use the search bar to find application-related content, with terms like “Advanced Packaging”, “Quantum Devices”, “Micro-optics” and many more.
- Find documents related to products and our technologies with the “tags” filter.
- The categories indicate the type of publication, e.g., Fact Sheets.
Title | Description | Category | Tags | Publisher | Published | Link | hf:doc_categories | hf:doc_tags | hf:doc_author | |
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A New Method of AFM‐Based Nanolithography Using Frequency Enhanced Electrochemical Pressure Solution Etching | This paper investigates Frequency Enhanced Electrochemical Pressure Solution (FEEPS) as a novel nanolithography method for etching silica surfaces with an AFM tip. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials Technologies | March, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-materials-technologies | ||
Achieving Reliable and Ultrafast Memristors via Artificial Filaments in Silk Fibroin | This paper investigates using biocompatible silk fibroin (SF) as a switching medium in silver/SF/gold (Ag/SF/Au) memristors. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials | November, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-materials | ||
Advanced MEMS/NEMS Fabrication and Sensors | This book introduces new and unique fabrication, micromachining, and integration manufacturing methods for MEMS and NEMS devices, as well as novel nanomaterials for sensor fabrications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | nature | October, 2021 | scientific-paper | nanofrazor thermal-scanning-probe | nature | ||
Anisotropic Particle Fabrication Using Thermal Scanning Probe Lithography | Nanoparticles’ optical and physicochemical properties are modulated via a novel, efficient nanolithographic method producing diverse monodispersed shapes, ensuring precise size, shape, and material control. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Materials & Interfaces | April, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-materials-interfaces | ||
Bilayer Lift-Off for NanoFrazor Lithography | Explore bilayer lift-off with NanoFrazor lithography, addressing advantages, process details, and examples, including high-quality contacts and structures as small as 7 nm. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | July, 2023 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
Chemically Amplified, Dry-Develop Poly(aldehyde) Photoresist | The effects of incorporating a base quencher into a poly(phthalaldehyde-co-propanal) photoresist to enhance the performance of dry-develop resist in a direct-write UV lithography tool. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ECS Journal of Solid State Science and Technology | May, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | ecs-journal-of-solid-state-science-and-technology | ||
Combining thermal scanning probe lithography and dry etching for grayscale nanopattern amplification | A novel method for amplifying the depth of grayscale nanopatterns in dielectric materials like SiO2 using a combination of t-SPL and optimized dry etching techniques. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Microsystems & Nanoengineering | February, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | microsystems-nanoengineering | ||
Complete logic operations in an ambipolar tellurium homojunction via non-invasive scanning probe lithography | Low-dimensional semiconductors, like tellurium nanoribbons, enable miniaturized logic devices via ambipolar conduction. Non-invasive lithography creates transistors performing all seven basic logic operations. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Device | September, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | device | ||
Cost and Time Effective Lithography of Reusable Millimeter Size Bone Tissue Replicas With Sub-15 nm Feature Size on A Biocompatible Polymer | Bio-tSPL enables cost-effective, high-precision fabrication of reusable, biocompatible 3D bone tissue replicas for stem cell culture, tissue-mimetic biofunctionalization, drug testing, and regenerative medicine. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Functional Materials | February, 2021 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-functional-materials | ||
Damage-free nanolithography enabling superior device performance | Thermal scanning probe lithography enabled by NanoFrazor helps to fabricate devices with superior performance due to its damage-free patterning principle. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | September, 2024 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
Deterministic Assembly of Single Sub-20 nm Functional Nanoparticles Using a Thermally Modified Template with a Scanning Nanoprobe | A deterministic technique uses hot scanning nanoprobes to assemble sub-20 nm nanoparticles, including quantum dots, into 2D arrays and complex nanostructures for various applications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials | November, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-materials | ||
Deterministic Deposition of Nanoparticles with Sub-10 nm Resolution | A nanofluidic slit method enables precise nanoparticle placement using geometry-induced energy landscapes, achieving 8 nm accuracy with electrostatic trapping, focusing, and adhesive contact. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nano Letters | November, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | nano-letters | ||
Deterministic grayscale nanotopography to engineer mobilities in strained MoS2 FETs | Engineered nanotopography induces tensile strain in MoS2 FETs, significantly enhancing carrier mobility and on-state current, promising advancements for 2D material-based electronics. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | nature communications | August, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | nature-communications | ||
Deterministic Thermal Sculpting of Large‐Scale 2D Semiconductor Nanocircuits | A scalable nanolithography method enables precise engineering of 2D TMD nanocircuits, like MoS2, for ultra-compact electronic and photonic devices with controlled thickness and excellent conductivity. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials Interfaces | November, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-materials-interfaces | ||
Direct Heat-Induced Patterning of Inorganic Nanomaterials | The HIPIN method uses heat-induced ligand transformation to pattern nanomaterials, enabling direct, wavelength-diverse lithography for advanced manufacturing of quantum dot electronic and optoelectronic devices. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Journal of the American Chemical Society | June, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | journal-of-the-american-chemical-society | ||
Direct Patterning of Metal Chalcogenide Semiconductor Materials | A low-cost, high-resolution direct patterning method using metal-organic precursors enables fabrication of 2D/3D semiconductor structures with sub-50 nm resolution for various nanodevices. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Functional Materials | May, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-functional-materials | ||
Edge-Contact MoS2 Transistors Fabricated Using Thermal Scanning Probe Lithography | Thermal scanning probe lithography (t-SPL) fabricates MoS2-based field-effect transistors, achieving high on/off ratios without damaging materials, offering a gentle alternative to electron beam lithography. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Materials & Interfaces | September, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-materials-interfaces | ||
Exploiting Thermal Scanning Probe Lithography for the Fabrication of Micro and Nano Electronic Devices | Thermal scanning probe lithography enables fast fabrication of micro/nano structures with 100nm resolution, enhancing electronic performance through gold coating and resistivity characterization. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | 2023 International Conference on Optical MEMS and Nanophotonics (OMN) and SBFoton International Optics and Photonics Conference (SBFoton IOPC) | September, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | 2023-international-conference-on-optical-mems-and-nanophotonics-omn-and-sbfoton-international-optics-and-photonics-conference-sbfoton-iopc | ||
Fabrication of a hybrid device for the integration of light-triggered proton pumps | A novel method for fabricating a hybrid device that integrates light-triggered proton pumps into a network of nanochannels for applications in directed ion transport. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Micro and Nano Engineering (ScienceDirect) | June, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | micro-and-nano-engineering-science-direct | ||
Fabrication of spin-orbit logic devices by thermal nanolithography | This work explores thermal scanning probe lithography (t-SPL) to fabricate devices with sub-50 nm features, enabling energy-efficient non-volatile computing and memory devices using 2D materials. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | April, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | ||||
Far-Field and Non-Intrusive Optical Mapping of Nanoscale Structures | This study analyzes far-field optical mapping of nanostructures using CLSM and radially polarized light, achieving 74 nm resolution for LDOS, crucial for high-density optical storage. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nanomaterials | July, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | nanomaterials | ||
Fraxicon for Optical Applications with Aperture ∼1 mm: Characterisation Study | This paper describes the fabrication and characterisation of a flat conical lens (fraxicon) with a diameter of 0.2 mm for use in miniaturised optical applications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nanomaterials | January, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | nanomaterials | ||
Freeform nanostructuring of hexagonal boron nitride | Hexagonal boron nitride (hBN), now available as atomically smooth flakes, offers unique properties in optoelectronics and nanoelectronics. Researchers demonstrate freeform nanostructuring for advanced device architectures. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | arXiv Physics/Optics | May, 2021 | scientific-paper | nanofrazor thermal-scanning-probe | arxiv-physics-optics | ||
Generating smooth potential landscapes with thermal scanning-probe lithography | Scanning probe microscopy with a NanoFrazor achieves atomic precision, enabling controlled material manipulation and high-resolution lithography, with broad applications in photonics, electronics, and nanomaterials science. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Journal of Physics: Materials | November, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | journal-of-physics-materials | ||
High-resolution patterning of nanowire-based quantum devices with the NanoFrazor | The NanoFrazor offers a unique patterning solution, combining t-SPL and laser mix and match lithography. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | September, 2024 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
High-sensitive two-dimensional PbI2 photodetector with ultrashort channel | This study reports a PbI2-based photodetector with the highest responsivity (172 A/W) achieved, using thermal scanning probe lithography for ultrashort channel fabrication to enhance performance. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Frontiers of Physics | July, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | frontiers-of-physics | ||
High-throughput protein nanopatterning | This work demonstrates high-throughput, sub-10 nm enzyme nanopatterning using thermochemical scanning probe lithography (tc-SPL), advancing bio-nanotechnology and molecular-level biological studies. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Faraday Discussions | March, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | faraday-discussions | ||
Interferometric scattering of a single plasmonic nanoparticle cluster assembled in a nanostructured template | Examining single Au nanoparticle cluster light scattering on nanostructured substrates, revealing two substrate effects via Green’s tensor theory for plasmonic nanostructure spectral interpretation. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Optics Express | April, 2021 | scientific-paper | nanofrazor thermal-scanning-probe | optics-express | ||
Laser Heat-Mode Lithography: Principle and Methods | This book explains laser heat-mode lithography, covering principles, system design, feature size manipulation, and applications, offering a versatile, simple, and tunable approach for nanofabrication. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | November, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | ||||
Monolayer MoS2 Nanoribbon Transistors Fabricated by Scanning Probe Lithography | This work demonstrates the fabrication of 30 nm monolayer MoS2 nanoribbon field-effect transistors using scanning probe lithography, achieving high performance with channel widths below 100 … | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nano Letters | February, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | nano-letters | ||
Multi‐ and Gray‐Scale Thermal Lithography of Silk Fibroin as Water‐Developable Resist for Micro and Nanofabrication | This paper describes a hybrid thermal lithography method that uses silk fibroin as a water-developable resist for the fabrication of micro and nanoscale structures. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Science | January, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-science | ||
Nano-Ironing van der Waals Heterostructures toward Electrically Controlled Quantum Dots | Nanoironing van der Waals heterostructures enhances interface quality, significantly improving electrical performance and enabling controlled quantum dot formation for advanced quantum technologies. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Materials & Interfaces | June, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-materials-interfaces | ||
Nano/Microscale Thermal Field Distribution: Conducting Thermal Decomposition of Pyrolytic-Type Polymer by Heated AFM Probes | This study investigates temperature distribution between heated AFM tips and materials, using PPA film to create programmable nano/microscale pyramid structures for scanning thermal microscopy applications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nanomaterials | March, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | nanomaterials | ||
Nanofabrication of graphene field-effect transistors by thermal scanning probe lithography | Thermal scanning probe lithography (t-SPL) shows promise for scalable nanofabrication in nanoelectronics. It produces high-performance graphene-based transistors with simplified processing, reducing time and cost. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | APL Materials | January, 2021 | scientific-paper | nanofrazor thermal-scanning-probe | apl-materials | ||
Nanofluidic rocking Brownian motors | Creating precise nanofluidic slits, utilizing electrostatic forces and oscillating fields, enables controlled transport of nanoparticles, demonstrated with 60nm gold spheres and efficient sorting of particles. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Science | March, 2018 | scientific-paper | nanofrazor thermal-scanning-probe | science | ||
NanoFrazor | The NanoFrazor takes nanofabrication to the next level. Building on decades of research and development, the NanoFrazor brings thermal scanning probe lithography (t-SPL) into your … | Fact Sheet | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments, Heidelberg Instruments Nano | July, 2024 | fact-sheet | nanofrazor thermal-scanning-probe | heidelberg-instruments heidelberg-instruments-nano | ||
NanoFrazor Explore Nanofabrication Tool | Thermal scanning probe lithography tool with a direct laser sublimation and grayscale modules. | Fact Sheet | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments | March, 2022 | fact-sheet | nanofrazor thermal-scanning-probe | heidelberg-instruments | ||
NanoFrazor for Direct Nanoscale Chemical Conversion of Materials | Chemical conversion using a thermal scanning probe can be used to make biosensors with advanced architecture and tailor surface chemistry to create nanostructures. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | August, 2024 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
NanoFrazor Scholar Nanofabrication Tool | Table-top thermal scanning probe lithography system with in-situ AFM imaging, compact and compatible with glovebox. | Fact Sheet | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments | March, 2022 | fact-sheet | nanofrazor thermal-scanning-probe | heidelberg-instruments | ||
Nanometer scale resolution, multi-channel separation of spherical particles in a rocking ratchet with increasing barrier heights | This nanoparticle size-separation device uses a nanofluidic Brownian motor with electrostatic barriers, achieving a separation resolution of approximately 2 nm for gold particles. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Physical Review Applied | July, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | physical-review-applied | ||
Nanopatterning of 2D materials by block copolymer self-assembly | Nanopatterning using block copolymer (BCP) self-assembly is a promising way to advancements in applications ranging from water treatment technologies to energy-efficient devices. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Technical University of Denmark (DTU) | August, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | technical-university-of-denmark-dtu | ||
Novel Mixed-Dimensional hBN-Passivated Silicon Nanowire Reconfigurable Field Effect Transistors: Fabrication and Characterization | This work demonstrates a reconfigurable field-effect transistor (RFET) combining a Si nanowire with a 2D hBN dielectric, improving electrical characteristics and enabling dynamic polarity control. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Materials & Interfaces | August, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-materials-interfaces | ||
Optical Fourier surfaces | Thermal Scanning Probe Lithography and templating creating optical surfaces containing multiple specified sinusoids, enabling advanced diffractive optics, photonics, and applications in emerging photonics fields. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments, nature | June, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | heidelberg-instruments nature | ||
Optically Inspired Nanomagnonics with Nonreciprocal Spin Waves in Synthetic Antiferromagnets | A versatile platform utilizes spin waves for optically inspired wave-based processing, advancing nanoscale devices with wavefront engineering, focusing, interference, and unique properties. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials | January, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-materials | ||
Oxidation and Thermal Scanning Probe Lithography for High-Resolution Nanopatterning and Nanodevices | Scanning probe lithography (SPL) offers high resolution, precise positioning, and material versatility, but its throughput limitations can be addressed through mix-and-match lithography strategies. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Electrical Atomic Force Microscopy for Nanoelectronics | August, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | electrical-atomic-force-microscopy-for-nanoelectronics | ||
Patterning metal contacts on monolayer MoS2 with vanishing Schottky barriers using thermal nanolithography | Thermal Scanning Probe Lithography enables precise metal electrode patterning on 2D semiconductors like MoS2, improving device performance with vanishing Schottky barriers and exceptional properties. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | nature electronics | January, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | nature-electronics | ||
Phase masks for electron microscopy fabricated by thermal scanning probe lithography | Silicon-nitride phase masks are fabricated using thermal scanning probe lithography, avoiding ion implantation, offering high accuracy, and generating electron vortex and Bessel beams. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Micron | October, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | micron | ||
Phase Nanoengineering via Thermal Scanning Probe Lithography and Direct Laser Writing | Nanomaterials derive unique properties from their nanostructure. A perspective explores advanced nanofabrication techniques to modify properties in condensed matter systems, discussing applications and future prospects. | Scientific Paper | Direct Writing, DWL 66+, NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials Technologies | August, 2023 | scientific-paper | direct-writing dwl-66 nanofrazor thermal-scanning-probe | advanced-materials-technologies | ||
Placement of Biological Membrane Patches in a Nanofluidic Gap With Control Over Position and Orientation | Purple membranes from Halobacterium salinarum are precisely positioned and oriented in nanofluidic confinement for integration into light-driven nanoscale hybrid devices. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials Interfaces | July, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-materials-interfaces | ||
Prospects of nano-lithographic tools for the fabrication of surface-enhanced Raman spectroscopy (SERS) substrates | This review discusses and compares different lithographic techniques for fabricating SERS substrates, highlighting their strengths and limitations, and explores their potential for commercial applications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Micro and Nano Engineering (ScienceDirect) | June, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | micro-and-nano-engineering-science-direct | ||
Recent Advances in Direct Optical Patterning of Inorganic Materials and Devices | Direct patterning technology enables cost-effective design and production of devices, enhancing the fabrication of inorganic materials for optoelectronic, electronic, and energy applications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Physics Research | August, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-physics-research | ||
Replication of a Tissue Microenvironment by Thermal Scanning Probe Lithography | Thermal scanning probe lithography (t-SPL) efficiently creates biocompatible nanoscale topographies for cell culture, enabling rapid prototyping of substrates for studying cell-matrix interactions. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Materials & Interfaces | May, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-materials-interfaces | ||
Scanning Probe Lithography: State-of-the-Art and Future Perspectives | Scanning probe lithography (SPL) is a promising nanofabrication technique for nanoelectronics, data storage, and bioengineering, though it is still mainly used for prototyping. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Micromachines | January, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | micromachines | ||
Scanning Probe Thermometry to study Thermoelectricity and Dissipation at Nanoscale Junctions | This thesis explores heat transport and dissipation in nanoelectronics using high-resolution scanning probe thermometry, revealing nanoscale thermal phenomena, defects, and thermoelectric effects. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ETH Zürich | August, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | eth-zurich | ||
Shaping Interfaces for Manipulation and Imaging of Nano-Objects in Nanofluidic Confinement | This study demonstrates nanoscale particle manipulation using nanofluidic slits, thermal scanning probe lithography, and electrostatic interactions for sorting, trapping, and surface charge modulation applications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ETH Zürich | January, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | eth-zurich | ||
Single CdSe Quantum Dots Positioned in Nanostructured Heterogeneous Templates: Implications for High-Precision Nanoassembly | This work develops a multiphysical strategy for precise assembly of colloidal quantum dots using nanostructured templates, controlling electric fields, surface energy, and topography. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Nano Materials | April, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-nano-materials | ||
Spatial defects nanoengineering for bipolar conductivity in MoS2 | Controlling defects in monolayer MoS2 using thermochemical scanning probe lithography enables precise p- and n-type doping, vital for nanoelectronics, p-n junctions, and high rectification ratios. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | nature communications | July, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | nature-communications | ||
Spectral tuning of Bloch Surface Wave resonances by light-controlled optical anisotropy | This work demonstrates dynamic control of resonant modes in a 2D bull’s eye cavity using optically-induced anisotropy, enabling precise tuning in metasurface-based optics. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nanophotonics | February, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | nanophotonics | ||
Structurally and morphologically engineered chalcogenide materials for optical and photonic devices | This paper explores advanced techniques like multiphoton lithography and thermal scanning probe lithography for patterning chalcogenide materials, enabling nanoscale features and functional photonic devices. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Journal of Optical Microsystems | January, 2021 | scientific-paper | nanofrazor thermal-scanning-probe | journal-of-optical-microsystems | ||
Sub-10 nm Resolution Patterning of Pockets for Enzyme Immobilization with Independent Density and Quasi-3D Topography Control | The study demonstrates thermochemical scanning probe lithography (tc-SPL) for precise enzyme nanopatterning on polymer surfaces, achieving single-enzyme resolution, high throughput, and controlled enzyme density. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Materials & Interfaces | October, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-materials-interfaces | ||
Tailored Micromagnet Sorting Gate for Simultaneous Multiple Cell Screening in Portable Magnetophoretic Cell‐On‐Chip Platforms | Novel technique for selectively sorting magnetic carriers and cells using a multi-notched disk micromagnet, enabling precise manipulation even in low magnetic fields. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Functional Materials | March, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-functional-materials | ||
The Lithographer – Quantum Issue | The Quantum Issue of The Lithographer, issued Fall 2020 Topics include: Maskless Aligners, Grayscale, 2D Materials, Quantum Technology | The Lithographer | Direct Writing, Grayscale, NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments | October, 2020 | the-lithographer | direct-writing grayscale nanofrazor thermal-scanning-probe | heidelberg-instruments | ||
The Potential of Combining Thermal Scanning Probes and Phase-Change Materials for Tunable Metasurfaces | Metasurfaces enable versatile optical wavefront control; active phase-change materials like germanium telluride offer compact, reconfigurable near-infrared metasurfaces, avoiding typical limitations. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Optical Materials | October, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-optical-materials | ||
Thermal nanoconversion of ferromagnetic nanoislands | This paper examines the use of thermal nanoconversion (TNC) to modify the magnetic properties of nickel-iron (Ni80Fe20) nanoislands. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Applied Physics Letters | March, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | applied-physics-letters | ||
Thermal scanning probe and laser lithography for patterning nanowire based quantum devices | The NanoFrazor combines thermal scanning probe and laser writing lithography to fabricate InSb nanowire quantum devices, achieving quasi-ballistic transport with reduced fabrication-induced disorder. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nanotechnology | April, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | nanotechnology | ||
Thermal scanning probe lithography | Thermal scanning probe lithography is a powerful nanofabrication method with 10 nm lateral resolution and 1 nm depth resolution, applicable in biomedicine, nanomagnetism, and nanoelectronics. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | nature reviews methods primer | May, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | nature-reviews-methods-primer | ||
Thermal scanning probe lithography – a review | Review of Thermal Scanning Probe Lithography (t-SPL) covering its capabilities for high-resolution nanolithography and material interactions, providing insights for nanofabrication and material science challenges. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments, Microsystems & Nanoengineering (nature) | April, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | heidelberg-instruments microsystems-nanoengineering-nature | ||
Thermal scanning probe lithography using Parylene C as thermal resist | Thermal scanning probe lithography with Parylene C as a thermal resist enables high-resolution (∼40 nm) patterning and direct pattern transfer using deep reactive ion etching. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Micro & Nano Letters | February, 2022 | scientific-paper | nanofrazor thermal-scanning-probe | micro-nano-letters | ||
Thermal Scanning-Probe Lithography for Broad-Band On-Demand Plasmonic Nanostructures on Transparent Substrates | Thermal scanning-probe lithography (t-SPL) enables high-resolution nanolithography on transparent substrates with conductive oxide films, creating tunable plasmonic nanostructures for nanophotonics and sensing applications. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | ACS Applied Nano Materials | October, 2023 | scientific-paper | nanofrazor thermal-scanning-probe | acs-applied-nano-materials | ||
Thermomechanical Nanocutting of 2D Materials | A thermomechanical indentation technique enables precise cutting of monolayer 2D with 20 nm resolution, offering potential for electronic and photonic nanodevice fabrication. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Advanced Materials | June, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | advanced-materials | ||
Thermomechanical Nanostraining of Two-Dimensional Materials | Nanoindentation via thermomechanical scanning probe allows precise, nanoscale strain engineering in 2D materials like MoS2 and graphene, achieving modulated bandgaps and investigating localized strain effects. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nano Letters | October, 2020 | scientific-paper | nanofrazor thermal-scanning-probe | nano-letters | ||
Tip-Based Nanomachining on Thin Films: A Mini Review | Coming soon. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Nanomanufacturing and Metrology | September, 2021 | scientific-paper | nanofrazor thermal-scanning-probe | nanomanufacturing-and-metrology | ||
Transistors platform for rapid and parallel detection of multiple pathogens by nanoscale-localized multiplexed biological activation | This paper describes a scalable and CMOS-compatible fabrication strategy for modifying individual field-effect transistors (FETs) with distinct bioreceptors. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | nature | January, 2024 | scientific-paper | nanofrazor thermal-scanning-probe | nature | ||
Ultra compact electrochemical metallization cells offering reproducible atomic scale memristive switching | Coming soon. | Scientific Paper | NanoFrazor, Thermal Scanning Probe (t-SPL) | Communications Physics | March, 2019 | scientific-paper | nanofrazor thermal-scanning-probe | communications-physics | ||
Ultra-High Resolution Pattern Transfer on NanoFrazor Lithography | High-resolution lithography is crucial for current and future technologies, requiring dimension reduction. NanoFrazor lithography, multi-layer stacks, and alternative strategies for superior patterns are discussed. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | July, 2023 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano |
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Title | Description | Category | Tags | Publisher | Published | Link | hf:doc_categories | hf:doc_tags | hf:doc_author | |
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Bilayer Lift-Off for NanoFrazor Lithography | Explore bilayer lift-off with NanoFrazor lithography, addressing advantages, process details, and examples, including high-quality contacts and structures as small as 7 nm. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | July, 2023 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
Damage-free nanolithography enabling superior device performance | Thermal scanning probe lithography enabled by NanoFrazor helps to fabricate devices with superior performance due to its damage-free patterning principle. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | September, 2024 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
High-resolution patterning of nanowire-based quantum devices with the NanoFrazor | The NanoFrazor offers a unique patterning solution, combining t-SPL and laser mix and match lithography. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | September, 2024 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
NanoFrazor for Direct Nanoscale Chemical Conversion of Materials | Chemical conversion using a thermal scanning probe can be used to make biosensors with advanced architecture and tailor surface chemistry to create nanostructures. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | August, 2024 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano | ||
Ultra-High Resolution Pattern Transfer on NanoFrazor Lithography | High-resolution lithography is crucial for current and future technologies, requiring dimension reduction. NanoFrazor lithography, multi-layer stacks, and alternative strategies for superior patterns are discussed. | Application Note | NanoFrazor, Thermal Scanning Probe (t-SPL) | Heidelberg Instruments Nano | July, 2023 | application-note | nanofrazor thermal-scanning-probe | heidelberg-instruments-nano |