Scanning near-field optical microscope
COUNTRY OF ORIGIN
BelarusIDENTIFIER
BO6677PUBLISHED
2023-04-23LAST UPDATE
2023-04-23DEADLINE
Linked profile in other language
Responsible
Svetlana Markova
+375 29 752 8328
sveta_oms@itmo.by
+375 29 752 8328
sveta_oms@itmo.by
Summary
A.V.Luikov Heat and Mass Transfer Institute of the National Academy of Sciences of Belarus offers customers a scanning near-field optical microscope under a manufacturing agreement and is looking for partners to conclude a distribution services agreement.
Description
A.V.Luikov Heat and Mass Transfer Institute of the National Academy of Sciences of Belarus has developed a scanning near-field optical microscope (hereinafter referred to as SNOM), designed to study the structure and composition of the surfaces of optically opaque objects. SNOM provides the study of the surface of objects by optical microscopy with a resolution below the diffraction limit due to the detection of radiation scattered by the object under study at distances smaller than the wavelength of light.
To create a local spatial inhomogeneity of optical radiation with a characteristic size of 5 - 20 nm, the passage of radiation through an aperture with dimensions much smaller than the wavelength (the so-called aperture method) is used, or the use of a real nanoscale electric dipole - a quantum dot, or a metal nanoparticle, as a rule , with the effect of giant Raman scattering (the so-called apertureless method).
At large distances, only radiative modes are observed, and for radiation with a wavelength of 650 nm and a diaphragm with an aperture of up to 5 nm, the radiation power in the far zone is 10-10 of the incident radiation power. When evanescent radiation interacts with a nanosized object under study in the near field, part of the electromagnetic field energy is converted into radiative modes, which are recorded by an optical photodetector in the form of an optical radiation intensity distribution depending on the local optical properties of the nanosized sample (local values of reflection, refraction, absorption and scattering of light).
The scanning system of the SSBOM-01 near-field optical microscope ensures the mutual movement of the probe and the sample in three dimensions X, Y, Z using a special positioner with piezo drives controlled by a specialized computer.
Composition of SBOM:
- scanning platform for nanodisplacements;
- microprocessor control unit of the scanning platform;
- fiber optic system;
- system of registration and restoration of images.
Main technical characteristics of SNOM:
To create a local spatial inhomogeneity of optical radiation with a characteristic size of 5 - 20 nm, the passage of radiation through an aperture with dimensions much smaller than the wavelength (the so-called aperture method) is used, or the use of a real nanoscale electric dipole - a quantum dot, or a metal nanoparticle, as a rule , with the effect of giant Raman scattering (the so-called apertureless method).
At large distances, only radiative modes are observed, and for radiation with a wavelength of 650 nm and a diaphragm with an aperture of up to 5 nm, the radiation power in the far zone is 10-10 of the incident radiation power. When evanescent radiation interacts with a nanosized object under study in the near field, part of the electromagnetic field energy is converted into radiative modes, which are recorded by an optical photodetector in the form of an optical radiation intensity distribution depending on the local optical properties of the nanosized sample (local values of reflection, refraction, absorption and scattering of light).
The scanning system of the SSBOM-01 near-field optical microscope ensures the mutual movement of the probe and the sample in three dimensions X, Y, Z using a special positioner with piezo drives controlled by a specialized computer.
Composition of SBOM:
- scanning platform for nanodisplacements;
- microprocessor control unit of the scanning platform;
- fiber optic system;
- system of registration and restoration of images.
Main technical characteristics of SNOM:
| scanning field in the XY plane | 100х100 micron |
| measuring range of linear dimensions along the Z axis | 50-100 nm |
| spectral range of detected radiation | 480-680 nm |
| optical zoom | 60X |
A scanning near-field optical microscope is used in various fields of science: microelectronics, nanotechnology, semiconductor technologies, superhard materials, micro- and nanotribology, surface finishing, precision mechanics systems, magnetic recording, vacuum technology, visualization of nanostructures, analysis of biological objects (membranes, cells and etc.).
The Institute offers partners:
*as part of a manufacturing agreement, the acquisition of a scanning near-field optical microscope, the development of technical means and methods for examining samples at the request of the customer.
*under a distribution services agreement: scanning near-field optical microscope.
The Institute offers partners:
*as part of a manufacturing agreement, the acquisition of a scanning near-field optical microscope, the development of technical means and methods for examining samples at the request of the customer.
*under a distribution services agreement: scanning near-field optical microscope.
Advantages and Innovations
The design of the SNOM uses a scheme for studying opaque samples for reflection, in which the probe is brought to the sample from above, and which is then recorded by a photodetector, which makes it possible to additionally implement the luminescent mode of operation with the detection of the object's luminescent radiation.
It is allowed to use a personal computer to control the drives using the USB 2.0 or USB 3.0 interface.
It is allowed to use a personal computer to control the drives using the USB 2.0 or USB 3.0 interface.
Stage of development
Already on the market
Funding source
State budged
Internal
Internal
IPR status
Exclusive rights
Secret know-how
Secret know-how
Sector group
Aeronautics, Space and Dual-Use Technologies
Nano and micro technologies
Nano and micro technologies
Client information
Type
R&D institution
Year established
1952
NACE keywords
C.28.99 - Manufacture of other special-purpose machinery n.e.c.
M.72.19 - Other research and experimental development on natural sciences and engineering
M.74.90 - Other professional, scientific and technical activities n.e.c.
M.72.19 - Other research and experimental development on natural sciences and engineering
M.74.90 - Other professional, scientific and technical activities n.e.c.
Turnover (in EUR)
1-10M
Already engaged in transnational cooperation
Yes
Languages spoken
English
Russian
Russian
Information about partnership
Type of partnership considered
Distribution services agreement
Manufacturing agreement
Manufacturing agreement
Type and role of partner sought
Consumers interested in purchasing a scanning near-field optical microscope under a manufacturing agreement.
Partners interested in concluding a distribution services agreement.
Partners interested in concluding a distribution services agreement.
Type and size of partner sought
> 500
251-500
SME 51-250
SME 11-50
SME <= 10
R&D Institution
University
251-500
SME 51-250
SME 11-50
SME <= 10
R&D Institution
University
Attachments
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Statistics since 23.04.2023 23:00:41
Statistics since 23.04.2023 23:00:41