Near-Field Optical Spectroscopy Centre at Sheffield, NOSC
Lead Research Organisation:
University of Sheffield
Department Name: Physics and Astronomy
Abstract
The function of many new materials that drive innovation and even the function of the living micro-systems such as bacteria is defined by their nanoscale properties such as the local chemical composition, ability to transfer and dissipate energy and electrical charge, local crystal structure and nanometre-sized defects, ability to scatter and trap light, or to induce chemical reactions through catalysis and many more. Understanding how we can prolong the life-time of devices, for example a battery cathode or a solar cell, can also be gained from understanding of how the material in the device changes on the nanoscale during its operation. It has long been a drive to develop technical means that allow to 'see' with nanometer resolution, an impossible task if conventional 'far-field' optical microscopy is used, because of the diffraction limit. The optical diffraction limit can be overcome if high energy electrons are used instead of light, but such electron microscopy may be damaging for the studied materials and nano-structures and quite often requires special sample preparation.
Truly non-invasive techniques relying on weak optical probes are therefore highly desirable, and have now become available in state-of-the-art experimental instruments. In this project, we will establish a research facility based on such an instrument, which provides a unique suite of novel optical techniques capable of 10 nm spatial resolution, 50 to 1000 times below the optical diffraction limit. The techniques are based on the light focusing with a very sharp tip, used in atomic force microscopy (AFM). Such techniques will operate in conjunction with the powerful nanoscale investigation method provided by AFM. The facility will provide this experimental platform for the world-leading research at the University of Sheffield and the UK scientific community as a whole in topics including artificial photosynthesis, antimicrobial resistance, inorganic and organic semiconductors, quantum and bioinspired nano-photonics, two-dimensional materials, solar cells, photocatalysis and nano-materials for solid state batteries among many others. Common to all these fields is the challenge of mapping structural, chemical and functional properties with nanoscale resolution; a challenge that prevents further breakthroughs in understanding and innovation in the technology areas that are vital to the UK's interests, and which we will address within the proposed nano-spectroscopy facility.
Truly non-invasive techniques relying on weak optical probes are therefore highly desirable, and have now become available in state-of-the-art experimental instruments. In this project, we will establish a research facility based on such an instrument, which provides a unique suite of novel optical techniques capable of 10 nm spatial resolution, 50 to 1000 times below the optical diffraction limit. The techniques are based on the light focusing with a very sharp tip, used in atomic force microscopy (AFM). Such techniques will operate in conjunction with the powerful nanoscale investigation method provided by AFM. The facility will provide this experimental platform for the world-leading research at the University of Sheffield and the UK scientific community as a whole in topics including artificial photosynthesis, antimicrobial resistance, inorganic and organic semiconductors, quantum and bioinspired nano-photonics, two-dimensional materials, solar cells, photocatalysis and nano-materials for solid state batteries among many others. Common to all these fields is the challenge of mapping structural, chemical and functional properties with nanoscale resolution; a challenge that prevents further breakthroughs in understanding and innovation in the technology areas that are vital to the UK's interests, and which we will address within the proposed nano-spectroscopy facility.
Publications
Krok D
(2023)
Highly efficient carbon dot-based photoinitiating systems for 3D-VAT printing
in Polymer Chemistry
Randerson S
(2024)
High Q Hybrid Mie-Plasmonic Resonances in van der Waals Nanoantennas on Gold Substrate
in ACS Nano
Title | Installation of versatile system for Near-field Optical Imaging and Spectroscopy |
Description | The new system allows optical nano-imaging and nano-spectroscopy with down to 20 nm spatial resolution independent of wavelength. The light is focussed on an Atomic Force Microscopy tip allowing optical interaction with the nm-scale spot on the sample surface only. The set-up has a unique combination of lasers with wavelength ranges covered by the equipment across the entire visible range into the near-infrared (350 nm - 1600 nm), and cover a large region of the mid-infrared (650 cm-1 - 2,300 cm-1, or 4-15 micron). |
Type Of Material | Improvements to research infrastructure |
Year Produced | 2022 |
Provided To Others? | Yes |
Impact | Too early to say. The instrument has been made available to University of Sheffield researchers from autumn 2022 (official launch September 2022) and will be made available to UK users outside the University of Sheffield from autumn 2023 (launch September 2023). |
URL | https://www.sheffield.ac.uk/nearfield-optical-spectroscopy |
Description | Farr |
Organisation | University of Sheffield |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Our team at Near-field Optical Imaging and Spectroscopy Centre (NOSC) carried out a large number of near-field nano-imaging and nano- spectroscopy experiments on a wide range of materials with applications in medical research, materials science etc |
Collaborator Contribution | Dr Nicholas Farr has worked closely with Dr Alexander Knight in providing materials and samples for the study in near-field nano-imaging and nano- spectroscopy experiments at NOSC |
Impact | We have published two research papers and submitted another two. |
Start Year | 2022 |