Nano-FTIR (nanoscale Fourier transform infrared spectroscopy) is a scanning probe technique that utilizes as a combination of two techniques: Fourier transform infrared spectroscopy (FTIR) and scattering-type scanning near-field optical microscopy (s-SNOM). As s-SNOM, nano-FTIR is based on atomic-force microscopy (AFM), where a sharp tip is illuminated by an external light source and the tip-scattered light (typically back-scattered) is detected as a function of tip position. A typical nano-FTIR setup thus consists of an atomic force microscope, a broadband infrared light source used for tip illumination, and a Michelson interferometer acting as Fourier transform spectrometer. In nano-FTIR, the sample stage is placed in one of the interferometer arms, which allows for recording both amplit
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| - Nano-FTIR (en)
- Nano-FTIR (pl)
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| - Nano-FTIR (nanoscale Fourier transform infrared spectroscopy) is a scanning probe technique that utilizes as a combination of two techniques: Fourier transform infrared spectroscopy (FTIR) and scattering-type scanning near-field optical microscopy (s-SNOM). As s-SNOM, nano-FTIR is based on atomic-force microscopy (AFM), where a sharp tip is illuminated by an external light source and the tip-scattered light (typically back-scattered) is detected as a function of tip position. A typical nano-FTIR setup thus consists of an atomic force microscope, a broadband infrared light source used for tip illumination, and a Michelson interferometer acting as Fourier transform spectrometer. In nano-FTIR, the sample stage is placed in one of the interferometer arms, which allows for recording both amplit (en)
- nano-FTIR – nanospektroskopia w podczerwieni z transformatą Fouriera (z ang. nanoscale Fourier Transformed Infrared Spectroscopy) – technika spektroskopii w podczerwieni umożliwiająca chemiczną i strukturalną charakteryzację takich materiałów jak: ciała stałe i półprzewodniki, materiały kompozytowe, organiczne, polimery oraz biomateriały w skali nanometrycznej w zakresie spektralnym 400–4500 cm−1 z rozdzielczością przestrzenną przekraczającą limit dyfrakcyjny Rayleigha. Pierwsza prezentacja układu nano-FTIR przeprowadzona została w 2006 roku w Instytucie Biochemii im. Maxa Plancka (MPIB) w Niemczech, natomiast w 2007 roku utworzone zostało niemieckie przedsiębiorstwo, spin-off, neaspec GmbH, które dwa lata później przygotowało pierwszy komercyjnie dostępny układ.Nano-FTIR jest techniką kom (pl)
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| - Nano-FTIR (nanoscale Fourier transform infrared spectroscopy) is a scanning probe technique that utilizes as a combination of two techniques: Fourier transform infrared spectroscopy (FTIR) and scattering-type scanning near-field optical microscopy (s-SNOM). As s-SNOM, nano-FTIR is based on atomic-force microscopy (AFM), where a sharp tip is illuminated by an external light source and the tip-scattered light (typically back-scattered) is detected as a function of tip position. A typical nano-FTIR setup thus consists of an atomic force microscope, a broadband infrared light source used for tip illumination, and a Michelson interferometer acting as Fourier transform spectrometer. In nano-FTIR, the sample stage is placed in one of the interferometer arms, which allows for recording both amplitude and phase of the detected light (unlike conventional FTIR that normally does not yield phase information). Scanning the tip allows for performing hyperspectral imaging (i.e. complete spectrum at every pixel of the scanned area) with nanoscale spatial resolution determined by the tip apex size. The use of broadband infrared sources enables the acquisition of continuous spectra, which is a distinctive feature of nano-FTIR compared to s-SNOM.Nano-FTIR is capable of performing infrared (IR) spectroscopy of materials in ultrasmall quantities and with nanoscale spatial resolution. The detection of a single molecular complex and the sensitivity to a single monolayer has been shown. Recording infrared spectra as a function of position can be used for nanoscale mapping of the sample chemical composition, performing a local ultrafast IR spectroscopy and analyzing the nanoscale intermolecular coupling, among others. A spatial resolution of 10 nm to 20 nm is routinely achieved. For organic compounds, polymers, biological and other soft matter, nano-FTIR spectra can be directly compared to the standard FTIR databases, which allows for a straightforward chemical identification and characterization. Nano-FTIR does not require special sample preparation and is typically performed under ambient conditions. It uses an AFM operated in noncontact mode that is intrinsically nondestructive and sufficiently gentle to be suitable for soft-matter and biological sample investigations. Nano-FTIR can be utilized from THz to visible spectral range (and not only in infrared as its name suggests) depending on the application requirements and availability of broadband sources. Nano-FTIR is complementary to tip-enhanced Raman spectroscopy (TERS), SNOM, AFM-IR and other scanning probe methods that are capable of performing vibrational analysis. (en)
- nano-FTIR – nanospektroskopia w podczerwieni z transformatą Fouriera (z ang. nanoscale Fourier Transformed Infrared Spectroscopy) – technika spektroskopii w podczerwieni umożliwiająca chemiczną i strukturalną charakteryzację takich materiałów jak: ciała stałe i półprzewodniki, materiały kompozytowe, organiczne, polimery oraz biomateriały w skali nanometrycznej w zakresie spektralnym 400–4500 cm−1 z rozdzielczością przestrzenną przekraczającą limit dyfrakcyjny Rayleigha. Pierwsza prezentacja układu nano-FTIR przeprowadzona została w 2006 roku w Instytucie Biochemii im. Maxa Plancka (MPIB) w Niemczech, natomiast w 2007 roku utworzone zostało niemieckie przedsiębiorstwo, spin-off, neaspec GmbH, które dwa lata później przygotowało pierwszy komercyjnie dostępny układ.Nano-FTIR jest techniką komplementarną do innych metod pomiarowych wykorzystujących mikroskop ze skanującą sondą, takich jak: wzmocniona na ostrzu spektroskopia Ramana (TERS), skaningowa mikroskopia optyczna pola bliskiego (SNOM) oraz spektroskopia w podczerwieni połączoną z mikroskopią sił atomowych (AFM-IR). (pl)
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