Narrow-band near-field nanoscopy in the spectral range from 1.3 to 8.5 THz

Kuschewski, Frederik; Ribbeck, H. G. von; Döring, Jonathan; Winnerl, Stephan; Eng, Lukas M.; Kehr, Susanne C.

doi:10.1063/1.4943793

Cited by 60 publications

(74 citation statements)

References 32 publications

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“…On Alumina, ℎ Q/7 increases only by a factor of 1.5 (from 11 to 16 nm) when the tip radius increases by a factor of 30 (from R = 25 nm to 750 nm). These dramatic sub-radius decay distances are in stark contrast to the widespread assumptions 6,19,27,39,43 that (i) the near-field signal´s decay distance is on the scale of the tip radius, and (ii) the lateral resolution is closely related to ℎ Q/7 . Comparison of Figure 3 and Figure 2c reveals that ℎ Q/7 can be one order of magnitude smaller than the lateral resolution Dx (e.g.…”

Section: Approach Curves Confirm Background-free Near-field Signalscontrasting

confidence: 66%

“…Unavoidable background scattering can be suppressed by vertical tip oscillation and demodulation of the detector signal at a higher harmonics (multiples) of the tip´s oscillation frequency. Improved background suppression is obtained in combination with interferometric detection, which additionally yields amplitude and phase of the scattered field that are related to the reflection and absorption properties of the sample, respectively 19-21 . s-SNOM at THz frequencies 22,23,6,[24][25][26][27][28][29][30][31][32][33] a tool of rapidly growing interest, as it allows, for example, for THz nanoimaging of complex electronic phases in 2D materials and exotic conductors 34. However, THz s-SNOM is still in its infancy, mainly due to two reasons. First, the power of most THz sources is rather weak compared to that of infrared and visible sources, and detectors are often bulky, expensive and require cryogenic operation.…”

Section: Introductionmentioning

confidence: 99%

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Probes for Ultrasensitive THz Nanoscopy

et al. 2019

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Scattering-type scanning near-field microscopy (s-SNOM) at terahertz (THz) frequencies could become a highly valuable tool for studying a variety of phenomena of both fundamental and applied interest, including mobile carrier excitations or phase transitions in 2D materials or exotic conductors. Applications, however, are strongly challenged by the limited signal-to-noise ratio. One major reason is that standard atomic force microscope (AFM) tips -which have made s-SNOM a highly practical and rapidly emerging tool -provide weak scattering efficiencies at THz frequencies. Here we report a combined experimental and theoretical study of commercial and custom-made AFM tips of different apex diameter and length, in order to understand signal formation in THz s-SNOM and to provide insights for tip optimization. Contrary to common beliefs, we find that AFM tips with large (micrometer-scale) apex diameter can enhance s-SNOM signals by more than one order of magnitude, while still offering a spatial resolution of about 100 nm at a wavelength of λ = 119 µm. On the other hand, exploiting the increase of s-SNOM signals with tip length, we succeeded in sub-15 nm (<λ/8000) resolved THz imaging employing a tungsten tip with 6 nm apex radius. We explain our findings and provide novel insights into s-SNOM via rigorous numerical modeling of the near-field scattering process. Our findings will be of critical importance for pushing THz nanoscopy to its ultimate limits regarding sensitivity and spatial resolution. TOC graphics

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Section: Approach Curves Confirm Background-free Near-field Signalscontrasting

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Probes for Ultrasensitive THz Nanoscopy

et al. 2019

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“…6 Near-field spectroscopy and scattering-type scanning near-field optical microscopy (s-SNOM) combine the material specificity of optical and IR techniques with the wavelength-independent 12,13 nanoscale resolution of atomic force microscopy, [14][15][16][17] making s-SNOM an outstanding tool for investigations down to the THz region. 13,[17][18][19][20][21][22] In addition to the spatial resolution, the probing depth of s-SNOM of about 100 nm 21,23-26 presents a major advantage for the investigation of small volumes or thin film samples, allowing for IR thin film spectroscopy with negligible direct substrate contribution to the optical signal. 27 The signal strength of s-SNOM is greatly enhanced via polaritoninduced resonant tip-sample interaction, 12,17,27,[30][31][32][34][35][36][37][38][39][40][41][42][43][44][45] which is of special advantage when exploring technically challenging wavelength regimes, 17,45 such as the "THz gap" (30-300 lm, i.e., 1-10 THz).…”

mentioning

confidence: 99%

Phonon-induced near-field resonances in multiferroic BiFeO3 thin films at infrared and THz wavelengths

Wehmeier

Nörenberg

Oliveira

et al. 2020

Applied Physics Letters

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Multiferroic BiFeO 3 (BFO) shows several phonon modes at infrared (IR) to THz energies, which are expected to carry information on any sample property coupled to crystal lattice vibrations. While macroscopic IR studies of BFO are often limited by single-crystal size, scatteringtype scanning near-field optical microscopy (s-SNOM) allows for IR thin film spectroscopy of nanoscopic probing volumes with negligible direct substrate contribution to the optical signal. In fact, polaritons such as phonon polaritons of BFO introduce a resonant tip-sample coupling in s-SNOM, leading to both stronger signals and enhanced sensitivity to local material properties. Here, we explore the near-field response of BFO thin films at three consecutive resonances (centered around 5 THz, 13 THz, and 16 THz), by combining s-SNOM with a free-electron laser. We study the dependence of these near-field resonances on both the wavelength and tip-sample distance. Enabled by the broad spectral range of the measurement, we probe phonon modes connected to the predominant motion of either the bismuth or oxygen ions. Therefore, we propose s-SNOM at multiple near-field resonances as a versatile and very sensitive tool for the simultaneous investigation of various sample properties.

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“…To date far-IR s-SNOM has only routinely been achieved using a free electron laser (FEL) [28] that provides the necessary high intensity quasi-cw radiation as needed for s-SNOM spectroscopy. Although in principle continuously tunable from 1.…”

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confidence: 99%

Far Infrared Synchrotron Near-Field Nanoimaging and Nanospectroscopy

et al. 2018

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Scattering scanning near-field optical microscopy (s-SNOM) has emerged as a powerful imaging and spectroscopic tool for investigating nanoscale heterogeneities in biology, quantum matter, and electronic and photonic devices. However, many materials are defined by a wide range of fundamental molecular and quantum states at far-infrared (FIR) resonant frequencies currently not accessible by s-SNOM. Here we show ultrabroadband FIR s-SNOM nanoimaging and spectroscopy by combining synchrotron infrared radiation with a novel fast and low-noise copper-doped germanium (Ge:Cu) photoconductive detector. This approach of FIR synchrotron infrared nanospectroscopy (SINS) extends the wavelength range of s-SNOM to 31 μm (320 cm −1 , 9.7 THz), exceeding conventional limits by an octave to lower energies. We demonstrate this new nanospectroscopic window by measuring elementary excitations of exemplary functional materials, including surface phonon polariton waves and optical phonons in oxides and layered ultrathin van der Waals materials, skeletal and conformational vibrations in molecular systems, and the highly tunable plasmonic response of graphene.

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Narrow-band near-field nanoscopy in the spectral range from 1.3 to 8.5 THz

Cited by 60 publications

References 32 publications

Probes for Ultrasensitive THz Nanoscopy

Probes for Ultrasensitive THz Nanoscopy

Phonon-induced near-field resonances in multiferroic BiFeO3 thin films at infrared and THz wavelengths

Far Infrared Synchrotron Near-Field Nanoimaging and Nanospectroscopy

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