Contact-mode AFM measurements

For contact mode AFM an etched silicon cantilever with a silicon tip combined with optical deflection detection was used to measure local interactions such as van der Waals or Coulomb forces. We used fiber-based interferometric sensing [Reference Rugar10] to detect the deflection: a fiber was mounted in the head of the microscope to detect the deflection of the cantilever induced by the tip-sample interaction. A measurement of the amplitude of the relative displacement between the AFM tip and the sample was performed to evaluate the impact of the absolute vibrations of the system on the performance of the scanning probe experiments. A schematic representation of our AFM head with interferometric read-out is shown in Figure 4a. The z-noise was measured while keeping the tip in contact with the sample surface. Vibration data describing the relative displacement between the tip and the sample for the fully enabled system were then recorded over time. Noise statistics of the tip deflection were acquired over 10,000 points. The sampling time was set to 5 ms, corresponding to a measurement bandwidth of 200 Hz. Figure 4b shows the noise histogram. The result is a normal Gaussian distribution of the noise with a standard deviation σ = 65 pm rms; this value, measured with the feedback loop enabled, is comparable to the z-noise amplitude obtained in liquid systems [11]. When the feedback is turned off, the noise amplitude increases by approximately a factor of 4. To demonstrate the low vibration noise, images were taken at T = 3.2 K on terraces of height matching the lattice parameter (a = 0.39 nm) of a strontium titanate (SrTiO₃) commercial wafer, shallow polished at 0.1° then annealed to obtain terrace-and-step rearrangement at the surface. The image in Figure 5a shows a contact mode scan revealing the terrace-and-step morphology of the sample surface, with steps measuring 0.4 nm. The image was acquired in 21 ms sampling time, with a bandwidth of 47.6 Hz. These measurements are fully consistent with those reported of a similar commercial sample of SrTiO₃ measured at room temperature, showing 0.4 nm lattice steps without the influence of a cryo-cooling system [Reference Huijben12].

Figure 4 (a) Interferometric head for AFM measurements. (b) Contact mode noise scan histogram of the z-height values measured with a bandwidth of 200 Hz at 3.2 K. Measured amplitude of the relative displacement was 65 pm.

Figure 5 (a) Contact-mode AFM image of terraces on SrTiO₃ (200 scan lines) at 3.2 K. Bar=400 nm. Step height is 0.39 nm, corresponding to the lattice parameter of the crystal. Frame time for the acquisition was 1,680 s at a scan rate of 500 nm/s. (b) Single-line profile showing the height of the atomically flat terraces on SrTiO₃.

Magnetic force microscopy measurements

Exciting research in low-temperature solid-state physics is currently carried out by means of magnetic force and magnetic resonance force microscopy, including the imaging of currents in topological insulators [Reference Nowack1], nanoscale spin configurations (magnetic skyrmions) in chiral magnets [Reference Milde2], scanning diamond magnetometry using nitrogen-vacancy (NV) centers in diamonds as solid-state sensors of magnetic field [Reference Balasubramanian13–Reference Mamin15], and scanning gate microscopy [Reference Pelliccione7, Reference Garcia16]. These techniques require sensitivity to extremely small magnetic interactions with nanometer spatial resolution. Their recent successful implementation required liquid bath cryostats. Given the scarcity of liquid helium, the implementation of scanning magnetic force microscopy inside dry cryostats represents the way forward. The low level of vibrations achieved in our dry cryostat allowed a variety of magnetic force microscopy measurements.

In magnetic force microscopy, tips with magnetic coatings, typically NiCr or cobalt (Co), are employed that are sensitive to variations of magnetic field. The tip is oscillated at its resonance using a dither piezo; as it is scanned across the sample, the strength of the magnetic interaction between the tip and the magnetic fields near the surface determines a shift in the oscillation frequency. Frequency shifts map the magnetic structure of the sample. Figure 4a shows a diagram of the cantilever-based force microscope used in this work, specific for applications at low temperature and high magnetic field. Magnetic force microscopy is especially sensitive to the sample-tip separation, and vertical vibrations can affect image resolution by impairing the force sensitivity of the probe. We measured skyrmion lattices in our dry cryostat with an unprecedented signal-to-noise ratio of 20:1.

Skyrmion-lattice and helimagnetic phase in single-crystal Fe_0.5Co_0.5Si

Magnetic skyrmions are nanoscale spin whirls. Hexagonal lattices of these whirls are observed in certain chiral magnets without inversion symmetry in a phase pocket in finite magnetic field [Reference Garcia17, Reference Garcia18, Reference Garcia19]. Perhaps most excitingly, electric currents allow these magnetic textures to move already at ultra-low current densities [Reference Garcia20, Reference Garcia21]. Combined with their size in the nanometer range and their stability arising from the topologically non-trivial winding, skyrmions promise great potential for applications in information technology [Reference Garcia22]. In addition to the bulk chiral magnets, skyrmions are recently also studied in thin films and monolayers, where they are typically driven by the surface and may be readily studied by means of SPM [Reference Garcia23, Reference Garcia24]. For this report, however, we investigated the surface of a polished single crystal of Fe_0.5Co_0.5Si in our dry cryostat [Reference Garcia2].

We observed (Figure 6a) helimagnetic structures at T=3.2 K in zero magnetic field and a skyrmion-lattice texture (Figure 6b) at T = 3.4 K in an externally applied field B = 15 mT. The measurements of the helimagnetic phase in Fe_0.5Co_0.5Si and the imaging of the skyrmion-lattice phase transition of the single crystal were carried out using a sharp tip (tip apex radius ~10 nm) with a magnetic coating (Nanosensors, SSS-MFMR). The magnetic tip was kept at a constant height of 20–30 nm over the sample surface, with a phase-locked loop activated to monitor the cantilever resonance frequency. The sample was heated to 60 K, and the magnetic field was increased to 15 mT. The sample was subsequently field-cooled to base temperature again. With the persistent switch heater of the superconducting magnet enabled, the temperature stabilized at 3.4 K at the sample position. Figure 7 shows an image sequence of the coalescence of the skyrmion phase into helimagnetic phase. The magnetic field was decreased from B = 15 mT, where the metastable skyrmion lattice was observed, to B = −30 mT, where the textures coalesce into the helimagnetic structure [Reference Balasubramanian2].

Figure 6 MFM images of the polished surface of a bulk sample of Fe_0.5Co_0.5Si. Images consist of 200 scan lines acquired using a sharp commercial cantilever (tip apex radius ~10 nm, SSS-MFMR from Nanosensors) with magnetic coating. (a) Helimagnetic phase of the sample at T=3.2 K after zero-field cooling (B=0 T). (b) Metastable skyrmion-lattice phase measured at T=3.4 K in an external magnetic field B=15 mT after field-cooling. Bars=1 μm. Line cuts highlight the frequency shift.

Figure 7 Coalescence of skyrmion-lattice phase into helimagnetic phase in Fe_0.5Co_0.5Si with decreasing magnetic field B = 15 mT to −30 mT. Bar = 500 nm. Acquisition details as stated in Figure 6.

Tuning Fork Scanning Force Microscopy measurements

Magnetic force microscopy imaging may be carried out with sensors exhibiting higher force sensitivity, such as tuning forks [Reference Pelliccione7]. We show shear-force tuning fork measurements performed in our dry cryostat, which demonstrate the potential for further improvement, in particular toward the use of NV-centers in diamond-based scanning probe magnetometry [Reference Balasubramanian13].

The implementation of quartz tuning forks as self-sensing probes in scanning force microscopy is especially beneficial because of their small size, the absence of thermal effects induced by the optical detection, and the avoidance of unnecessary exposure of sensitive samples to light at cryogenic temperatures. To the best of our knowledge this is the first time that tuning-fork shear-force microscopy measurements have been successfully reported in a dry cryostat. A tungsten tip was etched in house to reach a tip apex radius of approximately 80 nm and glued to one prong of the tuning fork [Reference Karrai and Grober25] as shown in Figure 8a. The viscoelastic interaction of the oscillating fork takes place through shear forces between the sample and the tip. Akiyama probes [26] are quartz resonators where a sharp silicon microcantilever is placed at the ends of the prongs, preserving the symmetry of the system. Typical values for the Akiyama spring constant are 5 N/m. The low noise amplitude measured between the tuning fork and the sample, with a bandwidth of 200 Hz and the feedback loop enabled, shows a normal Gaussian distribution with a standard deviation σ = 2 nm (Figure 8b). We demonstrate the achievement of tuning fork scanning force microscopy measurements of 20 ± 2 nm high SiO₂ patterns on Si with both Akiyama probes and in shear-force mode in our closed-cycle cryostat at T = 4 K (Figure 9a and 9b, respectively). The resolution is 200 lines per scan, acquired at 500 nm/s. Scanning in shear-force mode in a liquid-based cryostat, we measured noise amplitude better than 0.1 nm rms and, as discussed earlier, the contact mode noise measured in our dry cryostat was 65 pm.

Figure 8 (a) Quartz-crystal tuning fork with tungsten tip (1) and Akiyama probe (2). Bar=0.2 mm. (b) Shear-force mode noise scan; we measured 2 nm rms noise (bandwidth 200 Hz).

Figure 9 Quartz-crystal tuning fork AFM scans of SiO₂ 20 ± 2 nm high patterns on Si, performed in our dry cryostat at T = 4 K. 200 scan lines at 500 nm/s. (a) 5 × 5 μm² tapping mode scan with Akiyama probe (test grating pitch 2 μm). B = 2 μm. (b) 9 × 9 μm² shear-force mode scan with quartz-tuning-fork-tungsten-tip configuration (test grating pitch 4 μm). Bar in (d) = 4 μm. Cross sections relative to each scan are shown.