Local magnetic probes of superconductors

Bending, Simon

doi:10.1080/000187399243437

Cited by 190 publications

(152 citation statements)

References 38 publications

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“…Because the magnetic field of the sample is not coupled to the SQUID loop directly, but rather through a pickup coil, integration of a modulation coil or an integrated current-carrying element 15,19,21,33,38,39 allows the total flux in the SQUID loop to be maintained at its optimal bias while the magnetic field of the sample is varied independently.…”

Section: Introductionmentioning

confidence: 99%

“…Scanning micro-and nanoscale SQUIDs are of particular interest for magnetic imaging due to their high sensitivity and large bandwidth 15,19 . The two main technological approaches to the fabrication of scanning SQUIDs are based on planar lithographic methods 21,26,[33][34][35][36] and on self-aligned SQUIDon-tip (SOT) deposition 22,24,37 .In the planar SQUID architecture, spatial resolution is limited but pickup and modulation coils can be integrated to allow operation of the SQUID at optimal flux bias conditions using a fluxlocked loop (FLL) feedback mechanism 15,18,19,21,33,38,39 . Because the magnetic field of the sample is not coupled to the SQUID loop directly, but rather through a pickup coil, integration of a modulation coil or an integrated current-carrying element 15,19,21,33,38,39 allows the total flux in the SQUID loop to be maintained at its optimal bias while the magnetic field of the sample is varied independently.…”

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confidence: 99%

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Electrically Tunable Multiterminal SQUID-on-Tip

et al. 2016

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We present a new nanoscale superconducting quantum interference device (SQUID) whose interference pattern can be shifted electrically in-situ. The device consists of a nanoscale fourterminal/four-junction SQUID fabricated at the apex of a sharp pipette using a self-aligned threestep deposition of Pb. In contrast to conventional two-terminal/two-junction SQUIDs that display optimal sensitivity when flux biased to about a quarter of the flux quantum, the additional terminals and junctions allow optimal sensitivity at arbitrary applied flux, thus eliminating the magnetic field "blind spots". We demonstrate spin sensitivity of 5 to 8 µ B /Hz 1/2 over a continuous field range of 0 to 0.5 T, with promising applications for nanoscale scanning magnetic imaging.KEYWORDS: superconducting quantum interference device, SQUID on tip, nanoscale magnetic imaging, current-phase relations 2 In recent years, there has been a growing effort to develop and apply nanoscale magnetic imaging tools in order to address the rapidly evolving fields of nanomagnetism and spintronics.These include magnetic force microscopy (MFM) 1,2 , magnetic resonance force microscopy (MRFM) [3][4][5] , nitrogen vacancy (NV) centers sensors [6][7][8][9] , scanning Hall probe microscopy (SHPM) 10-12 , x-ray magnetic microscopy (XRM) 13 , and micro-or nano-superconducting quantum interference device (SQUID) [14][15][16][17][18][19][20] based scanning microscopy (SSM) [21][22][23][24][25][26][27][28][29][30][31][32] . Scanning micro-and nanoscale SQUIDs are of particular interest for magnetic imaging due to their high sensitivity and large bandwidth 15,19 . The two main technological approaches to the fabrication of scanning SQUIDs are based on planar lithographic methods 21,26,[33][34][35][36] and on self-aligned SQUIDon-tip (SOT) deposition 22,24,37 .In the planar SQUID architecture, spatial resolution is limited but pickup and modulation coils can be integrated to allow operation of the SQUID at optimal flux bias conditions using a fluxlocked loop (FLL) feedback mechanism 15,18,19,21,33,38,39 . Because the magnetic field of the sample is not coupled to the SQUID loop directly, but rather through a pickup coil, integration of a modulation coil or an integrated current-carrying element 15,19,21,33,38,39 allows the total flux in the SQUID loop to be maintained at its optimal bias while the magnetic field of the sample is varied independently.SOTs, in contrast, have better spatial resolution due to their small size and close proximity to the sample, attain higher spin sensitivity, and can operate at high magnetic fields 24 . The nanoscale proximity of the SOT to the sample surface, which is its key advantage, dictates however that the flux in the SQUID loop is directly coupled to the local field of the sample and therefore cannot be modified independently. As a result, the FLL concept cannot be implemented in direct nanoscale magnetic imaging. This poses a significant drawback, since the high sensitivity of the SOT is achieved only at specific field va...

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Electrically Tunable Multiterminal SQUID-on-Tip

et al. 2016

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“…2 Imaging technologies are powerful tools to visualize and understand vortex motion in patterned superconductors. The low-temperature versions of scanning tunneling microscopy ͑STM͒, 3 magnetic force microscopy ͑MFM͒, scanning Hall probe microscopy, 4 laser scanning microscopy ͑LSM͒, 5 and magneto-optic 6 ͑MO͒ microscopy are complementary technologies for the visualization of vortices in superconductors. For instance, high resolution MFM and MO imaging are sensitive on the scale of the London penetration depth L , whereas STM is sensitive to the variations of the order parameter .…”

Section: Introductionmentioning

confidence: 99%

Laser scanning microscopy of guided vortex flow in microstructured high-Tc films

Lukashenko

Ustinov

Zhuravel

et al. 2006

Journal of Applied Physics

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We report the visualization of guidance of vortices by artificial microholes ͑antidots͒ in superconducting thin films using a low-temperature laser scanning microscope. Previously, guided motion of vortices via tilted rows of antidots in YBa 2 Cu 3 O 7 films was detected indirectly by using resistive Hall-type measurements. Here we prove that vortices are steered between antidots into a priori chosen direction by imaging of resistive photoresponse with a spatial resolution down to about 1 m. We observe predominant paths for vortex motion. Vortices are nucleated and annihilated at antidots, i.e., antidots define starting and ending points of predominant vortex paths. Depending on the misorientation angle between rows of antidots and the current-driven direction of vortex motion, different channels dominate in antidot-guided vortex motion. Our experimental results can be explained by the n-channel model. Finally, we present direct measurements of the local critical currents. This technique can be used as a quantitative method for the analysis of vortex motion in micropatterned thin films.

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“…Magnetic force microscopy ͑MFM͒, for instance, has spatial resolution as high as 10 nm at room temperature. 1,2 However, it measures field gradients instead of actual fields, and its typical reported field sensitivity is 10 −4 T. 2 Recently, scanning Hall probe microscopes have shown spatial resolutions as high as 50 nm with field sensitivities down to 10 −8 T. 2,3 Superconducting quantum interference devices ͑SQUIDs͒ are known to be the highest sensitivity magnetometers, capable of detecting single flux quanta, and have been incorporated in scanning microscopes. For low temperature scanning SQUID microscopes using Nb-based SQUIDs, the maximum demonstrated field sensitivity is 2 ϫ 10 −14 T/Hz 1/2 .…”

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confidence: 99%

“…The best demonstrated sensitivity for these systems is 10 −14 T/Hz 1/2 . 2 However, the distance between the sample and the sensor limits the spatial resolution to 20 m. 2,4 Recently, tunneling magnetoresistance sensors have been incorporated in probe microscopes with spatial resolutions as high as 0.1 m and a demonstrated field sensitivity of 10 −9 T. 5 Magnetoelectric ͑ME͒ materials are material systems that simultaneously display ferromagnetism and ferroelectricity. Laminated magnetoelectrics, a subclass of magnetoelectric materials, have gained significant attention in the past few years due to their ability to sense very small magnetic fields.…”

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confidence: 99%

Demonstration of magnetoelectric scanning probe microscopy

Hattrick‐Simpers

Dai

Wuttig

et al. 2007

Review of Scientific Instruments

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A near-field room temperature scanning magnetic probe microscope has been developed using a laminated magnetoelectric sensor. The simple trilayer longitudinal-transverse mode sensor, fabricated using Metglas as the magnetostrictive layer and polyvinylidene fluoride as the piezoelectric layer, shows an ac field sensitivity of 467±3μV∕Oe in the measured frequency range of 200Hz–8kHz. The microscope was used to image a 2mm diameter ring carrying an ac current as low as 10−5A. ac fields as small as 3×10−10T have been detected.

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Local magnetic probes of superconductors

Cited by 190 publications

References 38 publications

Electrically Tunable Multiterminal SQUID-on-Tip

Electrically Tunable Multiterminal SQUID-on-Tip

Laser scanning microscopy of guided vortex flow in microstructured high-Tc films

Demonstration of magnetoelectric scanning probe microscopy

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