2018
DOI: 10.1103/physrevb.97.060404
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Generation of a localized microwave magnetic field by coherent phonons in a ferromagnetic nanograting

Abstract: A high-amplitude microwave magnetic field localized at the nanoscale is a desirable tool for various applications within the rapidly developing field of nanomagnetism. Here, we drive magnetization precession by coherent phonons in a metal ferromagnetic nanograting and generate ac-magnetic induction with extremely high amplitude (up to 10 mT) and nanometer scale localization in the grating grooves. We trigger the magnetization by a laser pulse which excites localized surface acoustic waves. The developed techni… Show more

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Cited by 27 publications
(36 citation statements)
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“…Interactions of coherent phonons with thermal phonons [10], electrons [11][12][13][14][15], plasmons [16][17][18], and magnons [19][20][21][22][23][24][25] are intensively studied in metallic (for a review see Ref. [26]) and semiconductor [27,28] nanoparticles, multilayered heterostructures [13][14][15]29,30], and patterned surfaces [16][17][18]21,31]. These interactions underpin a wide range of phenomena, such as piezoelectricity, light scattering, phonon-assisted tunneling, etc., and the design and successful development of devices for electronics [32] and optoelectronics [33].…”
Section: Introductionmentioning
confidence: 99%
“…Interactions of coherent phonons with thermal phonons [10], electrons [11][12][13][14][15], plasmons [16][17][18], and magnons [19][20][21][22][23][24][25] are intensively studied in metallic (for a review see Ref. [26]) and semiconductor [27,28] nanoparticles, multilayered heterostructures [13][14][15]29,30], and patterned surfaces [16][17][18]21,31]. These interactions underpin a wide range of phenomena, such as piezoelectricity, light scattering, phonon-assisted tunneling, etc., and the design and successful development of devices for electronics [32] and optoelectronics [33].…”
Section: Introductionmentioning
confidence: 99%
“…Using two roots ±k (i) , one can obtain the general solutions for u (i) . The normal stress can be represented as T (i) =T (i) zx= C (i) (u (i) /x)+ eIδi1/(jωl (1) C0), where second term exists only in the piezoelectric layer 1. Here e and C0 are the piezoelectric modulus and capacity of the layer, I is the displacement current flowing in the layer [24].…”
Section: Theorymentioning
confidence: 99%
“…The surface acoustic, Rayleigh-type, wave is additionally interesting in this context because of the circular trajectory of particle displacement, which suggests a small Barnett field [124,125]. Surface acoustic waves in this context become akin to localized sources of microwave magnetic field [126,127]. There is also ongoing work towards coupling individual spins in defect centres, such as the nitrogen vacancy in diamond, to local strain.…”
Section: Torque Measurements Against the Backdrop Of Ongoing Advancesmentioning
confidence: 99%