Acoustically actuated ultra-compact NEMS magnetoelectric antennas

State-of-the-art compact antennas rely on electromagnetic wave resonance, which leads to antenna sizes that are comparable to the electromagnetic wavelength. As a result, antennas typically have a size greater than one-tenth of the wavelength, and further miniaturization of antennas has been an open challenge for decades. Here we report on acoustically actuated nanomechanical magnetoelectric (ME) antennas with a suspended ferromagnetic/piezoelectric thin-film heterostructure. These ME antennas receive and transmit electromagnetic waves through the ME effect at their acoustic resonance frequencies. The bulk acoustic waves in ME antennas stimulate magnetization oscillations of the ferromagnetic thin film, which results in the radiation of electromagnetic waves. Vice versa, these antennas sense the magnetic fields of electromagnetic waves, giving a piezoelectric voltage output. The ME antennas (with sizes as small as one-thousandth of a wavelength) demonstrates 12 orders of magnitude miniaturization over state-of-the-art compact antennas without performance degradation. These ME antennas have potential implications for portable wireless communication systems.

(My emphasis.) It’s an open article, so the whole thing’s available without subscription.

This all looks good, until you read the first paragraph of the article body, where they say increasing frequency is the same as increasing wavelength (it’s exactly opposite.)

btm said:

Acoustically actuated ultra-compact NEMS magnetoelectric antennas

State-of-the-art compact antennas rely on electromagnetic wave resonance, which leads to antenna sizes that are comparable to the electromagnetic wavelength. As a result, antennas typically have a size greater than one-tenth of the wavelength, and further miniaturization of antennas has been an open challenge for decades. Here we report on acoustically actuated nanomechanical magnetoelectric (ME) antennas with a suspended ferromagnetic/piezoelectric thin-film heterostructure. These ME antennas receive and transmit electromagnetic waves through the ME effect at their acoustic resonance frequencies. The bulk acoustic waves in ME antennas stimulate magnetization oscillations of the ferromagnetic thin film, which results in the radiation of electromagnetic waves. Vice versa, these antennas sense the magnetic fields of electromagnetic waves, giving a piezoelectric voltage output. The ME antennas (with sizes as small as one-thousandth of a wavelength) demonstrates 12 orders of magnitude miniaturization over state-of-the-art compact antennas without performance degradation. These ME antennas have potential implications for portable wireless communication systems.

(My emphasis.) It’s an open article, so the whole thing’s available without subscription.

This all looks good, until you read the first paragraph of the article body, where they say increasing frequency is the same as increasing wavelength (it’s exactly opposite.)

Very interesting and its got me thinking about how I can use this in my own stuff

Are they using little magnets to pick up radio signals?

How does this compare with fractal antennas?

> acoustically actuated nanomechanical magnetoelectric (ME) antennas with a suspended ferromagnetic/piezoelectric thin-film heterostructure.

Very very interesting.

> Fractal antennas

Totally different. Fractal antennas are inferior in wideband performance to spiral antennas.

mollwollfumble said:

> acoustically actuated nanomechanical magnetoelectric (ME) antennas with a suspended ferromagnetic/piezoelectric thin-film heterostructure.

Very very interesting.

> Fractal antennas

Totally different. Fractal antennas are inferior in wideband performance to spiral antennas.

So often, you save me much research. Thanks.

mollwollfumble said:

> acoustically actuated nanomechanical magnetoelectric (ME) antennas with a suspended ferromagnetic/piezoelectric thin-film heterostructure.

Very very interesting.

> Fractal antennas

Totally different. Fractal antennas are inferior in wideband performance to spiral antennas.

Only a fraction as good I hear

Cymek said:

mollwollfumble said:

> acoustically actuated nanomechanical magnetoelectric (ME) antennas with a suspended ferromagnetic/piezoelectric thin-film heterostructure.

Very very interesting.

> Fractal antennas

Totally different. Fractal antennas are inferior in wideband performance to spiral antennas.

Only a fraction as good I hear

As you hear is negligible as to what can be recorded.

btm said:

Acoustically actuated ultra-compact NEMS magnetoelectric antennas

State-of-the-art compact antennas rely on electromagnetic wave resonance, which leads to antenna sizes that are comparable to the electromagnetic wavelength. As a result, antennas typically have a size greater than one-tenth of the wavelength, and further miniaturization of antennas has been an open challenge for decades. Here we report on acoustically actuated nanomechanical magnetoelectric (ME) antennas with a suspended ferromagnetic/piezoelectric thin-film heterostructure. These ME antennas receive and transmit electromagnetic waves through the ME effect at their acoustic resonance frequencies. The bulk acoustic waves in ME antennas stimulate magnetization oscillations of the ferromagnetic thin film, which results in the radiation of electromagnetic waves. Vice versa, these antennas sense the magnetic fields of electromagnetic waves, giving a piezoelectric voltage output. The ME antennas (with sizes as small as one-thousandth of a wavelength) demonstrates 12 orders of magnitude miniaturization over state-of-the-art compact antennas without performance degradation. These ME antennas have potential implications for portable wireless communication systems.

(My emphasis.) It’s an open article, so the whole thing’s available without subscription.

This all looks good, until you read the first paragraph of the article body, where they say increasing frequency is the same as increasing wavelength (it’s exactly opposite.)

OK, I admit that I failed to understand how this works.

Looking at Fig 1, am I right in thinking that this type of antennas has only a 6 db gain over an antenna of the same dimensions that doesn’t use piezoelectric and magnetostrictive components?