The "Unwired Energy" Update item (PHYSICS
TODAY, January 2007, page 26) reports a wireless energy-transmission system working over a few
meters, proposed by Marin Soljačić,
Aristeidis Karalis, and John Joannopoulos of MIT.
The item concludes with
the statement that "Soljačić
and his MIT colleagues are now working on demonstrating the technology in practice." I strongly
recommend that they consult with the MIT Radio Society and the Federal Communications Commission
(FCC) before testing anything, since simple calculations show that their system would be a terrible
and illegal electromagnetic polluter.
The system proposed by
the researchers uses conducting wire rings that are series-resonated with capacitors and that
operate at a frequency of 6.4 MHz. Practical examples of these resonated rings for 7.0 MHz are sold
by various vendors.
The proposed system provides
4 watts of output from the receiving ring, at a cost of 11 W dissipated as heat in the transmitting
ring and 1.5 W of power radiated from the system. Simple calculation shows that the 1.5 W exceeds
the FCC's radiated-emission power limit by a factor of 800 000.
As most amateur radio operators
know, 1.5 W of radiated power at 7.0 MHz is enough for worldwide radio communications under good
conditions, and indeed some of the resonated rings available for purchase are marketed as radio
antennas.
The 3- to 30-MHz frequency
range is intensively used for long-distance radio communications and broadcasting even today,
because it is the only channel that provides long-distance communications with no transmission
infrastructure at all.
I consider it deeply unwise
to pollute this unique channel for the sake of short-range systems.
I was somewhat bewildered
by the "Unwired Energy" Physics Update.
Energy transfer using
electromagnetic resonance is used today in thousands of locations around the world—door
locks, toll roads, and many more upcoming applications such as airport luggage tracing and supermarket
checkouts. All RFID (radio-frequency identification) tags are powered with LC resonant circuits.
Actually, nearly 50 years
ago, when I was in primary school, I built a diode radio receiver that drew operating energy from
a circuit tuned to a radio-station frequency. A diode was used to detect the signal that drove an
earphone. No battery was involved.
I don't think the MIT work
is really new physics but rather an attempt at improved engineering for, say, transferring sufficient
energy to drive laptops. Radiating hundreds of watts of RF in a room or several thousand watts in
a coffee shop seems to me to be too risky for people and will not be accepted.
Karalis, Kurs, Joannopoulos,
and Soljačić
reply: The results presented in our theoretical work1 are relatively simple
examples of how to implement our proposed scheme for wireless energy transfer. In practice, the
system could be designed to operate at frequencies outside the ham radio band, to perform much better
than Peter Anderson states (see, for example, section 4 of reference 1) by improving on the materials
and geometries used, and to radiate below general safety and interference limits—for example,
the IEEE (Institute of Electrical and Electronics Engineers, Inc) standards for general public
exposure.2 Safety and interference issues are very important and will have to be thoroughly
investigated before any product development.
The physics of electromagnetic
resonance and its use for transferring energy wirelessly has long been known and used to provide
relatively low levels of power to various applications, as Herzel Laor states. Existing resonant-electromagnetic-induction
technology has been inadequate to efficiently power, over mid-range distances, devices that
require on the order of tens of watts of power or more. Our work demonstrates that it is the physics
of strong coupling, for which resonance is a prerequisite, that enables the efficient wireless
energy transfer needed for larger power applications.1 The principles of this physical
concept will certainly lead to improved engineering in designing actual systems.
In addition, strong coupling
implies that the scheme is not radiative but rather uses the near stationary field; therefore,
"hundreds of watts of RF" are not being radiated by our method, as numerical examples in
reference 1 demonstrate.
References
1. A. Karalis, J. D. Joannopoulos, M. Soljačić, Ann. Phys. (in press); preprint at [LINK].
2. For a detailed analysis, see the supporting online material with A. Kurs, A. Karalis, R. Moffatt, J. D. Joannopoulos, P. Fisher, M. Soljačić, Science317, 83 (2007)[MEDLINE].
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