The present invention relates to the field of time-keeping devices and in particular to the field of devices known as atomic clocks.
Devices called atomic clocks have been known for several decades and are able to keep time with very high precision. Conventional atomic clocks use atoms in a gas phase that can undergo transitions that correspond in energy to electromagnetic radiation in the microwave part of the spectrum. In one example a tunable microwave cavity contains the gas and the cavity can be tuned such that the field in the cavity oscillates very stably at a frequency corresponding to the energy transition in question. The most precise clocks at present are based on atomic fountains of cold atoms such as caesium or rubidium. Recently there have been developments using oscillations at frequencies corresponding to the optical (visible) part of the electromagnetic spectrum.
The availability of very high stability frequency standards, and the time-keeping that they provide, is used in many fields, including the synchronization of communication networks and in positioning systems, such as the satellite-based global positioning system (GPS). Conventional atomic clocks are generally quite large, delicate and have significant power requirements while operating. Thus there are the problems of providing compact, reliable, portable, low power atomic clocks.
Some proposals have been made regarding using endohedral fullerenes in a solid state atomic clock, see for Example U.S. Pat. No. 7,142,066. However, there are still problems regarding reducing environmental influence on the time-keeping, especially in portable devices, and also problems with achieving practical measurement and control of such systems.
The present invention aims to alleviate, at least partially, some or any of the above problems.
The present invention provides an apparatus comprising:
a condensed matter medium comprising at least one system that has at least a pair of states, said states comprising a first state and a second state with respective energy levels, said energy levels having an energy difference therebetween, wherein the energy difference varies as a function of applied magnetic field;
a magnet device arranged to apply an adjustable magnetic field to the medium;
an excitation device arranged to cause the at least one system to undergo transitions between said pair of states; and
a detection device arranged to detect the response of the at least one system induced by the excitation device and to produce an output; and
a controller for receiving the output of the detection device and arranged to control the magnet device such that the magnetic field applied to the medium has a value at which the rate of change of said energy difference with change in magnetic field is substantially zero, and to derive oscillations at a frequency determined by the energy difference between said pair of states between which the at least one system is caused to undergo transitions.
Embodiments of the invention will now be described, by way of non-limiting example, with reference to accompanying drawings, in which:—
Referring to
An excitation device 14 both excites each system 11 of the medium 10 to cause it to undergo transitions which generate the time-keeping oscillations, and also probes the medium 10 such that the oscillations can be measured and the device controlled.
A detection device 16 is used to sense the response of the medium 10 induced by the excitation device 14. The output of the detection device 16 is fed to the controller 18. The controller 18 produces the output 19, which is the clock signal or frequency standard, and also controls the magnet device 12 and the excitation device 14.
Although the components in
Each of the components of
1. The Medium
In this preferred embodiment, the medium 10 is made of condensed matter, such as a solid, whether crystalline or non-crystalline, or such as a glass or other highly viscous material, or such as a liquid solution.
The medium 10 comprises a plurality of systems 11 capable of undergoing transitions between states which have an energy difference corresponding to a particular oscillation frequency. In the preferred embodiment, the systems are endohedral fullerenes.
The term “Fullerene” refers to a cage-like structure formed of carbon atoms and also known as carbon buckminster-fullerene or bucky-balls. The cage can be written as Cn, and the cage can be of various sizes; preferred embodiments include n=60, 70, 74, 80, 82, 84 and 90, but this is not an exhaustive list. C60 is spherical, but the other fullerenes are elongated. The diameter of the fullerene is typically of the order of 1 nm. The term fullerene used herein also encompasses derivates of the basic buckminster-fullerene cages.
The term “Endohedral” means that a species is located within the fullerene cage. According to one embodiment, the endohedral species is a single atom of an element. In some endohedral fullerene systems the endohedral species donates one or more electrons to the cage. Known examples of atomic endohedral species include Er, Gd, P, La, Lu, N, Sc, Tm, Y, Ho or Pr, in a variety of different size fullerene cages. Preferred endohedral species include any Group V element (N, P, As, Sb or Bi). One preferred embodiment is endohedral nitrogen in Co (i.e. a single nitrogen atom inside a carbon bucky-ball, written as N@C60). Diatomic endohedral species are also known, such as Er2, Hf2 or La2. Other preferred embodiments include trimetallic nitride templated endohedral metallofullerenes (TNT EMFs) of the form M3N@Cn where M can be one or more metal elements (for example Sc or Er, or a combination), and n is preferably 80, but can take other values.
Preferably each system 11 is substantially identical. Endohedral fullerenes are attractive for use in an atomic clock because the endohedral species is shielded from the environment by the carbon cage. This means that both the electron and nuclear spin lifetime and coherence time of the endohedral species can be very long which is advantageous for stable frequency operation.
The endohedral fullerenes can be embedded in a solid matrix, either in a random manner or in a specific pattern. Furthermore, the endohedral fullerenes may be provided within other structures, such as carbon nanotubes. A solid substrate can be provided to support the endohedral fullerenes and the matrix or other structures. The endohedral fullerenes may be in the form of a crystalline solid or powder, or may be deposited on a surface in a continuous layer or using a supramolecular template, or they may be in solution. The concentration may be diluted to reduce spin-spin dephasing and thereby increase Te2 (the electron spin coherence time). For example, a concentration of the order of 10E15 molecules of N@C60 per millilitre (number density of molecules per cm3) or lower, provided that it is reasonably uniformly dispersed, typically provides a spin decoherence time that is not limited by dipole-dipole interactions. Higher concentrations can be used, but, at significantly higher concentrations, the decoherence time deteriorates. The invention is not limited to a particular concentration or range of concentrations. [Throughout this specification the exponential notation xEy is used and is equivalent to x×10y]
Two preferred examples of endohedral fullerenes for use in this embodiment of the invention are N@C60 and P@C60. However N@C60 is the presently preferred choice because it offers superior spin properties and thermal stability and does not have the significant safety hazards associated with the production of P@C60, though P@C60 is still one option. For N@C60 the electron spin lifetime Te1 can be as long as at least 0.1 ms at room temperature and the coherence time Tee approximately ⅔ Te1. The nuclear spin lifetime Tn1 and coherence time Tn2 are also extremely long, for example at low temperature Tn1 can be almost arbitrarily long (several hours at 4.5 K).
Both N and P offer isotopes with nuclear spin I=½. This nuclear spin value is preferred because it has only two possible values along any given axis, such as an axis imposed by an applied magnetic field, namely +½ and −½; this eliminates some sources of decoherence such as nuclear quadrupole broadening and carbon hyperfine broadening. Therefore, in the preferred embodiment, either one or both of the N and/or C are isotopically purified forms, but this is not essential to the invention. The preferred endohedral fullerene molecule is therefore 15N@12C60.
2. Magnet Device
The magnet device 12 comprises one or more miniature coils for applying a magnetic field to the medium 10. The miniature coils can be, for example nanocoils or coiled nanowire and can be fabricated by techniques such as lithography. In one example a coil encircles the medium 10; in another example a single coil is provided on one surface of the medium 10 (this is especially suitable in examples in which the medium 10 is extremely thin); in another alternative a pair of coils are provided located at opposite surfaces of the medium 10 (i.e. like a pair of Helmholtz coils). The magnet may optionally have a soft ferromagnetic core, but for the low magnetic fields typically required this is not necessary.
3. Excitation and Detection Device
The excitation device 14 comprises a source of electric, magnetic or electro-magnetic oscillations at one or more frequencies. In the preferred embodiment, as discussed below, the frequencies correspond to the microwave part of the electro-magnetic spectrum, for example, tens of MHz. The microwave frequency source can be a simple analogue oscillator or a digital synthesiser. There is a wide choice of known cavity design. Features from the field of electron spin resonance (ESR) measurement may be employed, for example standard ESR spectrometers use cylindrical split ring resonators. Another alternative is a microwave stripline resonator; this could even incorporate more than one resonant frequency by having striplines angled with respect to each other.
The detection device 16 detects absorption at the excitation frequencies, either by directly measuring the change in field strength, or by detecting a change in the transparency of the medium. One example is a microwave sensor. Another example is circuitry to detect the impedance of the resonant cavity—change in impedance implying change in absorption. The detection device 16 may be separate from the excitation device 14, as shown in
In the preferred implementation of the invention, the detection is performed using spin resonance. There are two approaches to using spin resonance for this purpose: continuous wave spin resonance and pulsed spin resonance. Using continuous wave spin resonance, detection is achieved by observing an absorption of the applied microwaves; this can be detected as a change in impedance of the resonant cavity containing the spin species. Using pulsed spin resonance, detection is achieved by observing the induction from a precessing magnetic moment in the sample; this can be achieved by applying a sequence of pi and pi/2 pulses, and observing spin echo, as is done in the field of magnetic resonance imaging (MRI).
4. Controller
To understand the controller 18 and the operation of the apparatus, first the energy levels of each system 11 in the medium 10 will be explained, with particular reference to 15N as the endohedral species in an endohedral fullerene such as N@C60.
H=gμ
B
BS
z
+g
nμnBIz+AS·I
where:
B is the magnetic field (T) in a direction defining a z-axis;
S is the total electron spin (Sz being the component in the z-direction);
I is the total nuclear spin (Iz being the component in the z-direction); and where the parameters used are as follows:
g is the electron gyromagnetic ratio, g=2.0023;
μB is the Bohr magneton, μB=9.2847E-24 J T−1;
gn, is the nuclear gyromagnetic ratio, gn=−0.566;
μn is the nuclear magneton, μn=5.051E−27 J T−1;
A is the hyperfine coupling constant, A=1.4508E−26 Hz
At zero magnetic field two discrete energy levels are apparent. These arise from the splitting of the ground state of the N atom into two states depending on whether the electronic magnetic dipole moment is parallel or antiparallel with the nuclear magnetic dipole. These two states are non-degenerate and so have different energy levels. A transition of the N atom between these two states arising from the magnetic dipole-dipole interaction is known as a hyperfine transition. When a magnetic field is applied, each of the energy levels splits into a plurality of levels as can be seen in
In
The transition AB corresponds approximately to a frequency of 38 MHz (more precisely 37.9 MHz). The frequency f of an oscillation is related to the energy difference E by Planck's Constant h: E=hf. According to this embodiment of the invention, the apparatus is operated to use a transition whose frequency (i.e. energy difference) shows zero first-order dependence on magnetic field. This has the advantages of: (i) minimising errors due to fluctuations in external magnetic fields (these magnetic field fluctuations can arise from external electrical and electronic sources and from the earth's magnetic field as the orientation of a portable device containing the atomic clock changes), these external magnetic fields can even partially penetrate through shielding which is provided around the apparatus; and (ii) minimising decoherence arising from fluctuations in the electron spin.
The operation of the apparatus will now be described with reference to the controller 18 shown in
(a) Magnetic Field Stabilisation
A first oscillator 40 produces an oscillating signal at a first frequency fB. The frequency of oscillation is determined by, for example, a quartz crystal 42 or any other suitable frequency reference. The oscillating signal is provided to a driver 44 which produces an output 45 to drive the excitation device 14 of
(b) Clock Frequency Determination
In the present embodiment, the transition AB, whose frequency is independent of magnetic field to first order, has a dipole strength between the two levels that is too low to be useful, so cannot be directly probed. However, each level A and B has a transition to a third level C, indicated by the arrows AC and CB in
In practice one way to achieve this is by using the first oscillator 40 also to provide a carrier frequency fC (equal to fB) and a second oscillator 50 to provide a second frequency fD for symmetrical sidebands of frequency fC±fD. Although the first and second oscillators 40, 50 are shown as separate units in
The carrier and sideband frequencies are supplied to the excitation device 14 by the driver 44. In the present embodiment the excitation device is a microwave generator and the central carrier frequency fC is 32.8 MHz and the symmetrical sidebands are of frequency 32.8±19 MHz, i.e. the frequency fD is 19 MHz.
In the preferred embodiment the excitation is provided in a continuous wave (CW) manner, which is simple to control, however, it is also envisaged that the excitation may be pulsed.
Alternative transitions using a different third energy level to access the transition AB can, of course, be used, for example using the energy level indicated D in
The detection device 16 detects the response of the medium 10 to the applied frequencies. When the frequency fD is selected such that the value 2fD matches the transition AB, then at that resonance the medium 10 shows a minimum in absorption, i.e. in this resonant scheme the medium becomes approximately transparent to radiation at the relevant frequency. The clock stabilisation 52 circuit receives the output of the detection device 16 and uses feedback to adjust the frequency fD in order to achieve this resonance. The frequency fD is output at the terminal 19 and is, of course, the frequency standard that is the output of this “atomic clock”.
The strength of the resonant absorption varies as dACdCBB1B2/(Δ+Γ), where dAC and dCB are the matrix elements of those transitions, B1 and B2 are the microwave magnetic field magnitudes for those two transitions, Δ is the detuning and η is the reciprocal lifetime. As long as the centre frequency fC is within approximately η of the correct frequency, then the performance of the apparatus is not strongly sensitive to the error represented by Δ. The clock stabilisation circuit 52, may, of course, optionally also use feedback to adjust fC to maximise the response of the medium 10, but the precision of the clock does not depend critically on fC.
According to the present embodiment of the invention, because the apparatus is operated in a regime in which the transition AB (corresponding to a frequency 2fD) has no first order dependence on magnetic field, any drift in magnetic field (for example from external influences such as orientation of the device relative to the earth's magnetic field) or any imprecision in the control of the magnetic field applied to the medium, will affect the frequency fD only to second order. This means the frequency error will be less than one part in 1012 for an error of one part in 106 in the reference frequency, such as provided by the quartz crystal 42 or similar. Therefore this atomic clock is six orders of magnitude more accurate than the reference oscillator, but can still be used for portable or small-scale applications. Because the error is quadratic with the magnetic field error, an improvement in precision of one order of magnitude in the reference frequency (e.g. of the quartz crystal) offers an improvement of two orders of magnitude in the clock frequency, up to the limit of the decoherence rate of the electron spin. Therefore, in applications where increased power consumption is less critical, performance can optionally be improved by, for example, controlling the temperature of the quartz crystal providing the reference frequency, such that the temperature is substantially constant.
In this embodiment of the invention, the frequency of the first oscillator 40 is used both in the control of the magnetic field (by probing a separate resonant absorption) and as the central (carrier) frequency of the double sideband signal for the clock frequency determination. This arrangement is convenient and requires fewer components, and is preferred for its simplicity. However, in an alternative embodiment, separate oscillator frequencies fB, fC could be used for the two functions, which would give greater freedom for the choice of frequency of the resonant absorption used for the magnetic field stabilization. For example, in the above case, using 15N@C60 and a working magnetic field of 0.78 mT, the transition from the lowest level to the next lowest level (in
In the scheme described above, the spin system 11 is effectively used to multiply the precision of the oscillation frequency of a reference oscillator, such as the quartz crystal oscillator 42. However, in a further modification of this embodiment of the invention, the crystal reference oscillator 42 can be dispensed with altogether. The frequency fB of the transition which is field dependent is approximately a rational multiple or fraction of the desired clock frequency fD. A low precision oscillator is configured to generate an initial frequency in the vicinity of fB, the resonant absorption of the medium at approximately the desired applied magnetic field. A feedback loop modifies the magnetic field so as to ensure that the two frequencies fB and fD have the desired ratio, thereby guaranteeing that the magnetic field is correct to give a value of fD with no first order dependence on magnetic field. Thus the system locks onto the high precision frequency of oscillation required for the frequency standard output of the atomic clock. In this way the quartz crystal or similar for the reference oscillator (which in some cases needs to be temperature stabilized) is unnecessary; a low-precision and therefore cheaper oscillator (such as a simple inductor-capacitor LC resonant circuit) can be used to provide the initial reference frequency.
In any of the above embodiments, the transitions are preferably selected such that the frequency of the resonant absorption fB used for magnetic field stabilisation is a rational multiple or fraction of the clock transition (AB) frequency, or more preferably a rational multiple or fraction of half the clock transition (AB) frequency. In the symmetric sideband scheme, the transition AB corresponds to a frequency 2 fD, so half that frequency is fD; thus, in one example, the frequencies are related as follows:
fB=nfD
where n is an integer; in a preferred example n=2. In this way, a reference oscillator need only be provided for one of the frequencies, and the other frequency can be derived simply by using a frequency multiplier or divider, or standard digital electronics.
Number | Date | Country | Kind |
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0712696.4 | Jun 2007 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2008/002229 | 6/27/2008 | WO | 00 | 5/13/2010 |