WO2001025805A1 - Vorrichtung zur hochauflösenden messung von magnetischen feldern - Google Patents
Vorrichtung zur hochauflösenden messung von magnetischen feldern Download PDFInfo
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- WO2001025805A1 WO2001025805A1 PCT/DE2000/003034 DE0003034W WO0125805A1 WO 2001025805 A1 WO2001025805 A1 WO 2001025805A1 DE 0003034 W DE0003034 W DE 0003034W WO 0125805 A1 WO0125805 A1 WO 0125805A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R33/00—Arrangements or instruments for measuring magnetic variables
- G01R33/02—Measuring direction or magnitude of magnetic fields or magnetic flux
- G01R33/035—Measuring direction or magnitude of magnetic fields or magnetic flux using superconductive devices
- G01R33/0354—SQUIDS
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R33/00—Arrangements or instruments for measuring magnetic variables
- G01R33/0017—Means for compensating offset magnetic fields or the magnetic flux to be measured; Means for generating calibration magnetic fields
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S505/00—Superconductor technology: apparatus, material, process
- Y10S505/825—Apparatus per se, device per se, or process of making or operating same
- Y10S505/842—Measuring and testing
- Y10S505/843—Electrical
- Y10S505/845—Magnetometer
- Y10S505/846—Magnetometer using superconductive quantum interference device, i.e. squid
Definitions
- the invention relates to a device for high-resolution measurement, in particular for high-resolution absolute measurement of magnetic fields according to the preamble of claim 1.
- the measuring principle is based on the physical effect of macroscopic quantum interference, as occurs in closed circuits made of superconducting materials, which are coupled to one another by Josephson tunnel contacts or generally, so-called weak links.
- the easily accessible measurement variable is the direct voltage (V (B; I 0 )) dropping across the current loop, which is created by averaging the rapidly changing AC voltage over one or more periods.
- the calibration curve (V (B; I 0 )) of such a typical two contact dc-SQUID is sketched in Fig. 12.
- the calibration curve assumes a minimum, but a maximum for half-number multiples of the elementary flow quant ⁇ 0 .
- the calibration curves of all previously known SQUID systems have such a periodicity. If the area F of the current loop is known, the component of the magnetic induction B perpendicular to this area can be determined up to integer multiples of ⁇ 0 , ie in principle only ⁇ mod ⁇ 0 can be measured. Because of the periodicity of the calibration curve (V (B; I 0 ) ⁇ , conventional SQUIDs cannot therefore be used for the absolute quantitative precision measurement of magnetic induction B.
- Object of the invention is to provide a simple device that enables highly accurate absolute measurement of particular time-varying magnetic fields and can draw in full ⁇ .Umfang on developed for conventional SQUID Cryotechnology.
- the invention is based on a device for high-resolution measurement, in particular for high-resolution absolute measurement of magnetic, in particular time-varying magnetic fields, which comprises a network of transitions between superconductors which show Josephson effects, hereinafter referred to as "contacts", the network has closed meshes, hereinafter referred to as cells, each having at least two contacts, which contacts are superconductively connected, and wherein at least three of these cells are superconducting and / or non-superconducting electrically connected.
- the essence of the invention lies in the fact that the contacts of the at least three cells can be disturbed in such a way that a time-varying voltage drops across at least two contacts of a cell, the temporal mean of which does not disappear, and that the at least three cells are designed in a manner that is geometrically different are that at In an existing magnetic field, magnetic fluxes enclosed by the cells differ in such a way that the frequency spectrum of the voltage response function does not have a significant ⁇ 0 periodic component with respect to the magnetic flux, or that, if a discrete frequency spectrum exists, the contribution of the ⁇ 0 periodic component of the discrete frequency spectrum is not dominant in comparison to the non- ⁇ 0 periodic portion of the discrete frequency spectrum.
- the following functional approach can also be chosen: That the at least three cells are configured differently in such a way that the magnetic fluxes enclosed by the cells in an existing magnetic field are in a relationship to one another such that the period the voltage response function of the network with respect to the magnetic flux penetrating the network cells as a whole is greater or much greater than the value of an elementary flux quantum or the voltage response no longer has a ⁇ 0 periodic component.
- the invention is based on the finding that, in the ideal case, the voltage response function no longer has a period when the magnetic fluxes enclosed by the cells have no rational relationship to one another.
- the surface differences of the individual cells are preferably comparatively large. In this case in particular, superconductively connected cells superposition in such a way that the voltage response function no longer has a period.
- SQIF superconducting quantum interference filters
- the quantum mechanical wave functions which describe the state of the superconducting solid, interfere in such a way that a clear macroscopic calibration curve (v (B; I 0 )) arises.
- the calibration curve (v (B; I 0 ) ⁇ of the superconducting quantum interference filter ideally has no periodicity with the period ⁇ 0 and is a function of the magnitude of the external magnetic field B at the location of the SQIF that increases monotonously in a certain measuring range.
- the unambiguity of the calibration curve and the high sensitivity of superconducting quantum interference filters allow the direct measurement of time-varying electromagnetic fields in a continuous frequency range, the lower bound at v at «0 and the upper bound depending on the type of Josephson contacts used or weak links is currently several hundred GHz to THz. This entire frequency range is accessible with a single, appropriately designed superconducting quantum interference filter.
- the superconducting quantum interference filter operates simultaneously as a receiving antenna, filter and powerful amplifier.
- the inherent noise of suitably designed quantum interference filters can be several orders of magnitude smaller than the inherent noise of conventional SQUID magnetometers.
- Another advantage over conventional antennas and filters is that, due to the measuring principle, the frequency range does not depend on the spatial extent of the superconducting quantum interference filter. The spatial extent can only affect the sensitivity.
- the production of superconducting quantum interference filters can be carried out using known, inexpensive technical processes, such as those used in the modern production of conventional SQUIDs. Since the spatial extent of superconducting quantum interference filters does not have to differ significantly from the spatial extent of conventional SQUID systems, the cryotechnologies developed for conventional SQUID systems can be adopted directly. Special developments in the field of cryotechnology are not necessary.
- the desired effects can also be achieved in a favorable manner if more than two contacts are provided in a cell, which are superconductively connected and electrically are connected in parallel, in the form of a series connection of contacts which is connected in parallel with a single contact, or in the form of two series connections of contacts connected in parallel.
- the effects according to the invention can also be achieved by structures of at least one cell of a network in which, in addition to a basic form of at least two contacts, to which a time-varying voltage that does not vanish on average over time, drops, in particular in addition to a basic form of two electrically connected contacts, a further contact or a plurality of further contacts are provided, which contacts are not energized directly (cf. FIGS. 2b, 2e and 2f) and therefore, on average, no voltage drops across these contacts.
- the connection of all ⁇ contacts in the individual cells is still superconducting.
- Such embodiments can be advantageous since the shielding currents induced by a magnetic field in the individual cells can be reduced by additional contacts. This can reduce the influence of self-inductance and mutual inductance.
- a plurality of cells form a network or a network section in which all contacts are electrically connected in parallel, so that the contacts can be energized in the same direction.
- the cells are connected to one another in a superconducting manner in this connection, particularly great sensitivities for the measurement of a magnetic field can be achieved by such an arrangement.
- the network sections or cells can advantageously also be electrically connected in series, so that the contacts in the network can in turn be energized in the same direction.
- This measure allows the size of the measurement signal to be increased, since the voltages at the contacts add up in the series connection.
- a particularly high sensitivity can also be achieved by connecting Series arrangements of several cells or network sections can be achieved. Since the inherent noise also decreases sharply due to the larger number of cells in such embodiments, this also makes it possible to detect magnetic fields whose strength is several orders of magnitude smaller than in conventional SQUID systems.
- the network sections or cells are preferably connected in a superconducting manner, in particular by means of superconducting twisted-pair cables.
- the resolution of superconducting quantum interference filters can range up to aT (1CT 18 Tesla) and below. The calibration curve remains clear even for such measuring ranges, so that absolute quantitative measurements of extremely small fields are possible.
- the network can be voltage-driven or current-driven.
- the contacts be designed as point contacts.
- the geometry of the cell arrangement be designed in such a way that magnetic crosstalk from one cell to an adjacent cell is reduced on account of the magnetic self-field caused by a current flowing in the cells.
- the network is equipped with a superconducting loop and / or surface arrangement which displaces and / or reinforces the magnetic field in such a way that the magnetic flux generated by a primary magnetic field in these superconducting regions is coupled into the cells of the network becomes.
- a superconducting loop and / or surface arrangement which displaces and / or reinforces the magnetic field in such a way that the magnetic flux generated by a primary magnetic field in these superconducting regions is coupled into the cells of the network becomes.
- Loop arrangements due to the so-called Meissner effect of the superconductor have the property of forcing the magnetic flux penetrating them into their external environment. If a SQIF or SQUID is arranged in this external environment, there is a magnetic field that is greatly increased by this pick-up loop. This applies not only to loop arrangements, but also to flat superconducting areas (so-called washer). In this context, one speaks of "river focusing". It has been found that a SQIF can be coupled to a so-called pick-up loop much better than a conventional SQUID. Because with conventional SQUIDs with a pick-up loop, there is the problem that because of the very different effective area of the SQUID (regularly at most approx.
- the cells of the network and / or network sections are spatially, in particular spatially aligned in two or three dimensions. This measure makes it possible to determine individual magnetic field components in addition to the magnitude of the magnetic field. With a three-dimensional arrangement, the direction of the magnetic field can thus be measured.
- ohmic resistors which are in particular designed as bus-bar resistors, is fed in and / or discharged again. Because measurements have shown that feeding the driving current through ohmic resistors can significantly improve the performance of the SQIF.
- individual cells and / or network sections and / or the entire network are equipped with a compensation circuit for generating a secondary magnetic field such that the magnetic flux generated by a primary magnetic field through individual cells, network sections or the entire network can be compensated in a controlled manner.
- This may be particularly realized by and / or of the entire network is generated a controllable ⁇ static or time-varying magnetic field at the location of individual cells and / or network sections.
- the device according to the invention is preferably connected to an electronic computer, for example in order to evaluate the voltage response of the network or to control the compensation circuit.
- La and b a multi-cell network of parallel connected Josephson contacts in a spatial representation
- 5 shows a symbolically represented spatial arrangement of a superconducting quantum interference filter with an indicated vectorial basis of the three-dimensional space
- 6 shows a schematically illustrated, flat superconducting quantum interference filter with a magnetic field compensation device
- Fig. 8 shows a schematically
- FIG. 10b shows a corresponding to a network according to FIG. 10a
- FIG. 13 shows a schematically illustrated, flat superconducting quantum interference filter with a superconducting coupling loop (pick-up loop) which amplifies the primary magnetic field at the location of the filter.
- La and lb show the physical implementations according to the invention of simple multi-loop networks 1, 2 with Josephson contacts 3, 4, the geometry and detection behavior of which constitute superconducting quantum interference filters.
- the networks 1, 2 consist of superconducting regions 5, 6 which are connected to one another by the Josephson contacts 3, 4.
- the superconducting regions can consist of low-temperature superconducting materials as well as high-temperature superconducting materials.
- the functionality of the network according to the invention also does not depend on the special design of the Josephson contacts (eg break junctions, step junctions, micro bridges, etc.).
- the quantitative information on the exemplary embodiments relates, for example, to the parameter specifications of the typical Josephson contacts from conventional superconductors corresponding to the prior art, for example those Josephson contacts produced with the Nbl AlO x INb technology, as are used in conventional SQUID magnetometers.
- Such contacts have typical critical currents i c of about 200 ⁇ A and a normal resistance r n , which is defined by an ohmic resistance connected in parallel, for example about 1 ⁇ , and a geometric shunt capacitance c n in the picofarad range.
- the spatial extent of the network can be comparable to that of conventional SQUIDs.
- the dimensions of the cells of the networks are then in the range from ⁇ m to mm. Depending on the application, networks according to the invention can also have cells with larger or smaller dimensions.
- the superconducting quantum interference filter is constituted by a flat network 1, 2 from the Josephson contacts 3, 4, which has cells 7 to 13 or 7a to 14a, each of which has two contacts in the current direction.
- the network is characterized in that the individual areas of cells 1 to 9 have a different size and the
- the size of AV depends on the number of cells that the network has and on the choice of the area of the individual network cells, or on their relationships to one another. This is explained in more detail in the theoretical description of the superconducting quantum interference filter which follows in the next paragraph.
- the individual network cells comprise, in addition to the two functionally necessary contacts 3 according to FIG. 2a, a further contact or a plurality of further contacts.
- the contacts are marked as crosses.
- the thick solid lines indicate superconducting connections.
- the thin solid lines can be normal or superconducting.
- the additional contacts can be attached in the individual network cells in such a way that no or only a small part of the driving current flows through them (contacts 3a not directly energized) and, on average, no time-varying voltage drops.
- the shielding currents induced by a magnetic field in the individual cells can be reduced by such embodiments. Furthermore, the influence of self and mutual inductances can be reduced.
- the additional contacts can, however, also be attached in such a way that the driving current I flows through them (directly energized contacts 3b). Also a combination of one contact 3a or more Contacts 3a and a contact 3b or more contacts 3b in single or multiple cells of the network are possible.
- FIG. 4a to 4c show the voltage response function of a conventional single-loop SQUID (FIG. 4a), a conventional multi-loop SQUID with regular unit cells of identical size (FIG. 4b) and a superconducting quantum interference filter (FIG. 4a) for direct comparison. 4c).
- the single-loop SQUID consists of a single superconducting loop or cell with two Josephson contacts
- the driving current I 0 is chosen for all three arrangements such that
- 0 the current per contact has the value 1.1 i c , so that the voltage swing V mM -V mm is the same for all three devices.
- 4d shows the voltage response functions of a conventional SQUID and an SQIFS again using a specific exemplary embodiment. While devices according to the prior art (single-loop SQUID and multi-loop SQUID) have a periodic voltage response function (V) with the period ⁇ 0 such that an absolute measurement of the magnetic field is not possible, the plane superconducting quantum interference filter has one clear voltage response function. This voltage response function of the SQIF enables the absolute quantitative measurement of the magnetic field.
- F an average network cell area
- the resolution limit in these examples can range from 10 "13 T to 10 " 16 T.
- RCSJ resistively and capacitively shunted junction
- the individual Josephson contact is described by a nonlinear inductance, which is connected in parallel with an ohmic shunt resistor r n and a geometric shunt capacitance c n that characterizes the tunnel barrier.
- Equation 1 describes the nonlinear relation between the current /. and the voltage drop across the contact v, (t) in the RCSJ model.
- Equation 2 corresponds to the second Josephson relation, according to which the voltage V j (t) dropping across the contact is directly proportional to the time derivative d t ⁇ j of the phase difference ⁇ j .
- Equation 3 expresses the quantization of the magnetic flux through a closed superconducting loop.
- the network equations resulting from current conservation and equations 1 to 3 link the magnetic field B acting at the location of the network and the driving current I 0 with the voltage V (t) dropping across the circuit.
- the network equation for the SQIF of this exemplary embodiment and generally for SQIFs which consist of network cells connected in parallel can be in the form of a nonlinear differential equation
- the magnetic field B B ext + B c being composed of the primary external field B exl to be measured and possibly a controlled, generated secondary magnetic compensation field B c .
- the structure factor in equation 4 specifies the geometric and dynamic properties of the superconducting quantum interference filter composed of N - 1 cells. It determines the spatial and temporal
- phase shift d ⁇ also depends on the special geometry of the arrangement, but has no influence on the time-averaged voltage response function (V (B; I 0 )).
- N, ie v, (t) defines the superconducting ones.
- Quantum interference filter dropping alternating voltage.
- the directly accessible measured variable can be the direct voltage (V (B; I 0 )) that drops over the network on average over time.
- V (B; I 0 ) the direct voltage
- I 0 the direct voltage
- the influence of inductances and self-fields caused by the driver current is neglected in Equations 4 and 5 for the sake of clarity. Indeed, with a suitable design of the superconducting quantum interference filter, inductances and eigenfields can be minimized so that the functionality of the device is not impaired by these influences.
- Corresponding devices are presented in the further exemplary embodiments.
- this voltage response function is periodic with period ⁇ 0 , as is sketched in FIG. 4a.
- the voltage response function is not periodic. This is shown in Fig. 4c.
- the structure factor S N (B) of the superconducting quantum interference filter can be optimized such that the voltage response function (V (B; I 0 )) has a maximum measuring range
- the maximum operating range of a superconducting network is determined by the maximum compensation field strength that can be achieved.
- the period that may occur is very large in relation to ⁇ 0 and corresponds to - ⁇ A tot if GGT is the greatest common divisor of the amounts
- a typical state-of-the-art value for / 0 is approximately one hundred nm (niobium process).
- the minimum area difference / 0 2 is therefore of the order of magnitude of ⁇ 0 ⁇ 2 ⁇ m 2 with an assumed network cell area of the superconducting quantum interference filter of ⁇ 0 ⁇ 2 mm 2 .
- the period of the voltage response function is given as ⁇ A lot .
- this period is far outside the practically relevant measuring or operating range.
- FIG. 5 Another embodiment of the invention is shown in FIG. 5.
- the network cells disintegrate here into three groups in such a way that, from the oriented surface elements ä m a full vector basis of three-dimensional space can be formed.
- This embodiment of the invention which is hereinafter referred to as vector SQIF has, that the advantage of producing through appropriately designed compensation fields for example in each case a controllable secondary field in parallel to each of the basis vectors formed from the a m, both the thickness and the direction of the primary magnetic to be measured Field can be determined clearly and with very high accuracy. This enables the unambiguous quantitative reconstruction of the primary magnetic field vector B ext according to magnitude, direction and phase, and permits a large number of novel applications.
- the vector SQIF is constructed from three individual plane SQIFs operating independently of one another, the surface normals of which form a vectorial basis of the three-dimensional space.
- This device has the advantage that the individual flat SQIFs can be manufactured without any problems using the standard methods of thin-film technology that correspond to the current state of the art.
- the quantitative measurement can take place here either by simultaneous compensation of the three components of the external magnetic field as in the exemplary embodiment of the last section or by direct measurement of the voltage drop across each individual SQIF.
- the latter measurement method is a further advantage of such arrangements for certain applications, since then no compensation devices are necessary.
- the vector SQIF is constructed in accordance with the last or penultimate section such that the surface normals of the individual SQIFs or the oriented surface elements a m are arranged in such a way that a complete vectorial basis of a two-dimensional subspace of the three-dimensional space is formed from them can be.
- This version can be of advantage if the magnetic field is to be measured only in one plane, for example if the detector fields or memories are flat.
- FIG. 6 shows an embodiment of a flat SQIF in which the magnetic compensation field is generated by two control lines 18, 19, which are parallel to the network and thus perpendicular to the direction of the driving current.
- a current I kl , I k2 flows through one or both control lines 18, 19 in such an arrangement according to the invention, a magnetic flux of known strength which can be controlled very precisely by this current is coupled into the cells of the SQIF.
- This flux can compensate for the flux caused by an external magnetic field in such a way that the voltage drop across the SQIF becomes minimal.
- This so-called operating point then always lies in the absolute minimum of the calibration curve (V (B; I 0 ) j of the SQIF.
- the value of the compensation current since the distance between the control line and the network is known, allows the strength of the external magnetic field to be determined directly the choice of another working point within the measuring range of the SQIFs is possible.
- This embodiment has the advantage that the operational range of the SQIF, ie the range of magnetic field strengths that can be measured with the device, is in principle only limited by field strengths that destroy the phase coherence between the superconducting areas separated by tunnel barriers.
- Another advantage is that in this version SQIFs can still be operated fully functional if the actual measuring range, ie the range in which the voltage response function is unambiguous, becomes very small. This can occur if, due to manufacturing-related tolerances, secondary minima
- the device according to the invention remains fully functional in an embodiment with a compensation circuit.
- Another advantage of an embodiment with control lines is that the compensation circuit is attached on-chip and does not require any additional manufacturing steps.
- the control lines in thin-layer structures can be attached in the layers above or below the network feed lines. Attaching several control lines can also be advantageous, for example if a time-varying compensation field is to be superimposed on a static compensation field for precision measurements.
- SQIFs according to the invention should achieve their maximum sensitivity for operating modes in which time-varying compensation fields are used. In such modes, it is not only possible to determine the strength and direction of the field to be measured simultaneously, but also its phase position. This allows the complete reconstruction of the measured time-varying signal and thus the creation of an identical copy of this signal.
- the advantage of the devices is that such copies can be amplified and passed on without any loss of information.
- the reference symbol 20 denotes symbolically represented bus bar resistors.
- the dash-dotted line describes the limitation of the necessarily superconducting part of the network.
- the compensation circuit is attached outside the SQIF and consists of a pair of coils which is oriented such that the SQIF lies in a plane perpendicular to the axis of the pair of coils between the two coils.
- Such compensation circuits can have the advantage that the magnetic compensation field at the location of the SQIF has a very high degree of homogeneity and thus enables extremely precise measurements.
- Designs in which compensation is carried out locally, that is to say by means of control lines and by means of compensation circuits mounted outside the SQIF, can also be advantageous in order to minimize the influence of disturbances, such as noise and fluctuations.
- SQIFs invention which include compensation circuitry, such as in the form of control lines can also serve as logic devices (actuators) t for ultrafast
- High performance computers are used.
- SQIFs with two local control lines can provide OR logic modules that only switch when the same parallel current flows through both control lines.
- the switching times of such actuators are in the range of the network frequency, ie in the GHz to THz range.
- An advantage of such logic modules is that they act as amplifiers at the same time, since very small control currents already reach the maximum Lead voltage response that is several hundred ⁇ V to mV for today's typical Josephson contacts.
- the active control line 21 brings about a synchronization of the one-dimensional SQIF array even in the case of strongly differing structural factors of the different SQIF sections and parameter inhomogeneities. If the manufacturing tolerances are small, the active control line can also be dispensed with under certain circumstances.
- the advantage of such SQIF arrays which can also be designed in two dimensions, is that the resolution limit of the device decreases with the number of SQIF sections 23 and the gain factor increases with the number of SQIF sections. In the field of magnetic field measurement, such arrangements should, for example, be able to achieve resolution limits that are many orders of magnitude lower than those of conventional SQUID systems when the operating mode is optimally selected. SQIF arrays can also be easily manufactured using state-of-the-art manufacturing processes.
- FIG. 8 An exemplary embodiment in which a plurality of SQIF sections 24 are interconnected in a hierarchically structured SQIF array, is shown in Fig. 8.
- the basic elements of such a hierarchical SQIF array are identical basic SQIFs 24 with an identical structure factor.
- the advantage of such arrangements is that, depending on the relationships between the oriented surface elements of the basic SQIF and the one or more SQIFs at higher hierarchical levels, the interference patterns that are generated at the different levels are caused by the generally different structure factors on the different levels , again interfere with an overall pattern, which enables an extraordinarily high resolution. Since the oriented surface elements d m can be aligned differently in the different hierarchy levels, the resulting interference pattern is also extremely sensitive to the direction of the outer field. According to the current state of production technology, such multi-dimensional SQIF systems cannot be implemented on-chip.
- the overall SQIF therefore does not function, as in Eq. 6 the cable only comes in as an oriented surface element with a vanishingly small area.
- An exemplary embodiment which shows how the inductive couplings effective between the different network cells can be minimized is shown in FIG. 9a.
- Such inductive couplings can reduce the sensitivity of the device if the network consists of a large number of cells. Since a supercritical current flows through each contact, the resulting current distribution creates an eigenfield in this case, which under certain circumstances cannot be neglected.
- the inventive design as shown in FIG. 9b, can greatly reduce the influence of the eigenfields. In FIGS.
- Voltage response function corresponds to that according to Eq. 8.
- the driver current I 0 is fed in and out again by bus-bar resistors 29 corresponding to the state of the art, the distance of which from the network can be chosen large enough.
- An alternative embodiment of an SQIF, which also minimizes the mutual inductive influences, is shown in FIG. 9c.
- FIG. 10a An embodiment in which the various network cells are connected in series is shown in FIG. 10a.
- the oriented surface elements a m are also selected here so that the voltage response function of the network is not periodic or only has a very large period in comparison to ⁇ 0 .
- B 0 the global absolute minimum of this voltage response function.
- the parasitic mutual inductances can be minimized with such arrangements.
- series connections in manufacturing can have technical advantages.
- an increased packing density is possible, which can be advantageous when integrating the circuits on a chip.
- the oriented surface elements a n were arranged in a flat series arrangement according to the arithmetic relation na
- FIG. 10a a typical coupling and control circuit is shown schematically in FIG. 10a.
- a magnetic compensation field is generated by the Kompensationsström I comp at the location of the individual ⁇ etzwerkzellen that compensates an external field and / or which is produced by the current I inp the field.
- the current I inp is about the input current of a pick-up loop or another signal source.
- Series SQIFs can also be of great advantage because the intrinsic noise of the circuit, e.g. when used as a (current) amplifier, only increases proportionally to VN, while the voltage swing increases proportionally to N.
- the periodicity properties of the voltage response function are an essential feature of quantum interference filters according to the invention.
- the frequency spectrum of the voltage response functions of SQIFs according to the invention in relation to the magnetic flux therefore clearly differs from conventional SQUID interferometers corresponding to the prior art. This situation is shown in FIGS. 11a to 11d using typical frequency spectra from SQUIDs corresponding to the prior art (FIGS. 11a and 11b) and quantum interference filters according to the invention (FIGS. 11c and 11d).
- FIG. 11a shows the typical voltage response function of a conventional SQUID in the upper image.
- the (V ( ⁇ )) curve is periodic with the period ⁇ 0 .
- the associated frequency spectrum in the lower image of FIG. 11a accordingly shows a dominant amplitude at 1 ⁇ 0 . Since the voltage response function of a SQUID is not harmonic (see Eq. 8), even higher harmonic modes occur at 2 ⁇ 0 and 3 ⁇ 0 , which, however, only have a very small amplitude.
- the frequency spectrum of conventional SQUIDs is thus dominated by the ⁇ 0 periodic contribution.
- FIG. 11b shows, this is also the case with multi-loop arrangements which are made up of identical network cells, regardless of whether they are serial arrangements or
- quantum interference filters according to the invention have no dominant anten 0 periodic contribution in the frequency spectrum of their voltage response functions. This fact is shown in FIGS. 11c and 11d.
- the frequency spectra in FIGS. 11a to 11c (lower images) are plotted in the same arbitrary units, so that a direct comparison is possible.
- the voltage response and the associated frequency spectrum of a quantum interference filter according to the invention, which has no periodicity, is shown in FIG. 11c.
- the spectrum is practically continuous, a discrete spectrum does not exist. In particular, there is no significant ⁇ 0 periodic contribution.
- the amplitudes of the practically continuous spectrum are two or an order of magnitude smaller than in the conventional arrangements according to FIGS. 11a and 11b.
- the voltage response function and the associated spectrum of a quantum Interference filter shown which has a technical periodicity.
- the voltage response function has the property that its period is much larger than ⁇ 0 and the frequency spectrum has a discrete part with a very small amplitude at the period ⁇ 0 .
- This amplitude at the period ⁇ 0 is not significant and in any case does not make a dominant contribution to the frequency spectrum.
- the discrete spectrum is also distinguished in turn by the fact that its amplitudes are one to two orders of magnitude smaller than in the conventional arrangements.
- the frequency spectra of quantum interference filters according to the invention are robust with regard to the ⁇ 0 periodic contribution of the frequency spectrum. Parameter imperfections or geometric imperfections do not change the qualitative properties of arrangements according to the invention described above.
- FIG. 13 schematically shows an exemplary embodiment of a flat SQIF 30 which is provided with a superconducting coupling loop (pick-up loop).
- a superconducting coupling loop pick-up loop
- Such coupling loops strengthen the primary magnetic field by displacing the flux generated by this field inside them.
- Such devices have the advantage that the primary magnetic field at the location of the SQIF can be greatly increased by a suitable arrangement.
- Another advantage of SQIFs is that the total area of SQIFs can be designed so that the impedance mismatch between pick-up loop and SQIF is minimized. The sensitivity and resolution of SQIFs can be significantly increased by such devices.
- superconducting surfaces instead of a pick-up loop, superconducting surfaces (so-called washer) can also be used, which also lead to the advantages mentioned.
- the coupling of a gradiometer loop is also possible and leads to the mentioned Advantages when measuring magnetic field gradients.
- suitably designed superconducting coupling loops are
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Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2001528714A JP4180275B2 (ja) | 1999-10-04 | 2000-09-05 | 磁界の高精度測定用装置 |
DE50004918T DE50004918D1 (de) | 1999-10-04 | 2000-09-05 | Vorrichtung zur hochauflösenden messung von magnetischen feldern |
EP00972574A EP1135694B1 (de) | 1999-10-04 | 2000-09-05 | Vorrichtung zur hochauflösenden messung von magnetischen feldern |
DK00972574T DK1135694T3 (da) | 1999-10-04 | 2000-09-05 | Anordning til højtopløsende måling af magnetiske felter |
AT00972574T ATE257248T1 (de) | 1999-10-04 | 2000-09-05 | Vorrichtung zur hochauflösenden messung von magnetischen feldern |
AU11287/01A AU1128701A (en) | 1999-10-04 | 2000-09-05 | Device for high resolution measurement of magnetic fields |
US09/857,269 US6690162B1 (en) | 1999-10-04 | 2000-09-05 | Device for high-resolution measurement of magnetic fields |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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DE19947615 | 1999-10-04 | ||
DE19947615.2 | 1999-10-04 |
Publications (1)
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WO2001025805A1 true WO2001025805A1 (de) | 2001-04-12 |
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PCT/DE2000/003034 WO2001025805A1 (de) | 1999-10-04 | 2000-09-05 | Vorrichtung zur hochauflösenden messung von magnetischen feldern |
Country Status (10)
Country | Link |
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US (1) | US6690162B1 (de) |
EP (1) | EP1135694B1 (de) |
JP (1) | JP4180275B2 (de) |
AT (1) | ATE257248T1 (de) |
AU (1) | AU1128701A (de) |
DE (2) | DE50004918D1 (de) |
DK (1) | DK1135694T3 (de) |
ES (1) | ES2213620T3 (de) |
PT (1) | PT1135694E (de) |
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- 2000-09-05 DK DK00972574T patent/DK1135694T3/da active
- 2000-09-05 AT AT00972574T patent/ATE257248T1/de active
- 2000-09-05 DE DE50004918T patent/DE50004918D1/de not_active Expired - Lifetime
- 2000-09-05 AU AU11287/01A patent/AU1128701A/en not_active Abandoned
- 2000-09-05 JP JP2001528714A patent/JP4180275B2/ja not_active Expired - Fee Related
- 2000-09-05 DE DE10043657A patent/DE10043657A1/de active Pending
- 2000-09-05 WO PCT/DE2000/003034 patent/WO2001025805A1/de active IP Right Grant
- 2000-09-05 ES ES00972574T patent/ES2213620T3/es not_active Expired - Lifetime
- 2000-09-05 EP EP00972574A patent/EP1135694B1/de not_active Expired - Lifetime
- 2000-09-05 PT PT00972574T patent/PT1135694E/pt unknown
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Cited By (7)
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JP2005534930A (ja) * | 2002-08-02 | 2005-11-17 | ケスト クヴァンテンエレクトローニーシェ システーメ テュービンゲン ゲーエムベーハー ズィッツ ボブリンゲン | 磁力計 |
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WO2004114463A1 (de) * | 2003-06-13 | 2004-12-29 | QEST Quantenelektronische Systeme Tübingen GmbH Sitz Böblingen | Supraleitende quantenantenne |
US7369093B2 (en) | 2003-06-13 | 2008-05-06 | Qest Quantenelektronische Systeme Gmbh | Superconducting quantum antenna |
WO2007078889A3 (en) * | 2005-12-29 | 2008-04-10 | Intel Corp | Optical magnetometer array and method for making and using the same |
RU2483392C1 (ru) * | 2011-12-14 | 2013-05-27 | Учреждение Российской академии наук Институт радиотехники и электроники им. В.А. Котельникова РАН | Сверхпроводящий прибор на основе многоэлементной структуры из джозефсоновских переходов |
Also Published As
Publication number | Publication date |
---|---|
EP1135694B1 (de) | 2004-01-02 |
DE10043657A1 (de) | 2001-07-12 |
EP1135694A1 (de) | 2001-09-26 |
JP4180275B2 (ja) | 2008-11-12 |
US6690162B1 (en) | 2004-02-10 |
DE50004918D1 (de) | 2004-02-05 |
JP2003511853A (ja) | 2003-03-25 |
PT1135694E (pt) | 2004-05-31 |
DK1135694T3 (da) | 2004-05-03 |
ATE257248T1 (de) | 2004-01-15 |
AU1128701A (en) | 2001-05-10 |
ES2213620T3 (es) | 2004-09-01 |
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