Abstract:
The present invention relates to a method and a device for providing a current of spin-polarised electrons. More particularly, the present invention is suited for use in spin electronics or detection of spin-polarised electrons.

Description:
CLAIM OF PRIORITY 
       [0001]    This application claims the benefit of priority under 35 U.S.C. §119 (a)-(d) of Great Britain Patent Application Serial Number 1101862.9, entitled “SPIN FILTER DEVICE, METHOD FOR ITS MANUFACTURE AND ITS USE,” filed on Feb. 3, 2011, the benefit of priority of which is claimed hereby, and which is incorporated by reference herein in its entirety. 
       TECHNICAL FIELD 
       [0002]    The present invention relates to a method and a device for providing a current of spin-polarised electrons. More particularly, the present invention is suited for use in spin electronics or detection of spin-polarised electrons. 
       BACKGROUND 
       [0003]    The generation of a current of spin-polarised electrons, in which all electron spins point mostly in the same direction, is a central aspect of spin electronics (hereafter also called spintronics). Spintronics, or spin electronics, refers to the role played by electron spin in solid state physics, and to devices that specifically exploit spin properties, i.e. spin degrees of freedom, instead of, or in addition to, charge degrees of freedom. For example, spin relaxation and spin transport in metals and semiconductors are of interest in fundamental research such as solid state physics and more generally in other electronic technology areas. Extensive research and development is carried out in the field of spintronics with the objective to fully utilise the advantage that no electron charges need to be transported which would cost energy and produce heat. 
         [0004]    To date, currents of spin-polarised electrons are predominantly obtained from magnetic or magnetized materials. When the spin has to be inverted the applied external magnetic field needs to be inverted. This is typically intrinsically slow to carry out, and would thus be inefficient for many applications. 
         [0005]    Furthermore, currents of spin-polarised electrons can be obtained when circularly polarised light ejects electrons from substrates with large spin-orbit coupling, for example gallium arsenide (GaAs). 
         [0006]    In the above mentioned methods, the materials used are prepared in complex preparations under ultra-high vacuum (UHV) conditions. Thus, their integration into large scale integrated circuits or even printed circuits is difficult. 
         [0007]    An important attribute of free spin-polarised electrons is the degree of polarisation. The degree of polarisation of free spin-polarised electrons is presently measured by so called Mott scattering of high energy electrons on thin gold foil under high vacuum conditions. The high energy electrons are in the region of more than 50 kV and the thin gold foil is in the region of a few nanometers. Alternatively, the degree of polarisation of free spin-polarised electrons can be measured by spin-dependent diffraction at surfaces of wolfram (W) or iron (Fe) under ultra-high vacuum conditions (less than 10 −10  mbar). However, both methods for detecting spin-polarised electrons are technically complex and prone to errors. 
       BRIEF SUMMARY OF THE INVENTION 
       [0008]    The present invention provides a spin filter device with the features of claim  1 , a method for manufacturing a spin filter device of claim  6  the use of a spin filter device of claim  9  and a spintronic transistor structure with the features of claim  15 . Further dependent claims describe preferred embodiments. 
         [0009]    It is one object of the present invention to provide a method and system which overcomes at least some of the problems relating to spin-polarised electrons. 
         [0010]    It is thus an object of the present invention to provide a method and device for obtaining spin-polarised electrons which can be integrated and used in large scale integrated circuits, printed circuits and/or spintronic applications in general. 
         [0011]    It is a further object of the present invention to provide a method and device for detecting spin-polarised electrons which can be employed without the need of complex and error-prone equipment. 
         [0012]    It is a further object of the present invention to achieve high efficiency in spin selectivity. 
         [0013]    According to an aspect of the present invention, there is provided a spin filter device including
       a substrate and   at least one monolayer deposited upon said substrate;
 
wherein said monolayer comprises asymmetrical molecules, and is adapted to filter electrons travelling from said substrate through said at least one monolayer such that electrons that exhibit a predetermined spin can pass.
       
 
         [0016]    Optionally, the molecules of said at least one monolayer are chiral molecules. Chiral molecules lack mirror image symmetry and show two types of enantiomers that can be described as left-handed (L- or levo-) and right-handed (D- or dextro-) species. When a charge moves within a chiral system in one direction it creates a magnetic field as a result of so called broken mirror image symmetry. 
         [0017]    Optionally, the substrate can be one of a metal or a semiconductor. 
         [0018]    The substrate can optionally be polycrystalline or single crystalline. An example of the substrate suitable for the spin filter device of the present invention can include, but is not limited to, polycrystalline gold (Au) or single crystalline gold (Au(111)). 
         [0019]    Optionally, the at least one monolayer can be self-assembled on the substrate, produced for example in a wet chemical procedure. 
         [0020]    The said at least one monolayer can optionally comprise organic molecules. 
         [0021]    Optionally, the said at least one monolayer can comprise nano-particles, particularly nano-dots. 
         [0022]    The molecules of the said at least one monolayer can optionally be thiolated molecules. An example of the thiolated molecules suitable for the spin filter device of the invention can include, but is not limited to, double stranded DNA. Double stranded DNA is chiral both because of its primary structure and because of its secondary, double helix structure. The molecules can have a predetermined length, e.g. the double stranded DNA can comprise for example 26, 40, 50, 78 or any other number of base pairs (bp) as considered appropriate for particular application of the present invention. 
         [0023]    According to an aspect of the invention, there is provided a method for manufacturing a spin filter device, the method including the steps of
       (a) providing a substrate;   (b) depositing at least one monolayer upon the substrate;
 
wherein the at least one monolayer comprises asymmetrical molecules adapted to filter a current of electrons such that electrons that exhibit a predetermined spin can pass to generate a current of spin-polarised electrons.
       
 
         [0026]    The substrate and the at least one monolayer can include all or selected features of the substrate and the monolayer, respectively, and its preferred embodiments as defined in relation to the aspect of the invention further above in which a spin filter device is provided, as considered appropriate for manufacturing the spin filter device. 
         [0027]    Step (a) of the method can optionally include cleaning the substrate prior to step (b), for example by sputtering with rare or reactive gases or by wet chemical agents. 
         [0028]    Optionally, the at least one monolayer can be deposited upon the substrate by self-assembling of the molecules. The self-assembling of the molecules can optionally be processed in a wet chemical procedure. 
         [0029]    Optionally, step (b) of the method can include integrating nano-particles, particularly nano-dots, into the at least one monolayer. If there is more than one monolayer, the nano-particles can optionally be integrated between the monolayers. 
         [0030]    According to an aspect of the invention, there is provided a method for using a spin filter device for generating a current having a first substrate and at least one mono-layer deposited on the first substrate, the method including the steps of
       (a) producing a current of electrons from the first substrate to travel into the at least one monolayer; and   (b) injecting electrons which have passed the at least one monolayer into a second substrate;
 
wherein the at least one monolayer comprises asymmetrical molecules adapted to filter the current of electrons such that electrons that exhibit a predetermined spin can pass to generate a current of spin-polarised electrons.
       
 
         [0033]    Optionally, the first substrate is one of a metal or a semiconductor. The second substrate can optionally be one of a metal, a semiconductor, an isolator or a vacuum. 
         [0034]    The at least one monolayer can include all or selected features of the monolayer and its preferred embodiments as defined in relation to the aspect of the invention in which a spin filter device is provided, as considered appropriate for using the spin filter device. 
         [0035]    Optionally, step (a) of the method can include irradiating said substrate with photons from a photon source thereby producing a current of photoelectrons which travel into said at least one monolayer. 
         [0036]    Optionally, step (a) of the method can include irradiating said substrate with a UV laser pulse. Optionally, a photon energy of the photoelectrons emitted by the UV laser can be 5.84 eV, wherein the pulse duration can be about 200 ps (picoseconds) at 20 kHz repetition rate, and a fluence of 150 pJ/cm 2 . However, any other photon energy, pulse duration, repetition rate or fluence can be applied as appropriate. The laser pulse can optionally be generated from a Nd:YVO 4  oscillator. 
         [0037]    Optionally, step (a) can be realised by electric or magnetic field induced injection from a spin polarised substrate. 
         [0038]    Step (a) can optionally include irradiating said substrate with linearly or circularly polarised or unpolarised photons. 
         [0039]    According to a further aspect of the present invention, there is provided a spintronic transistor structure including a semiconductor structure carrying a spin filter device including all or selected features of the spin filter device and its preferred embodiments as defined in relation to the aspect of the invention in which a spin filter device is provided, wherein the spin filter device is adapted to operate as a spin injector the semiconductor structure. 
         [0040]    Optionally, the semiconductor structure can comprise silicon or GaAs. 
         [0041]    According to a further aspect of the present invention, there is provided a detector for spin-polarised electrons, the detector including at least one monolayer;
       wherein the monolayer is deposited upon the detector such that electrons to be detected have to pass the monolayer; and   wherein the monolayer comprises asymmetrical molecules and is adapted to filter electrons such that electrons that exhibit a predetermined spin can pass.       
 
         [0044]    Optionally, the molecules of the at least one monolayer are chiral molecules. 
         [0045]    The said at least one monolayer can optionally comprise organic molecules. Optionally, the at least one monolayer is self-assembled on the detector, for example in a wet chemical procedure. 
         [0046]    The at least one monolayer can optionally comprise nano-particles, particularly nano-dots. 
         [0047]    An advantage of embodiments of the present invention is that magnetic or magnetized substrates are no longer needed to generate spin-polarised electrons. Also, circularly polarised light is no longer needed to generate spin-polarised electrons. The materials can be easily prepared, for example by wet chemical procedures, and have turned out to be stable in air. So, they can be used in room temperature and do not need expensive cooling. A further advantage of the present invention is that it provides an effective way to inject spin into standard transistors, such as silicon based transistor. The invention further enables spin sensitive gating. Furthermore the invention enables the reduction of the amount of space and heat capacitance of logic devices. 
         [0048]    Another advantage of embodiments of the present invention arises from the fact that molecular scale electronics are used. This opens a way for incorporating the quantum mechanical spin concepts with a standard device such as those based on, for example silicon (Si) or gallium arsenide (GaAs). In molecular electronic devices, when trying to contact molecules to the macroscopic world, problems can be circumvented with the present invention. Embodiments of the present invention provide a viable alternative to the conventional schemes proposed for molecular electronics. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0049]    Embodiments of the present invention will be described with reference to and as shown in the following Figures, in which 
           [0050]      FIG. 1  is a perspective view of a spin filter device according to one embodiment of the present invention; 
           [0051]      FIG. 2   a  shows a distribution of a spin polarisation percentage of electrons ejected from a clean substrate with linearly or circularly polarised light according to the prior art; 
           [0052]      FIG. 2   b  shows a distribution of a spin polarisation percentage of electrons ejected from another bare substrate with linearly or circularly polarised light according to the prior art; 
           [0053]      FIGS. 3   a ,  3   b ,  3   c  show a distribution of the spin polarisation percentage of electrons transmitted through a spin filter device according to an embodiment of the present invention, for light polarised clockwise (cw) circularly, linearly, and counter-clockwise (ccw) circularly, respectively; 
           [0054]      FIG. 4  shows the electron spin polarisation for spin filter devices according to the present invention and reference materials as a function of the length of chiral molecules; 
           [0055]      FIG. 5  shows a total photoelectron signal measured for electrons ejected from a spin filter device according to the present invention applying clockwise (cw) and counter-clockwise (ccw) polarised light; 
           [0056]      FIGS. 6   a ,  6   b ,  6   c  show a distribution of the spin polarisation percentage of electrons transmitted through a spin filter device comprising a monolayer with molecules of a first length according to an embodiment of the present invention, for light polarised clockwise (cw) circularly, linearly, and counter-clockwise (ccw) circularly, respectively; 
           [0057]      FIGS. 7   a ,  7   b ,  7   c  show a distribution as in  FIGS. 6   a - 6   c  but for a spin filter device comprising a monolayer with molecules of a second length according to an embodiment of the present invention; 
           [0058]      FIGS. 8   a,    8   b ,  8   c  show another distribution as in  FIGS. 6   a - 6   c  but for a spin filter device comprising a monolayer with molecules of a third length according to an embodiment of the present invention; 
           [0059]      FIG. 9  shows the spin dependent current through a monolayer of the spin filter device according to an embodiment of the present invention; 
           [0060]      FIG. 10  shows a spintronic transistor structure according to an embodiment of the present invention; and 
           [0061]      FIG. 11  shows a spin filter device according to a further embodiment of the present invention. 
       
    
    
     DETAILED DESCRIPTION 
       [0062]      FIG. 1  shows a perspective view of a spin filter device  10  according to one embodiment of the invention. In this example, the spin filter device  10  includes a mono-layer  12  of double stranded DNA (dsDNA). Thiolated dsDNA is bound to a substrate  14 , which is a gold surface in this example, and forms a self-assembled mono-layer  12  of chiral molecules. The substrate can also be formed by any other material, e.g. a different metal or a semiconductor. Unpolarised electrons  16  ejected from the gold surface produced by linearly polarised light  18  incident from the monolayer side are transmitted and can be analyzed. Most of the electrons  20  transmitted through the monolayer  12  are spin polarised. Spin orientation depends on the enantiomer used in the monolayer. 
         [0063]    It is well known that spin-polarised photoelectrons are readily generated from magnetic substrates or when circularly polarised light ejects electrons from substrates with large spin-orbit coupling. Since an organic chiral layer on a non-magnetic metal surface is not likely to be self-magnetized, one expects that photoelectrons ejected from such a layer with unpolarised light will not be spin polarised. The present invention however shows exceptionally high polarisation of electrons which are ejected from surfaces coated with self-assembled monolayer of double stranded DNA, independent of the polarisation of the incident light. It has previously been shown that the photoelectron yield from self-assembled monolayers of chiral molecules on gold depends on the circular polarisation of the exciting light as well as the voltage across the layer and its handedness. The spin polarisation of the electrons was not measured, and indications for spin-dependent transmission were only inferred from the dependence of the total electron yield on the circular polarisation of the incident photons. These studies could not determine whether or not the ejected electrons are spin polarised when the incident photons are unpolarised or linearly polarised. Furthermore, the observed effect may result from circular dichroism, namely that the absorption of the system depends on the light&#39;s circular polarisation. 
         [0064]    In the present invention, self-assembled dsDNA monolayers can be prepared according to standard procedures by depositing dsDNA which is thiolated on one, e.g. the 3′, end of one of the DNA strands on a clean gold substrate. Either polycrystal-line Au or single crystal Au(111) may be used as substrates. The monolayers are characterized by various methods that ensure the uniformity and reproducibility of the DNA layer. The experiments have been carried out under ultra-high vacuum conditions that employed photoelectron detection with two detectors, an electron time-of-flight instrument, recording the kinetic energy distribution of the electrons, and a Mott-type electron polarimeter for spin analysis. The photoelectrons were ejected by a UV laser pulse with a photon energy of 5.84 eV, pulse duration of about 200 ps at 20 kHz repetition rate, and a fluence of 150 pJ/cm 2 . The laser light is normally incident onto the sample, and it is either linearly or circularly polarised. For the vast majority of DNA samples no damage is observed over the course of the spin polarisation measurement within about four hours. For direct polarisation measurements, the photoelectrons are guided by an electrostatic 90°-bender and subsequent transport optics. Hence, an initial longitudinal spin polarisation is converted into a transversal one for analysis. In the electron polarimeter, an electron spin polarisation causes an up-down scattering asymmetry A=(I U −I L )/(I U +I L ). Here I U,L  denote the count rates of an upper and a lower counter. The transversal polarisation is given by P=A/S eff . The analysing power, also known as the Sherman function, has been calibrated to be S eff =−(0.229±0.011). In the above set-up, the spin polarisation parallel to the sample normal and thus parallel to the initial electron velocity is measured. 
         [0065]      FIG. 2   a  and  FIG. 2   b  illustrate examples of measurements of spin-polarisation with prior art devices. In  FIG. 2   a , the spin polarisation of photoelectrons from a clean Au(111) single crystal is shown for different laser polarisations. The spin polarisation and the sign of its orientation depend on the laser polarisation. The comparison of the counting rates in the upper and lower counter of the Mott polarimeter yields an intensity asymmetry of A=±(5.03±1.1) % for clockwise (cw, curve  22 ) and counter clockwise (ccw, curve  24 ) circularly polarised light. Combined with the Sherman function S eff  average electron spin polarisations of P=±(22±5) % are determined for emission from the single crystal substrate, shown by the histograms  26 ,  28 . For negative electron spin polarisation, the direction of the spin vector is antiparallel to the propagation direction of the electron, and correspondingly parallel to {right arrow over (k)} for positive spin polarisation. As expected for an unmagnetized substrate, no asymmetry and therefore also no spin polarisation is observed for electrons ejected from the gold surface when the laser is polarised linearly (curve  30 , histogram  32 ). For reference, the spin polarisation is shown for electrons emitted from the molybdenum sample holder in  FIG. 2   b . In this case, the spin polarisation is zero for circular as well as linear laser polarisation (curve  34 ). This signal has been used as a reference for the further experiments. 
         [0066]      FIGS. 3   a ,  3   b  and  3   c  illustrate examples of measurements of spin-polarisation of spin filter device as shown in  FIG. 1  according to an embodiment of the present invention. More specifically,  FIGS. 3   a ,  3   b  and  3   c  show the spin polarisation observed when electrons from the same Au(111) single crystal are transmitted through a self-assembled monolayer of 50 base pairs (bp) dsDNA. Excitation with linearly polarised light ( FIG. 3   b ) produces now strongly spin polarised electrons with an average P=−(31±4) % (curve  36 ). Also, excitation by clockwise (cw) ( FIG. 3   a ) and counter-clockwise (ccw) ( FIG. 3   c ) circularly polarised light yields spin polarised electrons with average polarisations of P=−(35±3) % and −(29±3) % (curves  38 ,  40 ), respectively. All electron spin polarisations show the same negative sign, independent of the light polarisation. A similar high spin polarisation is observed for linearly polarised light too ( FIG. 3   b , curve  36 ). These results stand in contrast to the case of the clean Au (111) substrate as shown in  FIG. 2   a , for which linearly polarised light induces no electron spin polarisation (curve  30 ), and for which the helicity of the circularly polarised light determines the direction of the electron spin polarisation. These results indicate that the ordered monolayer  12  ( FIG. 1 ) of dsDNA acts as a spin filter for electrons  16 ,  20  ( FIG. 1 ) excited in the gold as substrate  14  ( FIG. 1 ) and transmitted through the dsDNA monolayer  12 . 
         [0067]      FIG. 4  shows measurements of the electron spin polarisation for various monolayers  12  ( FIG. 1 ) of DNA on polycrystalline gold (Au) surfaces. More specifically, room temperature electron spin polarisations are presented for four different monolayers of dsDNA in which each of the molecules have different lengths of 26, 40, 50, and 78 base pairs (line with filled dots shown at  42   a,b,c ,  44   a,b,c ,  46   a,b,c ,  48   a,b,c ). The results of 36 different experiments on ten different samples are shown. Further, monolayers of single stranded DNA (lines with open diamond shown at  50   a,b,c ), and a sample of dsDNA damaged by UV light (lines with open triangle shown at  52   a,b,c ) are investigated. Also the electron spin polarisation from an un-cleaned bare polycrystalline gold substrate (open circle  54   a,b,c ) is shown at zero base pairs. Measurements are conducted with light of different polarisations, cw ( 42   a ,  44   a ,  46   a ,  48   a ,  50   a ,  52   a ,  54   a ) and ccw ( 42   b ,  44   b ,  46   b ,  48   b ,  50   b ,  52   b ,  54   b ) circular, and linear ( 42   c ,  44   c ,  46   c ,  48   c ,  50   c ,  52   c ,  54   c ). For clarity, the symbols for the different light polarisations are off-set by a plus and minus one base pair. The data indicates that with increasing length of the dsDNA molecules the absolute value of electron spin polarisation increases. The highest electron spin polarisation is observed for 78 bp dsDNA with about P=−60% (shown at  48   a,b,c ). While for dsDNA on average the electron spin polarisation increases with the length of the DNA, no polarisation is obtained for single stranded DNA (shown at  50   a,b,c ). In an absolute value, the polarisation increases slightly in the case of dsDNA, when the electrons are injected with ccw circular polarised light ( 42   b ,  44   b ,  46   b ,  48   b ), because there are more electrons injected into the monolayer  12  with a spin polarisation that coincides with a high transmission of the monolayer  12 . Given error bars are standard deviation of the mean of several runs, namely single measurements each having a statistical error of about less than 3%. Measurements performed on different samples coated with the same number of base pairs are averaged and the total error is calculated by error propagation. 
         [0068]    The measurements presented in the Figures as described above indicate that well-organized self-assembled monolayers  12  of dsDNA on Au as substrate  14  act as very efficient spin filters. Within the range of dsDNA length studied, the selectivity increases with its length and therefore the number of turns of the helix. It is important to appreciate that even the longest molecules used are still shorter than the persistence length of the DNA, which is the length up to which the DNA behaves as a rigid rod. Hence, the dsDNA oligomers studied here are rigid and each monolayer  12  can be visualized as consisting of rigid chiral rods closely packed together, as depicted in  FIG. 1 . In the case of a monolayer made from single strand DNA, the molecules are more floppy and do not form rigid close-packed monolayers and indeed no spin selectivity is observed. Because the photon energy is lower than the ionization energy of the DNA and the laser intensity is low, the photoelectrons all originate from the gold substrate. In addition, less than 0.1% of the incident light is absorbed in the layer, even under resonance conditions. The low intensities and weak absorbances ensure further that non-linear excitation processes do not occur in the DNA layer. 
         [0069]    Electrons are known to transmit through free standing or supported thin ferromagnetic films that acted as a spin filter in certain situations. In these cases, and for low-energy electrons, the selectivity was reported to be about 25%. The spin polarisation can be explained by inelastic electron scattering involving unoccupied d-states above the Fermi level. The scattering rate for minority spin electrons is then enhanced with respect to that of majority spin electrons because of an excess of minority spin holes. The polarisation decreased sharply as a function of collision energies, due to the spin dilution by secondary electrons. However, in the present invention the polarisation is energy independent within the energy range studied. Although polarised light is not needed, the polarisation achieved with embodiments of the present invention is almost as high as that obtained by photoemission with circular polarised light from GaAs substrates. 
         [0070]    The mechanism of how charge transport or charge redistribution through chiral systems generates a magnetic field is elementary; however, this magnetism is transient, ending when the charge flow stops. A possible way to transform transient charge flow into permanent magnetism is by spin-orbit coupling that converts the orbital angular momenta of the electrons in the helical potential into spin alignment. Spin-orbit coupling in hydrocarbons is commonly believed to be very weak and therefore no significant spin alignment is expected. Indeed, the interaction of spin polarised electrons with chiral molecules has earlier been studied. When these electrons were scattered from gas phase and thus randomly oriented chiral molecules, only a very small preference of the order or 10 −4  of one spin orientation over the other was found, and only when a heavy metal atom with significant spin-orbit interaction was present in the molecules. In contrast to these gas phase studies, electrons transmitted through organized monolayers of dipolar-chiral molecules of the present invention display a large dependence on the handedness of the molecules. 
         [0071]      FIG. 5  shows the kinetic energy distribution of the electrons  16 ,  20  ( FIG. 1 ) transmitted through the self-assembled monolayer  12  ( FIG. 1 ) of dsDNA (50 bp) adsorbed on a polycrystalline Au substrate  14  ( FIG. 1 ) for clockwise (cw, curve  56 ) and counter clockwise (ccw, curve  58 ) circularly polarised light. Photoelectrons with kinetic energies up to about 1.2 eV are measured. The intensity of the signal (curve  58 ) observed with ccw circularly polarised radiation is larger by about 7% relative to that obtained with the cw circularly polarised light (curve  56 ). This ratio is independent of the primary kinetic energy of the photo-emitted electrons. This result clearly shows a circular dichroism which is consistent with the results obtained in  FIG. 2   a . In this measurement the electron signal is not spin resolved. It further shows that the work function is independent of the handedness of the light, as expected. 
         [0072]    In  FIGS. 6   a ,  6   b ,  6   c ,  7   a ,  7   b ,  7   c ,  8   a ,  8   b  and  8   c , typical results for one preparation are shown for 40 bp, 50 bp, and  78  by monolayers  12  ( FIG. 1 ) of dsDNA on poly-Au substrates  14  ( FIG. 1 ). 
         [0073]      FIGS. 6   a ,  6   b  and  6   c  show measurements of the spin polarisation of 40 bp dsDNA/poly-Au. The spin polarisation is −(38.0±6.5) % for linear polarised light ( FIG. 6   a ), −(35.1±8.3) % for cw polarised light ( FIGS. 6   b ), and −(40.1±5.5) % for ccw polarised light ( FIG. 6   c ). 
         [0074]      FIGS. 7   a ,  7   b  and  7   c  show measurements of the spin polarisation of 50 bp dsDNA/poly-Au. The spin polarisation is −(35.5±5.5) % for linear polarised light ( FIG. 7   a ), −(31.5±5.7) % for cw polarised light ( FIGS. 7   b ), and −(38.8±5.9) % for ccw polarised light ( FIG. 7   c ). 
         [0075]      FIGS. 8   a ,  8   b  and  8   c  show measurements of the spin polarisation of 78 bp dsDNA/poly-Au. The spin polarisation is −(57.2±5.9) % for linear polarised light ( FIG. 8   a ), −(54.5±7.0) % for cw polarised light ( FIG. 8   b ), and −(60.8±5.8) % for ccw polarised light ( FIG. 8   c ). 
         [0076]      FIG. 9  shows the spin dependent current through double stranded DNA which is 40 base pairs long. The current of electrons with spin up is shown in curve  60 , whereas the current of electrons with spin down is shown in curve  62 . At ±1 Volt the ratio between the two spin currents  60 ,  62  is 1:5. These measurements show that trans-port through these molecules favours one spin orientation. 
         [0077]      FIG. 10  shows a spintronic transistor structure  70  according to an embodiment of the invention. It comprises three monolayers  12  of organic molecules and nano-dots  72  incorporated between the monolayers  12 . The monolayers  12  are self-assembled to the substrate  14  which is made of gold (Au). The spintronic transistor structure  70  is based on a semiconductor structure  74  comprising GaAs. The transistor  70  can create discrete gating for non binary logic operation. By creating several plateaus-like features in the IV characteristics of the transistors  70  a reduction of the power of standard transistors working in non binary base may be obtained. 
         [0078]    In  FIG. 11 , a spin filter device  80  is shown as an example for a further embodiment according to the present invention. A first substrate  82 , e.g. a metal or a semiconductor, acts as source material. A monolayer  86  of asymmetrical molecules, preferably organized chiral molecules is deposited upon the first substrate  82 . The first substrate  82  and the monolayer  86  form the spin filter device. A second substrate  84 , which can be for example a metal, a semiconductor, an isolator or a vacuum, acts as target material. The monolayer  86  is located between the first and the second substrate  82 ,  84 . Preferably, the monolayer  86  is deposited upon or bounded to the first substrate  82  by self-assembling. Electrons (not shown) travel from the first substrate  84  into the monolayer  86 . The majority of those electrons which have passed the monolayer  86  have the same spin. These spin filtered or spin-polarised electrons are injected into the second substrate  84 . 
         [0079]    The sample organisation for the high spin selectivity is important. Measurements further provide quantitative information regarding the spin polarisation and its dependence on the monolayer thickness or the length of the helical potential. If the effect described in relation to the Figures is caused by a pseudo-magnetic field within the monolayer it means that a field exceeding a few hundred Tesla has to be present. 
         [0080]    The present invention provides for practical and theoretical considerations allowing for configuring a novel spin filter device that can be used in spintronic devices. This structure is characterized by spin selectivity for electron transmission therethrough. The spin filter device of the present invention can be used in a spintronic transistor structure. 
         [0081]    Those skilled in the art can appreciate that while the present invention has been described in terms of preferred embodiments, the concept upon which the invention is based may readily be utilized as a basis for designing other structures, systems and processes for carrying out the several purposes of the present invention. 
         [0082]    In terms of the monolayer  12 , it is appreciated that other kinds of asymmetrical and/or chiral molecules than double stranded DNA can be used to achieve the present advantages. 
         [0083]    Although the examples of utilization of the spin filter device  10  of the present invention were shown for a spin filter device  80  and as a part of a spintronics circuit, e.g. in large scale integrated circuits or printed circuits, the structure can also be used as components in other detectors or sensors. 
         [0084]    It is important, therefore, that the scope of the invention is not construed as being limited by the illustrative embodiments described herein. Other variations are possible within the scope of the present invention as defined herein.