Magneto-optical light modulator

The invention claimed is: 1. A magneto-optical light modulator for modulating light based on a physical property provided as an input to the modulator, the modulator comprising a substrate with a region of material comprising a film of Eu (1-x) Sr (x) MO 3 , 0≤x<1, an optical waveguide adapted for directing light through the region of material and a first control unit, the M of the film of Eu (1-x) Sr (x) MO 3 being a metal selected from Ti, Hf, Zr and Th, the first control unit being adapted to maintain the region of material at a constant predefined temperature in case the physical property is an input magnetic field subject to the region of material or maintain the region of material subjected to a constant predefined magnetic field in case the physical property is an input temperature of the region of material, the light modulator being adapted to perform the modulation of the light using the birefringence of the region of material, the birefringence depending on the physical property. 2. The modulator of claim 1 , further comprising a light source for generating the light to be directed through the region of material and a light detector adapted for determining the modulation of the light by determining the optical transparency of the region of material from the light directed through the region of material. 3. The modulator of claim 2 , further comprising an evaluation unit adapted to determine from the determined transparency and the constant predefined temperature the field strength of the input magnetic field or to determine from the determined transparency and the constant predefined magnetic field the input temperature. 4. The modulator of claim 1 , the substrate being a SrTiO 3 substrate. 5. The modulator of claim 1 , further comprising a magnet for generating the input magnetic field and a second control unit coupled to a control input, the second control unit being adapted for controlling the generating of the input magnetic field with a desired field strength and/or field direction based on an input signal receivable via the control input. 6. The modulator of claim 1 , the modulator comprising one or more of the substrates carrying a plurality of the regions of the material, the regions being spatially separated from each other, the optical waveguide being adapted for directing the light through the separated regions of the material, a magnet for generating the input magnetic field with a constant predefined field strength and/or field direction relative to the modulator. 7. The modulator of claim 6 , further comprising a light source for generating the light to be directed through the regions of material, a light detector adapted for determining the modulation of the light by determining the optical transparency of each region of material from the light directed through said region of material, an evaluation unit adapted to determine from the determined transparencies one or more binary data values encoded using two different crystallographic orientations of the Eu (1-x) Sr (x) MO 3 in the regions, the two crystallographic orientations being relative to the modulator. 8. The modulator of claim 1 , the Eu(1-x)Sr(x)MO3 being single crystalline, the input magnetic field and the constant magnetic field being oriented along the direction of the Eu(1-x)Sr(x)MO3 and/or the constant magnetic field being larger than 0.1 T and/or the constant temperature being in between 100K and 280K, light generated by the light source having an optical wavelength in between 400 nm and 700 nm. 9. A magnetic field sensor, the sensor comprising the modulator of claim 3 . 10. A temperature sensor, the sensor comprising the modulator of claim 3 . 11. A signal processor, the processor comprising the modulator of claim 5 . 12. A memory device, the memory device comprising the modulator of claim 6 . 13. A memory device for storing one or more binary data values, the memory device comprising one or more substrates with a plurality of regions of material, each region of material comprising a film of Eu (1-x) Sr (x) MO 3 , 0≤x<1, the M of the film of Eu (1-x) Sr (x) MO 3 being a metal selected from Ti, Hf, Zr and Th, the regions being spatially separated from each other, the Eu (1-x) Sr (x) MO 3 being single crystalline, the one or more binary data values being encoded in the regions using two different crystallographic orientations of the Eu (1-x) Sr (x) MO 3 in the regions, the two crystallographic orientations being relative to the device. 14. A reader for reading the memory device of claim 13 , the reader comprising a magnet generating a magnetic field at a readout zone of the reader, the magnetic field having a constant magnetic field strength and a constant field direction with respect to the device, the reader further comprising a processor and a memory, the memory comprising instructions, wherein execution of the instructions by the processor causes the reader to: determine in the readout zone the optical transparencies of the regions along a predefined constant direction relative to the device, determine from the determined transparencies the binary data values encoded in the regions. 15. A method for reading a memory device storing one or more binary data values, the memory device comprising a one or more substrates with a plurality of regions of material, each region of material comprising a film of Eu (1-x) Sr (x) MO 3 , 0≤x<1, the M of the film of Eu (1-x) Sr (x) MO 3 being a metal selected from Ti, Hf, Zr and Th, the regions being spatially separated from each other, the Eu (1-x) Sr (x) MO 3 being single crystalline, the one or more binary data values being encoded in the regions using two different crystallographic orientations of the Eu (1-x) Sr (x) MO 3 in the regions, the two crystallographic orientations being relative to the device, a reader comprising a magnet generating a magnetic field at a readout zone of the reader, the magnetic field having a constant magnetic field strength and a constant field direction with respect to the device, the method comprising: determining, by the reader, in the readout zone the optical transparencies of the regions along a predefined constant direction relative to the device, determining, by the reader, from the determined transparencies the one or more binary data values encoded in the regions. 16. A computer program product comprising computer executable instructions to perform the method as claimed in claim 15 . 17. The modulator of claim 1 , wherein the optical waveguide is adapted for directing light through the region of material and an underlying substrate.