Posted: Jan 11, 2017  
A new method for quick and precise measurement of quantum states 

Reconstructing quantum states without postprocessing 

Quantum state tomography is the process of reconstructing – or more precisely completely characterizing – the quantum state of an object as it is emitted by its source, before a possible measurement or interaction with the environment takes place. This technique has become an essential tool in the emerging field of quantum technologies.  
The theoretical framework of quantum state tomography dates back to the 1970s. Its experimental implementations are nowadays routinely carried out in a wide variety of quantum systems. The basic principle of quantum state tomography – as of is medical counterpart – is to repeatedly perform measurements from different spatial directions on the quantum systems in order to uniquely identify the system’s quantum state.  
Nevertheless, for quantum state tomography a lot of computational postprocessing of the measured data is required to deduce the initial quantum state from the observed measurement results – all together a high expenditure.  
Consequently, in 2011 a novel, more direct tomographical method was established that makes it possible to determine the quantum state without the need for postprocessing. However, that novel method had a major drawback: it uses minimally disturbing measurements, so called weak measurements, to determine the system’s quantum state.  
The basic idea behind weak measurements is to gain very little information about the observed system, by keeping the disturbance, caused by the measurement process, (negligible) small. Usually, a measurement has a huge impact on a quantum system, causing typical quantum phenomena, such as entanglement or interference, to vanish irretrievably. Since the amount of information gained in this procedure is very small, the measurements have to be repeated multiple times – a huge disadvantage of this measurement procedure in practical applications.  
A research team at the Institute of Atomic and Subatomic Physics of TU Wien headed by Stephan Sponar now managed to combine these two methods, benefitting from both.  
Schematic illustration of the interferometric setup. (click on image to enlarge)  
“We were able to further develop the established method so that the need of weak measurements becomes obsolete. Thus, we were able to integrate usual, socalled strong measurements, in the direct measurement procedure of the quantum state. Consequently, it is possible to determine the quantum state with higher precision and accuracy in a much shorter time compared to the approach with weak measurements – a tremendous progress.”, explains Tobias Denkmayr the first author of the paper.  
These results have now been published in the journal Physical Review Letters ("Experimental Demonstration of Direct Path State Characterization by Strongly Measuring Weak Values in a MatterWave Interferometer").  
Neutron interferometry – the method of choice 

An experimental test of the new scheme in a neutron interferometric experiment was carried out by Sponar and his team. It is based on the wave nature of neutrons, which are massive nuclear constituents forming almost two thirds of our universe.  
Nevertheless, if they are isolated from the atomic nucleus – for example in the fission process of a research reactor – they behave like waves. This phenomenon is usually referred to as waveparticle duality, which is explained in the framework of quantum mechanics.  
Inside the interferometer, an incident beam is split into two separate beams (by a thin, perfect silicon crystal plate). The beams travel along different regions in space and at some point are brought together again and allowed to interfere.  
The experiment was done at the neutron source at the Institut LaueLangevin (ILL) in Grenoble, where the group of the Institute of Atomic and Subatomic Physics is in charge of a permanent beam port.  
It is important to note, that the results are not limited to the quantum system formed by single neutrons but are in fact completely general. Therefore, they can be applied to many other quantum systems such as photons, trapped ions or superconducting qubits.  
The results may have a big impact on how quantum state estimation is performed in the future and will foreseeably be exploited in the rapidly evolving technologies applied in quantum information science. 
Source: Vienna University of Technology  
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