Quantum team reads information from robust Majorana qubits using quantum capacitance

by Robert Schreiber
Berlin, Germany (SPX) Feb 16, 2026
Researchers have demonstrated a method to read information stored in Majorana-based qubits using a technique known as quantum capacitance, marking what they describe as a crucial advance for topological quantum computing. The work involves an international collaboration in which the Spanish National Research Council (CSIC), through the Madrid Institute of Materials Science (ICMM-CSIC), provided the theoretical foundation for a sophisticated experiment carried out primarily at Delft University of Technology.

Topological qubits based on Majorana zero modes are designed to protect quantum information by storing it non locally rather than at a single point in a device. In this scheme, information is encoded across a pair of special quantum states called Majorana zero modes, which act like a safe box for quantum data because local disturbances are unlikely to corrupt the global state. This non local encoding is expected to make Majorana qubits intrinsically robust against local noise and decoherence, since an error would have to affect the entire system to destroy the stored information.

However, the same property that provides protection has also posed a major challenge for experiments, because it is not obvious how to read out a property that does not reside at any specific location. Traditional local charge measurements tend to be blind to the non local information associated with the parity of the Majorana pair, limiting earlier attempts to verify and use these qubits. The new study addresses this problem by introducing a global probe that can sense the overall quantum state of the system rather than just local observables.

The experimental team constructed a modular nanostructure referred to as a minimal Kitaev chain, assembled in a bottom up fashion from controllable building blocks. In practice, they created a chain consisting of two semiconductor quantum dots coupled via a superconducting segment, allowing them to engineer conditions under which Majorana modes emerge in a controlled way. This modular approach contrasts with previous experiments that relied on less controlled combinations of materials and interfaces.

Once the minimal Kitaev chain was established, the researchers used quantum capacitance as a global probe to access the qubit information encoded in the non local Majorana modes. With this technique, they were able, for the first time, to distinguish in real time and in a single measurement whether the non local quantum state formed by the two Majorana modes had even or odd parity. In qubit language, this corresponds to determining whether the fermionic mode formed by the two Majoranas is effectively full or empty, which defines the logical states of the qubit.

The measurements showed that while local charge probes did not reveal the parity information, the quantum capacitance probe responded clearly to changes in the global state. This finding provides an elegant confirmation of the topological protection principle: local observables remain largely insensitive to the encoded information, while a carefully designed global observable can access it without strongly disturbing the qubit. The result offers a practical readout pathway that is compatible with the underlying robustness of Majorana-based qubits.

In addition to demonstrating parity readout, the experiment revealed what the researchers describe as random parity jumps in the system. By monitoring these stochastic events, they were able to extract a parity coherence time exceeding one millisecond, which is a highly promising value for future topological qubit operations based on Majorana modes. Such coherence times suggest that, with further engineering, Majorana qubits could support gate operations and error correction protocols that exploit their intrinsic noise protection.

The study highlights the synergy between advanced experimental techniques and detailed theoretical modeling. The Delft group developed and implemented the modular device architecture and quantum capacitance measurement scheme, while the ICMM-CSIC team provided the theoretical framework needed to interpret the complex signals and confirm that they arise from Majorana physics in a minimal Kitaev chain. According to the authors, this combination of controlled device design, global probing, and robust theory represents a significant step toward functional topological qubits that can be initialized, manipulated, and read out in scalable quantum processors.

Research Report: Single-shot parity readout of a minimal Kitaev chain