A simple and efficient joint measurement strategy for estimating fermionic observables and Hamiltonians
Abstract We propose a simple scheme to estimate fermionic observables and Hamiltonians relevant in quantum chemistry and correlated fermionic systems. Our approach is based on implementing a measurement that jointly measures noisy versions of any product of two or four Majorana operators in an N mod...
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| Main Authors: | , , |
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| Format: | Article |
| Language: | English |
| Published: |
Nature Portfolio
2025-04-01
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| Series: | npj Quantum Information |
| Online Access: | https://doi.org/10.1038/s41534-025-00957-7 |
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| Summary: | Abstract We propose a simple scheme to estimate fermionic observables and Hamiltonians relevant in quantum chemistry and correlated fermionic systems. Our approach is based on implementing a measurement that jointly measures noisy versions of any product of two or four Majorana operators in an N mode fermionic system. To realize our measurement we use: (i) a randomization over a set of unitaries that realize products of Majorana fermion operators; (ii) a unitary, sampled at random from a constant-size set of suitably chosen fermionic Gaussian unitaries; (iii) a measurement of fermionic occupation numbers; (iv) suitable post-processing. Our scheme can estimate expectation values of all quadratic and quartic Majorana monomials to ϵ precision using $${\mathcal{O}}(N\log (N)/{\epsilon }^{2})$$ O ( N log ( N ) / ϵ 2 ) and $${\mathcal{O}}({N}^{2}\log (N)/{\epsilon }^{2})$$ O ( N 2 log ( N ) / ϵ 2 ) measurement rounds respectively, matching the performance offered by fermionic classical shadows1,2. In certain settings, such as a rectangular lattice of qubits which encode an N mode fermionic system via the Jordan-Wigner transformation, our scheme can be implemented in circuit depth $${\mathcal{O}}({N}^{1/2})$$ O ( N 1 / 2 ) with $${\mathcal{O}}({N}^{3/2})$$ O ( N 3 / 2 ) two-qubit gates, offering an improvement over fermionic and matchgate classical shadows that require depth $${\mathcal{O}}(N)$$ O ( N ) and $${\mathcal{O}}({N}^{2})$$ O ( N 2 ) two-qubit gates. By benchmarking our method on exemplary molecular Hamiltonians and observing performances comparable to fermionic classical shadows, we demonstrate a novel, competitive alternative to existing strategies. |
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| ISSN: | 2056-6387 |