Cryogenic trapped-ion system for large scale quantum simulation

ABSTRACTIn bottom-up proteomics, peptides are separated by liquid chromatography with elution peak widths in the range of seconds, while mass spectra are acquired in about 100 microseconds with time-of-fight (TOF) instruments. This allows adding ion mobility as a third dimension of separation. Among several formats, trapped ion mobility spectrometry (TIMS) is attractive due to its small size, low voltage requirements and high efficiency of ion utilization. We have recently demonstrated a scan mode termed parallel accumulation – serial fragmentation (PASEF), which multiplies the sequencing speed without any loss in sensitivity (Meier et al., PMID: 26538118). Here we introduce the timsTOF Pro instrument, which optimally implements online PASEF. It features an orthogonal ion path into the ion mobility device, limiting the amount of debris entering the instrument and making it very robust in daily operation. We investigate different precursor selection schemes for shotgun proteomics to optimally allocate in excess of 100 fragmentation events per second. More than 800,000 fragmentation spectra in standard 120 min LC runs are easily achievable, which can be used for near exhaustive precursor selection in complex mixtures or re-sequencing weak precursors. MaxQuant identified more than 6,400 proteins in single run HeLa analyses without matching to a library, and with high quantitative reproducibility (R > 0.97). Online PASEF achieves a remarkable sensitivity with more than 2,900 proteins identified in 30 min runs of only 10 ng HeLa digest. We also show that highly reproducible collisional cross sections can be acquired on a large scale (R > 0.99). PASEF on the timsTOF Pro is a valuable addition to the technological toolbox in proteomics, with a number of unique operating modes that are only beginning to be explored.

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Quantum gate teleportation between separated qubits in a trapped-ion processor

Science ◽

10.1126/science.aaw9415 ◽

2019 ◽

Vol 364 (6443) ◽

pp. 875-878 ◽

Cited By ~ 13

Author(s):

Yong Wan ◽

Daniel Kienzler ◽

Stephen D. Erickson ◽

Karl H. Mayer ◽

Ting Rei Tan ◽

...

Keyword(s):

Confidence Level ◽

Large Scale ◽

Ion Trap ◽

Quantum Gate ◽

Quantum Computers ◽

Mixed Species ◽

Cnot Gate ◽

Classical Communication ◽

Trapped Ion ◽

Single Qubit

Large-scale quantum computers will require quantum gate operations between widely separated qubits. A method for implementing such operations, known as quantum gate teleportation (QGT), requires only local operations, classical communication, and shared entanglement. We demonstrate QGT in a scalable architecture by deterministically teleporting a controlled-NOT (CNOT) gate between two qubits in spatially separated locations in an ion trap. The entanglement fidelity of our teleported CNOT is in the interval (0.845, 0.872) at the 95% confidence level. The implementation combines ion shuttling with individually addressed single-qubit rotations and detections, same- and mixed-species two-qubit gates, and real-time conditional operations, thereby demonstrating essential tools for scaling trapped-ion quantum computers combined in a single device.

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AlphaTims: Indexing trapped ion mobility spectrometry - time of flight data for fast and easy accession and visualization

10.1101/2021.07.27.453933 ◽

2021 ◽

Author(s):

Sander Willems ◽

Eugenia Voytik ◽

Patricia Skowronek ◽

Maximilian T Strauss ◽

Matthias Mann

Keyword(s):

Mass Spectrometry ◽

Open Source ◽

Ion Mobility Spectrometry ◽

Ion Mobility ◽

Large Scale ◽

High Resolution Mass Spectrometry ◽

Time Of Flight ◽

Arrival Times ◽

Trapped Ion ◽

Trapped Ion Mobility Spectrometry

High resolution mass spectrometry-based proteomics generates large amounts of data, even in the standard liquid chromatography (LC) - tandem mass spectrometry configuration. Adding an ion mobility dimension vastly increases the acquired data volume, challenging both analytical processing pipelines and especially data exploration by scientists. This has necessitated data aggregation, effectively discarding much of the information present in these rich data sets. Taking trapped ion mobility spectrometry (TIMS) on a quadrupole time-of-flight platform (Q-TOF) as an example, we developed an efficient indexing scheme that represents all data points as detector arrival times on scales of minutes (LC), milliseconds (TIMS) and microseconds (TOF). In our open source AlphaTims package, data are indexed, accessed and visualized by a combination of tools of the scientific Python ecosystem. We interpret unprocessed data as a sparse 4D matrix and use just-in-time compilation to machine code with Numba, accelerating our computational procedures by several orders of magnitude while keeping to familiar indexing and slicing notations. For samples with more than six billion detector events, a modern laptop can load and index raw data in about a minute. Loading is even faster when AlphaTims has already saved indexed data in a HDF5 file, a portable scientific standard used in extremely large-scale data acquisition. Subsequently, data accession along any dimension and interactive visualization happen in milliseconds. We have found AlphaTims to be a key enabling tool to explore high dimensional LC-TIMS-QTOF data and have made it freely available as an open-source Python package with a stand-alone graphical user interface at https://github.com/MannLabs/alphatims or as part of the AlphaPept ecosystem.

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Experimental quantum simulation of fermion-antifermion scattering via boson exchange in a trapped ion

Nature Communications ◽

10.1038/s41467-017-02507-y ◽

2018 ◽

Vol 9 (1) ◽

Cited By ~ 11

Author(s):

Xiang Zhang ◽

Kuan Zhang ◽

Yangchao Shen ◽

Shuaining Zhang ◽

Jing-Ning Zhang ◽

...

Keyword(s):

Quantum Simulation ◽

Trapped Ion ◽

Boson Exchange

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Scalable trapped ion quantum computation with a probabilistic ion-photon mapping

Quantum Information and Computation ◽

10.26421/qic4.3-1 ◽

2004 ◽

Vol 4 (3) ◽

pp. 165-173

Author(s):

L.-M. Duan ◽

B.B. Blinov ◽

D.L. Moehring ◽

C. Monroe

Keyword(s):

Quantum Computation ◽

Coulomb Interaction ◽

Large Scale ◽

Trapped Ions ◽

Quantum Gates ◽

Photon Mapping ◽

Trapped Ion ◽

Experimental Noise

We propose a method for scaling trapped ions for large-scale quantum computation and communication based on a probabilistic ion-photon mapping. Deterministic quantum gates between remotely located trapped ions can be achieved through detection of spontaneously-emitted photons, accompanied by the local Coulomb interaction between neighboring ions. We discuss gate speeds and tolerance to experimental noise for different probabilistic entanglement schemes.

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Digital quantum simulation, Trotter errors, and quantum chaos of the kicked top

npj Quantum Information ◽

10.1038/s41534-019-0192-5 ◽

2019 ◽

Vol 5 (1) ◽

Cited By ~ 12

Author(s):

Lukas M. Sieberer ◽

Tobias Olsacher ◽

Andreas Elben ◽

Markus Heyl ◽

Philipp Hauke ◽

...

Keyword(s):

Time Evolution ◽

Quantum Chaos ◽

Threshold Value ◽

Quantum Simulation ◽

Spin Systems ◽

Step Size ◽

Sharp Threshold ◽

Trapped Ion ◽

Quantum Simulators ◽

Atomic Spins

Abstract This work aims at giving Trotter errors in digital quantum simulation (DQS) of collective spin systems an interpretation in terms of quantum chaos of the kicked top. In particular, for DQS of such systems, regular dynamics of the kicked top ensures convergence of the Trotterized time evolution, while chaos in the top, which sets in above a sharp threshold value of the Trotter step size, corresponds to the proliferation of Trotter errors. We show the possibility to analyze this phenomenology in a wide variety of experimental realizations of the kicked top, ranging from single atomic spins to trapped-ion quantum simulators which implement DQS of all-to-all interacting spin-1/2 systems. These platforms thus enable in-depth studies of Trotter errors and their relation to signatures of quantum chaos, including the growth of out-of-time-ordered correlators.

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