Your search keyword '"Glaser, S"' showing total 669 results

1. Polarization transfer from optically-pumped NV center ensembles to multinuclear spin baths

Author

Rizzato, R., Bruckmaier, F., Liu, K. S., Glaser, S. J., and Bucher, D. B.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Chemical Physics

Abstract

NV-diamonds have attracted keen interest for nanoscale sensing and spin manipulation. In particular, the non-equilibrium electron spin polarization after optical excitation of single NV centers has successfully been transferred to nuclear spin baths in the surrounding of the defects. However, these experiments need to be extended to NV-ensembles which have promising practical applications in the hyperpolarization of bulk sample volumes for NMR signal enhancement. Here, we use a dense, shallow ensemble of NV-centers to demonstrate polarization transfer to nuclear spins in a well-defined composite diamond sample system. This allows us to address three different types of nuclear spins in different positions with respect to the NV polarization source: from the close proximity of $^{13}$C inside the diamond lattice to the self-assembled molecular system consisting of $^{1}$H and $^{19}$F spins outside the diamond and over multiple interfaces. We show that ensemble NV experiments face problems different from single NV experiments. In particular, using spinlock pulses, the inhomogeneously broadened ESR line of the NV ensemble limits the minimal resonance linewidth with which the transfer protocol can occur. Furthermore, we compare the NV spin-polarization losses and polarization transfer rates to the different nuclear baths and discuss the role of spin-diffusion as detrimentally affecting the direct observation of nuclear polarization build-up within the detection volume of nanoscale NV-NMR experiments., Comment: 12 pages, 12 figures

Published

2021

2. Application of the Small Tip-Angle approximation in the Toggling Frame for the design of analytic robust pulses in Quantum Control

Author

Van Damme, L., Sugny, D., and Glaser, S. J.

Subjects

Quantum Physics

Abstract

We apply the Small Tip-Angle Approximation in the Toggling Frame in order to analytically design robust pulses against resonance offsets for state to state transfer in two-level quantum systems. We show that a broadband or a local robustness up to an arbitrary order can be achieved. We provide different control parameterizations to satisfy experimental constraints and limitations on the amplitude or energy of the pulse. A comparison with numerical optimal solutions is made., Comment: 32 pages, 7 figures

Published

2021

3. Robust control of an ensemble of springs: Application to Ion Cyclotron Resonance and two-level Quantum Systems

Author

Martikyan, V., Devra, A., Guéry-Odelin, D., Glaser, S., and Sugny, D.

Subjects

Quantum Physics

Abstract

We study the simultaneous control of an ensemble of springs with different frequencies by means of adiabatic, shortcut to adiabaticity and optimal processes. The linearity of the system allows us to derive analytical expressions for the control fields and the time evolution of the dynamics. We discuss the relative advantages of the different solutions. These results are applied in two different examples. For Ion Cyclotron Resonance, we show how to optimally control ions by means of electric field. Using a mapping between spins and springs, we derive analytical shortcut protocols to realize robust and selective excitations of two-level quantum systems., Comment: 25 pages, 7 figures

Published

2020

4. Purity Speed Limit of Open Quantum Systems from Magic Subspaces

Author

V., A. A. Diaz, Martikyan, V., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We introduce the concept of Magic Subspaces for the control of dissipative N- level quantum systems whose dynamics are governed by Lindblad equation. For a given purity, these subspaces can be defined as the set of density matrices for which the rate of purity change is maximum or minimum. Adding fictitious control fields to the system so that two density operators with the same purity can be connected in a very short time, we show that magic subspaces allow to derive a purity speed limit, which only depends on the relaxation rates. We emphasize the superiority of this limit with respect to established bounds and its tightness in the case of a two-level dissipative quantum system. The link between the speed limit and the corresponding time-optimal solution is discussed in the framework of this study. Explicit examples are described for two- and three- level quantum systems., Comment: 26 pages, 7 figures

Published

2020

5. Robust control of a NOT gate by composite pulses

Author

Dridi, G., Mejatty, M., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We present a general procedure to implement a NOT gate by composite pulses robust against both offset uncertainties and control field variations. We define different degrees of robustness in this two-parameter space, namely along one, two or all directions. We show that the phases of the composite pulse satisfy a nonlinear system, and can be computed analytically or numerically., Comment: 18 pages, 9 figures

Published

2020

6. Climate elasticity of evapotranspiration shifts the water balance of Mediterranean climates during multi-year droughts

Author

Avanzi, F, Rungee, J, Maurer, T, Bales, R, Ma, Q, Glaser, S, and Conklin, M

Subjects

Physical Geography and Environmental Geoscience, Civil Engineering, Environmental Engineering

Abstract

Multi-year droughts in Mediterranean climates may shift the water balance, that is, the partitioning rule of precipitation across runoff, evapotranspiration, and subsurface storage. Mechanisms causing these shifts remain largely unknown and are not well represented in hydrologic models. Focusing on measurements from the headwaters of California s Feather River, we found that also in these mixed rain snow Mediterranean basins a lower fraction of precipitation was partitioned to runoff during multi-year droughts compared to non-drought years. This shift in the precipitation runoff relationship was larger in the surfacerunoff-dominated than subsurface-flow-dominated headwaters (39% vs. 18% decline of runoff, respectively, for a representative precipitation amount). The predictive skill of the Precipitation Runoff Modeling System (PRMS) hydrologic model in these basins decreased during droughts, with evapotranspiration (ET) being the only water-balance component besides runoff for which the drop in predictive skill during drought vs. non-drought years was statistically significant. In particular, the model underestimated the response time required by ET to adjust to interannual climate variability, which we define as climate elasticity of ET. Differences between simulated and data-driven estimates of ET were well correlated with accompanying data-driven estimates of changes in sub-surface storage (1S, r D 0:78). This correlation points to shifts in precipitation runoff relationships being evidence of a hysteretic response of the water budget to climate elasticity of ET during and after multi-year droughts. This hysteresis is caused by carryover storage offsetting precipitation deficit during the initial drought period, followed by vegetation mortality when storage is depleted and subsequent post-drought vegetation expansion. Our results point to a general improvement in hydrologic predictions across drought and recovery cycles by including the climate elasticity of ET and better accounting for actual subsurface water storage in not only soil, but also deeper regolith that stores water accessible to roots. This can be done by explicitly parametrizing carryover storage and feedback mechanisms capturing vegetation response to atmospheric demand for moisture.

Published

2020

7. Time-optimal selective pulses of two uncoupled spin 1/2 particles

Author

Van Damme, L., Ansel, Q., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We investigate the time-optimal solution of the selective control of two uncoupled spin 1/2 particles. Using the Pontryagin Maximum Principle, we derive the global time-optimal pulses for two spins with different offsets. We show that the Pontryagin Hamiltonian can be written as a one-dimensional effective Hamiltonian. The optimal fields can be expressed analytically in terms of elliptic integrals. The time-optimal control problem is solved for the selective inversion and excitation processes. A bifurcation in the structure of the control fields occurs for a specific offset threshold. In particular, we show that for small offsets, the optimal solution is the concatenation of regular and singular extremals., Comment: 25 pages, 10 figures

Published

2018

8. Optimal control of an inhomogeneous spin ensemble coupled to a cavity

Author

Ansel, Q., Probst, S., Bertet, P., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We apply optimal control techniques to an inhomogeneous spin ensemble coupled to a cavity. A general procedure is proposed for designing the control strategies. We numerically show the extent to which optimal control fields robust against system uncertainties help enhancing the sensitivity of the detection process. The parameters of the numerical simulations are taken from recent Electron Spin Resonance experiments. The low and high cooperativity regimes are explored., Comment: Submitted to PRA

Published

2018

9. Optimizing fingerprinting experiments for parameter identification: Application to spin systems

Author

Ansel, Q., Tesch, M., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We introduce the Optimal Fingerprinting Process which is aimed at accurately identifying the parameters which characterize the dynamics of a physical system. A database is first built from the time evolution of an ensemble of dynamical systems driven by a specific field, which is designed by optimal control theory to maximize the efficiency of the recognition process. Curve fitting is then applied to enhance the precision of the identification. As an illustrative example, we consider the estimation of the relaxation parameters of a spin- 1/2 particle. The experimental results are in good accordance with the theoretical computations. We show on this example a physical limit of the estimation process., Comment: 21 pages, 8 figures

Published

2017

10. Optimal control theory for applications in magnetic resonance imaging

Author

Van-Reeth, E., Ratiney, H., Lapert, M., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We apply innovative mathematical tools coming from optimal control theory to improve theoretical and experimental techniques in Magnetic Resonance Imaging (MRI). This approach allows us to explore and to experimentally reach the physical limits of the corresponding spin dynamics in the presence of typical experimental imperfections and limitations. We study in this paper two important goals, namely the optimization of image contrast and the maximization of the signal to noise per unit time. We anticipate that the proposed techniques will find practical applications in medical imaging in a near future to help the medical diagnosis., Comment: 19 pages, 7 figures, to be published in Pacific Journal of Mathematics for Industry

Published

2017

11. Linking the rotation of a rigid body to the Schr\'odinger equation: The quantum tennis racket effect and beyond

Author

Van Damme, L., Leiner, D., Mardesic, P., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

The design of efficient and robust pulse sequences is a fundamental requirement in quantum control. Numerical methods can be used for this purpose, but with relatively little insight into the control mechanism. Here, we show that the free rotation of a classical rigid body plays a fundamental role in the control of two-level quantum systems by means of external electromagnetic pulses. For a state to state transfer, we derive a family of control fields depending upon two free parameters, which allow us to adjust the efficiency, the time and the robustness of the control process. As an illustrative example, we consider the quantum analog of the tennis racket effect, which is a geometric property of any classical rigid body. This effect is demonstrated experimentally for the control of a spin 1/2 particle by using techniques of Nuclear Magnetic Resonance. We also show that the dynamics of a rigid body can be used to implement one-qubit quantum gates. In particular, non-adiabatic geometric quantum phase gates can be realized based on the Montgomery phase of a rigid body. The robustness issue of the gates is discussed., Comment: 14 pages, 6 figures

Published

2017

12. Robust optimal control of two-level quantum systems

Author

Van Damme, L., Ansel, Q., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We investigate the time and the energy minimum optimal solutions for the robust control of two-level quantum systems against offset or control field uncertainties. Using the Pontryagin Maximum Principle, we derive the global optimal pulses for the first robustness orders. We show that the dimension of the control landscape is lower or equal to 2N for a field robust to the N th order, which leads to an estimate of its complexity., Comment: 30 pages, 15 figures, submitted to Phys. Rev. A

Published

2017

13. Spatially distributed water-balance and meteorological data from the rain–snow transition, southern Sierra Nevada, California

Author

Bales, R C, Stacy, E, Safeeq, M, Meng, X, Meadows, M, Oroza, C, Conklin, M H, Glaser, S, and Wagenbrenner, J

Subjects

snow, hydrology, rain

Abstract

We strategically placed spatially distributed sensors to provide representative measures of changes in snowpack and subsurface water storage, plus the fluxes affecting these stores, in a set of nested headwater catchments. The high temporal frequency and distributed coverage make the resulting data appropriate for process studies of snow accumulation and melt, infiltration, evapotranspiration, catchment water balance, (bio)geochemistry, and other critical-zone processes. We present 8 years of hourly snow-depth, soil-moisture, and soil-temperature data, as well as 14 years of quarter-hourly streamflow and meteorological data that detail water-balance processes at Providence Creek, the upper part of which is at the current 50 % rain versus snow transition of the southern Sierra Nevada, California. Providence Creek is the long-term study cooperatively run by the Southern Sierra Critical Zone Observatory (SSCZO) and the USDA Forest Service Pacific Southwest Research Station's Kings River Experimental Watersheds (KREW). The 4.6 km2 montane Providence Creek catchment spans the current lower rain–snow transition elevation of 1500–2100 m. Two meteorological stations bracket the high and low elevations of the catchment, measuring air temperature, relative humidity, solar radiation, precipitation, wind speed and direction, and snow depth, and at the higher station, snow water equivalent. Paired flumes at three subcatchments and a V-notch weir at the integrating catchment measure quarter-hourly streamflow. Measurements of meteorological and streamflow data began in 2002. Between 2008 and 2010, 50 sensor nodes were added to measure distributed snow depth, air temperature, soil temperature, and soil moisture within the top 1 m below the surface. These sensor nodes were installed to capture the lateral differences of aspect and canopy coverage. Data are available at hourly and daily intervals by water year (1 October–30 September) in nonproprietary formats from online data repositories. Data for the Southern Sierra Critical Zone Observatory distributed snow and soil datasets are at https://doi.org/10.6071/Z7WC73. Kings River Experimental Watersheds meteorological data are available from https://doi.org/10.2737/RDS-2018-0028 and stream-discharge data are available from https://doi.org/10.2737/RDS-2017-0037.

Published

2018

14. A numerical study of surface-wave-based tunnel detection at the Black Diamond Mines Regional Preserve, California

Author

Sherman, CS, Rector, J, Dreger, D, and Glaser, S

Subjects

Geochemistry & Geophysics, Geophysics

Abstract

Detecting underground voids, such as old mine workings, solution cavities in karst terrain, or unknown tunnels such as illicit cross-border tunnels, is a challenging problem for geophysics and an important concern for geotechnical design, public safety, and domestic security. Seismic surface-wave-based detection methods have become increasingly popular for detecting relatively shallow and small targets; however, the theoretical limitations of these methods have thus far remained unclear. We use a suite of 3D numerical simulations inspired by a tunnel detection experiment carried out at the Black Diamond Mines Regional Preserve (BDM) in northern California. The geophysical anomalies predicted by our numerical simulations at BDM agree with field observations, and our estimates for the location of the primary tunnel target agree with historical records in the area. Using our calibrated numerical model, we perform a parametric study to determine the effect of tunnel size, depth of burial, filling material, and source characteristics to determine the range over which surface-wave backscattering and attenuation-based methods are effective. In addition, we perform a regression analysis to determine a relationship for the maximum depth at which a tunnel may be detected via these approaches, given the target diameter, wavelength of interest, and the signal-to-noise ratio.

Published

2018

15. Precise orbit and Earth parameter determination supported by LEO satellites, inter-satellite links and synchronized clocks of a future GNSS

Author

Michalak, G., Glaser, S., Neumayer, K.H., and König, R.

Published

2021

16. A fully efficient time-parallelized quantum optimal control algorithm

Author

Riahi, Mohamed-Kamel, Salomon, Julien, Glaser, S. J., and Sugny, D

Subjects

Mathematics - Optimization and Control, Mathematics - Analysis of PDEs, Mathematics - Numerical Analysis

Abstract

We present a time-parallelization method that enables to accelerate the computation of quantum optimal control algorithms. We show that this approach is approximately fully efficient when based on a gradient method as optimization solver: the computational time is approximately divided by the number of available processors. The control of spin systems, molecular orientation and Bose-Einstein condensates are used as illustrative examples to highlight the wide range of application of this numerical scheme., Comment: Journal paper submitted to Physical Review A

Published

2016

17. A discrete-pulse optimal control algorithm with an application to spin systems

Author

Dridi, G., Lapert, M., Salomon, Julien, Sugny, D, and Glaser, S. J.

Subjects

Mathematics - Optimization and Control

Abstract

This article is aimed at extending the framework of optimal control techniques to the situation where the control field values are restricted to a finite set. We propose a generalization of the standard GRAPE algorithm suited to this constraint. We test the validity and the efficiency of this approach for the inversion of an inhomogeneous ensemble of spin systems with different offset frequencies. It is shown that a remarkable efficiency can be achieved even for a very limited number of discrete values. Some applications in Nuclear Magnetic Resonance are discussed.

Published

2015

18. Demo: SierraNet: Monitoring the snowpack in the Sierra Nevada

Author

Brun-Laguna, K, Oroza, C, Zhang, Z, Malek, S, Watteyne, T, and Glaser, S

Abstract

Next-generation hydrologic science and monitoring requires real-time, spatially distributed measurements of key variables including: soil moisture, air/soil temperature, snow depth, and air relative humidity. The SierraNet project provides these measurements by deploying low-power mesh networks across the California Sierra Nevada. This demo presents a replica of the end-to-end SierraNet monitoring system deployed in the Southern Sierra. This system is a highly reliable, low-power turn-key solution for environmental monitoring.

Published

2016

19. Optimal control of the signal to noise ratio per unit time for a spin 1/2 particle

Author

Lapert, M., Assémat, E., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We investigate the maximum signal to noise ratio per unit time that can be achieved for a spin 1/2 particle subjected to a periodic pulse sequence. Optimal control techniques are applied to design the control field and the position of the steady state, leading to the best signal to noise performance. A complete geometric description of the optimal control problem is given in the unbounded case. We show the optimality of the well-known Ernst angle solution, which is widely used in spectroscopic and medical imaging applications, over a large control space allowing use of shaped pulses., Comment: 12 pages, 4 figures

Published

2014

20. Time-optimal control of SU(2) quantum operations

Author

Garon, A., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We propose an analysis of the time-optimal control of SU(2) quantum operations. By using the Pontryagin Maximum Principle, we show how to determine the optimal trajectory reaching a given target state. Explicit analytical solutions are given for two specific examples. We discuss the role of the detuning in the construction of the optimal synthesis., Comment: 24 pages, 8 figures

Published

2013

21. Advanced technologies for satellite navigation and geodesy

Author

Giorgi, G., Schmidt, T.D., Trainotti, C., Mata-Calvo, R., Fuchs, C., Hoque, M.M., Berdermann, J., Furthner, J., Günther, C., Schuldt, T., Sanjuan, J., Gohlke, M., Oswald, M., Braxmaier, C., Balidakis, K., Dick, G., Flechtner, F., Ge, M., Glaser, S., König, R., Michalak, G., Murböck, M., Semmling, M., and Schuh, H.

Published

2019

22. Exploring the physical limits of saturation contrast in Magnetic Resonance Imagign

Author

Lapert, M., Zhang, Y., Janich, M., Glaser, S. J., and Sugny, D.

Subjects

Physics - Medical Physics, Quantum Physics

Abstract

Magnetic Resonance Imaging has become nowadays an indispensable tool with applications ranging from medicine to material science. However, so far the physical limits of the maximum achievable experimental contrast were unknown. We introduce an approach based on principles of optimal control theory to explore these physical limits, providing a benchmark for numerically optimized robust pulse sequences which can take into account experimental imperfections. This approach is demonstrated experimentally using a model system of two spatially separated liquids corresponding to blood in its oxygenated and deoxygenated forms., Comment: 11 pages, 4 figures. This paper is in open access, Nature-Scientific Reports

Published

2012

23. Geometric optimal control of the contrast imaging problem in Nuclear Magnetic Resonance

Author

Bonnard, B., Cots, O., Glaser, S. J., Lapert, M., Sugny, D., and Zhang, Y.

Subjects

Quantum Physics, Physics - Medical Physics

Abstract

The objective of this article is to introduce the tools to analyze the contrast imaging problem in Nuclear Magnetic Resonance. Optimal trajectories can be selected among extremal solutions of the Pontryagin Maximum Principle applied to this Mayer type optimal problem. Such trajectories are associated to the question of extremizing the transfer time. Hence the optimal problem is reduced to the analysis of the Hamiltonian dynamics related to singular extremals and their optimality status. This is illustrated by using the examples of cerebrospinal fluid / water and grey / white matter of cerebrum., Comment: 30 pages, 13 figure

Published

2012

24. Saturation of a spin 1/2 particle by generalized Local control

Author

Mintert, F., Lapert, M., Zhang, Y., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We show how to apply a generalization of Local control design to the problem of saturation of a spin 1/2 particle by magnetic fields in Nuclear Magnetic Resonance. The generalization of local or Lyapunov control arises from the fact that the derivative of the Lyapunov function does not depend explicitly on the control field. The second derivative is used to determine the local control field. We compare the efficiency of this approach with respect to the time-optimal solution which has been recently derived using geometric methods., Comment: 12 pages, 4 figures, submitted to new journal of physics (2011)

Published

2011

25. Second order gradient ascent pulse engineering

Author

de Fouquieres, P., Schirmer, S. G., Glaser, S. J., and Kuprov, Ilya

Subjects

Quantum Physics, Mathematical Physics

Abstract

We report some improvements to the gradient ascent pulse engineering (GRAPE) algorithm for optimal control of quantum systems. These include more accurate gradients, convergence acceleration using the BFGS quasi-Newton algorithm as well as faster control derivative calculation algorithms. In all test systems, the wall clock time and the convergence rates show a considerable improvement over the approximate gradient ascent., Comment: Submitted for publication

Published

2011

26. Comparing, Optimising and Benchmarking Quantum Control Algorithms in a Unifying Programming Framework

Author

Machnes, S., Sander, U., Glaser, S. J., de Fouquieres, P., Gruslys, A., Schirmer, S., and Schulte-Herbrueggen, T.

Subjects

Quantum Physics, Mathematics - Optimization and Control

Abstract

For paving the way to novel applications in quantum simulation, computation, and technology, increasingly large quantum systems have to be steered with high precision. It is a typical task amenable to numerical optimal control to turn the time course of pulses, i.e. piecewise constant control amplitudes, iteratively into an optimised shape. Here, we present the first comparative study of optimal control algorithms for a wide range of finite-dimensional applications. We focus on the most commonly used algorithms: GRAPE methods which update all controls concurrently, and KROTOV-type methods which do so sequentially. Guidelines for their use are given and open research questions are pointed out. --- Moreover we introduce a novel unifying algorithmic framework, DYNAMO (dynamic optimisation platform) designed to provide the quantum-technology community with a convenient MATLAB-based toolset for optimal control. In addition, it gives researchers in optimal-control techniques a framework for benchmarking and comparing new proposed algorithms to the state-of-the-art. It allows for a mix-and-match approach with various types of gradients, update and step-size methods as well as subspace choices. Open-source code including examples is made available at http://qlib.info., Comment: update incl. 3 new figures, comments welcome

Published

2010

27. Simultaneous time-optimal control of the inversion of two spin 1/2 particles

Author

Assemat, E., Lapert, M., Zhang, Y., Braun, M., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics

Abstract

We analyze the simultaneous time-optimal control of two-spin systems. The two non coupled spins which differ in the value of their chemical offsets are controlled by the same magnetic fields. Using an appropriate rotating frame, we restrict the study to the case of opposite shifts. We then show that the optimal solution of the inversion problem in a rotating frame is composed of a pulse sequence of maximum intensity and is similar to the optimal solution for inverting only one spin by using a non-resonant control field in the laboratory frame. An example is implemented experimentally using techniques of Nuclear Magnetic Resonance., Comment: 13 pages, 3 figures

Published

2010

28. Singular extremals for the time-optimal control of dissipative spin 1/2 particles

Author

Lapert, M., Zhang, Y., Braun, M., Glaser, S. J., and Sugny, D.

Subjects

Quantum Physics, Physics - Chemical Physics

Abstract

We consider the time-optimal control by magnetic fields of a spin 1/2 particle in a dissipative environment. This system is used as an illustrative example to show the role of singular extremals in the control of quantum systems. We analyze a simple case where the control law is explicitly determined. We experimentally implement the optimal control using techniques of nuclear magnetic resonance. To our knowledge, this is the first experimental demonstration of singular extremals in quantum systems with bounded control amplitudes., Comment: 10 pages, 3 figures

Published

2010

29. Extracting high fidelity quantum computer hardware from random systems

Author

Walther, A., Julsgaard, B., Rippe, L., Ying, Yan, Kröll, S., Fisher, R., and Glaser, S.

Subjects

Quantum Physics

Abstract

An overview of current status and prospects of the development of quantum computer hardware based on inorganic crystals doped with rare-earth ions is presented. Major parts of the experimental work in this area has been done in two places, Canberra, Australia and Lund, Sweden, and the present description follows more closely the Lund work. Techniques will be described that include optimal filtering of the initially inhomogeneously broadened profile down to well separated and narrow ensembles, as well as the use of advanced pulse-shaping in order to achieve robust arbitrary single-qubit operations with fidelities above 90%, as characterized by quantum state tomography. It is expected that full scalability of these systems will require the ability to determine the state of single rare-earth ions. It has been proposed that this can be done using special readout ions doped into the crystal and an update is given on the work to find and characterize such ions. Finally, a few aspects on the possibilities for remote entanglement of ions in separate rare-earth-ion-doped crystals are considered., Comment: 19 pages, 9 figures. Written for The Proceedings of the Nobelsymposium on qubits for future quantum computers, Gothenburg, May-09

Published

2010

30. Optimal control of circuit quantum electrodynamics in one and two dimensions

Author

Fisher, R., Helmer, F., Glaser, S. J., Marquardt, F., and Schulte-Herbrueggen, T.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Optimal control can be used to significantly improve multi-qubit gates in quantum information processing hardware architectures based on superconducting circuit quantum electrodynamics. We apply this approach not only to dispersive gates of two qubits inside a cavity, but, more generally, to architectures based on two-dimensional arrays of cavities and qubits. For high-fidelity gate operations, simultaneous evolutions of controls and couplings in the two coupling dimensions of cavity grids are shown to be significantly faster than conventional sequential implementations. Even under experimentally realistic conditions speedups by a factor of three can be gained. The methods immediately scale to large grids and indirect gates between arbitrary pairs of qubits on the grid. They are anticipated to be paradigmatic for 2D arrays and lattices of controllable qubits., Comment: Published version.

Published

2009

31. Gradient Flows for Optimisation and Quantum Control: Foundations and Applications

Author

Schulte-Herbrueggen, T., Glaser, S. J., Dirr, G., and Helmke, U.

Subjects

Quantum Physics, Mathematical Physics, Mathematics - Optimization and Control

Abstract

For addressing optimisation tasks on finite dimensional quantum systems, we give a comprehensive account of the foundations of gradient flows on Riemannian manifolds including new developments: we extend former results from Lie groups such as the full unitary group to closed subgroups like partitionings by factorisation into tensor products, where the finest partitioning consists of purely local unitary operations. Moreover, the common framework is kept sufficiently general and allows for setting up gradient flows on (sub-)manifolds, Lie (sub-)groups, quotient groups, and reductive homogeneous spaces. Relevant convergence conditions are discussed meant to serve as justification for recent and new achievements, and as foundation for further research. Exploiting the differential geometry of quantum dynamics under different scenarios helps to provide highly useful algorithms: (a) On an abstract level, gradient flows may establish the exact upper bounds of pertinent quality functions, i.e. upper bounds reachable within the underlying manifold of the state space dynamics; (b) in a second stage referring to a concrete experimental setting, gradient flows on the manifold of piecewise constant control amplitudes $\R^m$ may be set up to provide (approximations to) optimal control of quantum devices under realistic conditions. Illustrative examples and new applications are given relating to distance measures of pure-state entanglement. We establish the correspondence to best rank-1 approximations of higher-order tensors., Comment: updated version with further references

Published

2008

32. Quantum CISC Compilation by Optimal Control and Scalable Assembly of Complex Instruction Sets beyond Two-Qubit Gates

Author

Schulte-Herbrueggen, T., Spoerl, A., and Glaser, S. J.

Subjects

Quantum Physics

Abstract

We present a quantum CISC compiler and show how to assemble complex instruction sets in a scalable way. Enlarging the toolbox of universal gates by optimised complex multi-qubit instruction sets thus paves the way to fight decoherence for realistic settings. Compiling a quantum module into the machine code for steering a concrete quantum hardware device lends itself to be tackled by means of optimal quantum control. To this end, there are two opposite approaches: (i) one may use a decomposition into the restricted instruction set (RISC) of universal one- and two-qubit gates, which in turn have prefabricated translations into the machine code or (ii) one may prefer to generate the entire target module directly by a complex instruction set (CISC) of available controls. Here we advocate direct compilation up to the limit of system size a classical high-performance parallel computer cluster can reasonably handle. For going beyond these limits, i.e. for large systems we propose a combined way, namely (iii) to make recursive use of medium-sized building blocks generated by optimal control in the sense of a quantum CISC compiler. The advantage of the method over standard RISC compilations into one- and two-qubit universal gates is explored on the parallel cluster HLRB-II (with a total LINPACK performance of 63.3 TFlops/s) for the quantum Fourier transform, the indirect SWAP gate as well as for multiply-controlled CNOT gates. Implications for upper limits to time complexities are also derived., Comment: substantially enlarged update with new sections; 19 pages, 17 figures; comments welcome

Published

2007

33. Optimal Control for Generating Quantum Gates in Open Dissipative Systems

Author

Schulte-Herbrueggen, T., Spoerl, A., Khaneja, N., and Glaser, S. J.

Subjects

Quantum Physics

Abstract

Optimal control methods for implementing quantum modules with least amount of relaxative loss are devised to give best approximations to unitary gates under relaxation. The potential gain by optimal control using relaxation parameters against time-optimal control is explored and exemplified in numerical and in algebraic terms: it is the method of choice to govern quantum systems within subspaces of weak relaxation whenever the drift Hamiltonian would otherwise drive the system through fast decaying modes. In a standard model system generalising decoherence-free subspaces to more realistic scenarios, openGRAPE-derived controls realise a CNOT with fidelities beyond 95% instead of at most 15% for a standard Trotter expansion. As additional benefit it requires control fields orders of magnitude lower than the bang-bang decouplings in the latter., Comment: largely expanded version, superseedes v1: 10 pages, 5 figures

Published

2006

34. Composite Dipolar Recoupling: Anisotropy Compensated Coherence Transfer in Solid-State NMR

Author

Khaneja, N., Kehlet, C., Glaser, S. J., and Nielsen, N. C.

Subjects

Quantum Physics

Abstract

The efficiency of dipole-dipole coupling driven coherence transfer experiments in solid-state NMR spectroscopy of powder samples is limited by dispersion of the orientation of the internuclear vectors relative to the external magnetic field. Here we introduce general design principles and resulting pulse sequences that approach full polarization transfer efficiency for all crystallite orientations in a powder in magic-angle-spinning experiments. The methods compensate for the defocusing of coherence due to orientation dependent dipolar coupling interactions and inhomogeneous radio-frequency fields. The compensation scheme is very simple to implement as a scaffold (comb) of compensating pulses in which the pulse sequence to be improved may be inserted. The degree of compensation can be adjusted and should be balanced as a compromise between efficiency and length of the overall pulse sequence. We show by numerical and experimental data that the presented compensation protocol significantly improves the efficiency of known dipolar recoupling solid-state NMR experiment.

Published

2006

35. Optimal Control of Coupled Josephson Qubits

Author

Spoerl, A. K., Schulte-Herbrueggen, T., Glaser, S. J., Bergholm, V., Storcz, M. J., Ferber, J., and Wilhelm, F. K.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum optimal control theory is applied to two and three coupled Josephson charge qubits. It is shown that by using shaped pulses a CNOT gate can be obtained with a trace fidelity > 0.99999 for the two qubits, and even when including higher charge states, the leakage is below 1%. Yet, the required time is only a fifth of the pioneering experiment [T. Yamamoto et al., Nature 425 (2003), 941] for otherwise identical parameters. The controls have palindromic smooth time courses representable by superpositions of a few harmonics. We outline schemes to generate these shaped pulses such as simple network synthesis. The approach is easy to generalise to larger systems as shown by a fast realisation of TOFFOLI's gate in three linearly coupled charge qubits. Thus it is to be anticipated that this method will find wide application in coherent quantum control of systems with finite degrees of freedom whose dynamics are Lie-algebraically closed.

Published

2005

36. Optimal Control-Based Efficient Synthesis of Building Blocks of Quantum Algorithms Seen in Perspective from Network Complexity towards Time Complexity

Author

Schulte-Herbrueggen, T., Spoerl, A. K., Khaneja, N., and Glaser, S. J.

Subjects

Quantum Physics

Abstract

In this paper, we demonstrate that optimal control algorithms can be used to speed up the implementation of modules of quantum algorithms or quantum simulations in networks of coupled qubits. The gain is most prominent in realistic cases, where the qubits are not all mutually coupled. Thus the shortest times obtained depend on the coupling topology as well as on the characteristicratio of the time scales for local controls {\em vs} non-local ({\em i.e.} coupling) evolutions in the specific experimental setting. Relating these minimal times to the number of qubits gives the tightest known upper bounds to the actual time complexity of the quantum modules. As will be shown, time complexity is a more realistic measure of the experimental cost than the usual gate complexity. In the limit of fast local controls (as {\em e.g.} in NMR), time-optimised realisations are shown for the quantum Fourier transform (QFT) and the multiply controlled {\sc not}-gate ({\sc c$^{n-1}$not}) in various coupling topologies of $n$ qubits. The speed-ups are substantial: in a chain of six qubits the quantum Fourier transform so far obtained by optimal control is more than eight times faster than the standard decomposition into controlled phase, Hadamard and {\sc swap} gates, while the {\sc c$^{n-1}$not}-gate for completely coupled network of six qubits is nearly seven times faster., Comment: 7 pages, 5 figures, REVTEX

Published

2005

37. Broadband Relaxation-Optimized Polarization Transfer in Magnetic Resonance

Author

Khaneja, N., Li, J. S., Kehlet, C., Luy, B., and Glaser, S. J.

Subjects

Quantum Physics

Abstract

Many applications of magnetic resonance are limited by rapid loss of spin coherence caused by large transverse relaxation rates. In nuclear magnetic resonance (NMR) of large proteins, increased relaxation losses lead to poor sensitivity of experiments and increased measurement time. In this paper we develop broadband relaxation optimized pulse sequences (BB-CROP) which approach fundamental limits of coherence transfer efficiency in the presence of very general relaxation mechanisms that include cross-correlated relaxation. These broadband transfer schemes use new techniques of chemical shift refocusing (STAR echoes) that are tailored to specific trajectories of coupled spin evolution. We present simulations and experimental data indicating significant enhancement in the sensitivity of multi-dimensional NMR experiments of large molecules by use of these methods.

Published

2004

38. Boundary of Quantum Evolution under Decoherence

Author

Khaneja, N., Luy, B., and Glaser, S. J.

Subjects

Quantum Physics

Abstract

Relaxation effects impose fundamental limitations on our ability to coherently control quantum mechanical phenomena. In this letter, we establish physical limits on how closely can a quantum mechanical system be steered to a desired target state in the presence of relaxation. In particular, we explicitly compute the maximum coherence or polarization that can be transferred between coupled nuclear spins in the presence of very general decoherence mechanisms that include cross-correlated relaxation. We give analytical expressions for the control laws (pulse sequences) which achieve these physical limits and provide supporting experimental evidence. Exploitation of cross-correlation effects has recently led to the development of powerful methods in NMR spectroscopy to study very large biomolecules in solution. We demonstrate with experiments that the optimal pulse sequences provide significant gains over these state of the art methods, opening new avenues for spectroscopy of much larger proteins. Surprisingly, in spite of very large relaxation rates, optimal control can transfer coherence without any loss when cross-correlated relaxation rates are tuned to auto-correlated relaxation rates.

Published

2003

39. Rapid solution of problems by nuclear-magnetic-resonance quantum computation

Author

Myers, John M., Fahmy, A. F., Glaser, S. J., and Marx, R.

Subjects

Quantum Physics

Abstract

We offer an improved method for using a nuclear-magnetic-resonance quantum computer (NMRQC) to solve the Deutsch-Jozsa problem. Two known obstacles to the application of the NMRQC are exponential diminishment of density-matrix elements with the number of bits, threatening weak signal levels, and the high cost of preparing a suitable starting state. A third obstacle is a heretofore unnoticed restriction on measurement operators available for use by an NMRQC. Variations on the function classes of the Deutsch-Jozsa problem are introduced, both to extend the range of problems advantageous for quantum computation and to escape all three obstacles to use of an NMRQC. By adapting it to one such function class, the Deutsch-Jozsa problem is made solvable without exponential loss of signal. The method involves an extra work bit and a polynomially more involved Oracle; it uses the thermal-equilibrium density matrix systematically for an arbitrary number of spins, thereby avoiding both the preparation of a pseudopure state and temporal averaging., Comment: 19 pages

Published

2000

40. Realization of a 5-bit NMR Quantum Computer Using a New Molecular Architecture

Author

Marx, R., Fahmy, A. F., Myers, J. M., Bermel, W., and Glaser, S. J.

Subjects

Quantum Physics

Abstract

We demonstrate a five-bit nuclear-magnetic-resonance quantum computer that distinguishes among various functions on four bits, making use of quantum parallelism. Its construction draws on the recognition of the sufficiency of linear coupling along a chain of nuclear spins, the synthesis of a suitably coupled molecule, and the use of a multi-channel spectrometer., Comment: 7 pages, 4 figures, 1 table

Published

1999

41. Outbreak of Salmonella Goldcoast Infections Linked to Consumption of Fermented Sausage, Germany 2001

Author

Bremer, V., Leitmeyer, K., Jensen, E., Metzel, U., Meczulat, H., Weise, E., Werber, D., Tschaepe, H., Kreienbrock, L., Glaser, S., and Ammon, A.

Published

2004

42. The DNA methylation status of the TERT promoter differs between subtypes of mature B-cell lymphomas

Author

Kouroukli, A.G., Fischer, A., Kretzmer, H., Chteinberg, E., Rajaram, N., Glaser, S., Kolarova, J., Bashtrykov, P., Mathas, S., Drexler, H.G., Ohno, H., Ammerpohl, O., Jeltsch, A., Siebert, R., and Bens, S.

Subjects

Cancer Research

Published

2023

43. On the improvement of the sensitivity levels of VLBI solutions from a combination with GNSS

Author

Küreç Nehbit, P., Glaser, S., Sakic, P., Balidakis, K., Heinkelmann, R., Schuh, H., and Konak, H.

Abstract

Very Long Baseline Interferometry (VLBI) is the only technique that connects the celestial and the terrestrial reference frames. Because of its essential role, it is important to investigate the quality of VLBI observations and their effect on the estimated parameters. The fundamental goal of the quality assessment using the sensitivity is to find out to what level VLBI can detect station displacements in the adjusted coordinates. However, the global VLBI station network is worse in terms of the number and global distribution of stations when compared to the GNSS station network. In this study, we aim to improve the capacity of VLBI to detect station displacements through an inter-technique combination with GNSS. The effect of the selection of co-location sites in the inter-technique combination is investigated with four scenarios and we investigate how the sensitivity is affected by the assumed standard deviations of the local ties. The lower the standard deviations of the local ties, the higher the obtained sensitivity level. When larger standard deviations are assumed, the sensitivity levels of the VLBI stations are obtained up to 3 mm. When a smaller deviation is assumed for a local tie having various standard deviations obtained from different local tie observations, the sensitivity levels change too. If local ties with standard deviations of 1 cm and more are excluded, the detection capacities of the VLBI stations based on the gross errors improve by around 1 mm. When smaller standard deviations are assumed among the local ties, which are used in the inter-technique combination, the sensitivity levels drop below 2 mm. Hence, this study quantifies how important the selection of the co-location sites and the standard deviations of the local ties are for the accuracy of geodetic products obtained by inter-technique combination.

Published

2023

44. The streaming potential of liquid carbon dioxide in Brea Sandstone

Author

Moore, J., Glaser, S., Morrison, F., and Hoversten, G.M.

Subjects

Environmental sciences

Abstract

We report here, for the first time, evolution of the streaming potential coupling coefficient as liquid carbon dioxide infiltrates Berea sandstone. Using 125 Omega-m tap water, the coupling coefficient determined before and after each CO2 flood of five samples averaged approximately -30 mV/0.1 MPa. After liquid CO2 passed through the specimens displacing all mobile pore water, trapped water remained and the coupling coefficient was approximately -3 mV/0.1 MPa. A bound water limit of the coupling coefficient for liquid CO2 flow was foundusing an air-dried sample to be -0.02 mV/0.1 MPa. For initially water-saturated samples, bulk resistivity varied during CO2 invasion from 330 Ohm-m, to 150 Ohm-m during CO2/water mixing, to a final value of 380 Ohm-m. Results suggest that trapped and bound water control electrical conduction and the electrokinetic response. Applications include monitoring CO2 injectate in subsurface reservoirs using the self potential method.

Published

2004

45. The streaming potential of liquid carbon dioxide in Berea sandstone

Author

Moore, Jeffrey R, Glaser, S D, Morrison, H F, and Hoversten, G M

Subjects

streaming potential, self potential, resistivity, carbon dioxide

Abstract

We report here, for the first time, evolution of the streaming potential coupling coefficient as liquid carbon dioxide infiltrates Berea sandstone. Using 125 Omega-m tap water, the coupling coefficient determined before and after each CO2 flood of five samples averaged approximately -30 mV/0.1 MPa. After liquid CO2 passed through the specimens displacing all mobile pore water, trapped water remained and the coupling coefficient was approximately -3 mV/0.1 MPa. A bound water limit of the coupling coefficient for liquid CO2 flow was found using an air-dried sample to be -0.02 mV/0.1 MPa. For initially water-saturated samples, bulk resistivity varied during CO2 invasion from 330 Ohm-m, to 150 Ohm-m during CO2/water mixing, to a final value of 380 Ohm-m. Results suggest that trapped and bound water control electrical conduction and the electrokinetic response. Applications include monitoring CO2 injectate in subsurface reservoirs using the self potential method.

Published

2004

46. Microseismic source deconvolution: Wiener filter versus minimax, Fourier versus wavelets, and linear versus nonlinear

Author

Ching, J Y, To, A C, and Glaser, S D

Abstract

Deconvolution is commonly performed on microseismic signals to determine the time history of a dislocation source, usually modeled as combinations of forces or couples. This paper presents a new deconvolution method that uses a nonlinear thresholding estimator, which is based on the minimax framework and operates in the wavelet domain. Experiments were performed on a steel plate using artificially generated microseismic signals, which were recorded by high-fidelity displacement sensors at various locations. The source functions were deconvolved from the recorded signals by Wiener filters and the new method. Results were compared and show that the new method outperforms the other methods in terms of reducing noise while keeping the sharp features of the source functions. Other advantages of the nonlinear thresholding estimator include (1) its performance is close to that of a minimax estimator, (2) it is nonlinear and takes advantage of sparse representations under wavelet bases, and (3) its computation is faster than the fast Fourier transforms. (C) 2004 Acoustical Society of America.

Published

2004

47. Role of ductular reaction and ductular–canalicular junctions in identifying severe primary biliary cholangitis

Author

Overi, D, Carpino, G, Cristoferi, L, Onori, P, Kennedy, L, Francis, H, Zucchini, N, Rigamonti, C, Vigano, M, Floreani, A, D'Amato, D, Gerussi, A, Venere, R, Alpini, G, Glaser, S, Alvaro, D, Invernizzi, P, Gaudio, E, Cardinale, V, Carbone, M, Overi D., Carpino G., Cristoferi L., Onori P., Kennedy L., Francis H., Zucchini N., Rigamonti C., Vigano M., Floreani A., D'Amato D., Gerussi A., Venere R., Alpini G., Glaser S., Alvaro D., Invernizzi P., Gaudio E., Cardinale V., Carbone M., Overi, D, Carpino, G, Cristoferi, L, Onori, P, Kennedy, L, Francis, H, Zucchini, N, Rigamonti, C, Vigano, M, Floreani, A, D'Amato, D, Gerussi, A, Venere, R, Alpini, G, Glaser, S, Alvaro, D, Invernizzi, P, Gaudio, E, Cardinale, V, Carbone, M, Overi D., Carpino G., Cristoferi L., Onori P., Kennedy L., Francis H., Zucchini N., Rigamonti C., Vigano M., Floreani A., D'Amato D., Gerussi A., Venere R., Alpini G., Glaser S., Alvaro D., Invernizzi P., Gaudio E., Cardinale V., and Carbone M.

Abstract

Background & Aims: Primary biliary cholangitis (PBC) is a chronic cholangiopathy characterised by immuno-mediated injury of interlobular bile ducts leading to intrahepatic cholestasis and progressive liver fibrosis. PBC histology is characterised by portal inflammation, progressive fibrosis, ductopenia, and the appearance of the so-called ductular reaction. The aim of the present study was to investigate the pathogenetic relevance of ductular reaction in PBC. Methods: Liver biopsies were collected from naïve people with PBC (N = 87). Clinical–serological parameters were obtained at diagnosis and after 1 year of ursodeoxycholic acid (UDCA) treatment. Histological staging was performed on all slides according to multiple scoring systems and criteria for PBC. Liver samples were obtained from Mdr2−/− mice treated with or without UDCA. Samples were processed for histology, immunohistochemistry, and immunofluorescence. Results: Ductular reaction in people with PBC correlated with the disease stage and liver fibrosis, but not with disease activity; an extensive ductular reaction correlated with serum alkaline phosphatase levels at diagnosis, response to UDCA, and individuals’ estimated survival, independently from other histological parameters, including disease stage. In people with PBC, reactive ductules were associated with the establishment of junctions with bile canaliculi and with fibrogenetic cell activation. Consistently, in a mouse model of intrahepatic cholestasis, UDCA treatment was effective in reducing ductular reaction and fibrosis and increasing ductular–canalicular junctions. Conclusions: Extensive ductular reaction outlines a severe histologic phenotype in PBC and is associated with an inadequate therapy response and a worse estimated prognosis. Lay summary: In people affected by primary biliary cholangitis (PBC), the histological appearance of extensive ductular reaction identifies individuals at risk of progressive fibrosis. Ductular reaction at dia

Published

2022

48. Unitary Control in Quantum Ensembles: Maximizing Signal Intensity in Coherent Spectroscopy

Author

Glaser, S. J., Schulte-Herbrüggen, T., Sieveking, M., Schedletzky, O., Nielsen, N. C., Sørensen, O. W., and Griesinger, C.

Published

1998

49. A complex past : historical and contemporary fisheries demonstrate nonlinear dynamics and a loss of determinism

Author

Klein, E. S., Glaser, S. M., Jordaan, A., Kaufman, L., and Rosenberg, A. A.

Published

2016

50. Discriminating between tectonic transients and processing artifacts in GNSS displacement time series: A case study from the Cascadia subduction margin

Author

Garcia, C., Bedford, J., Männel, B., Glaser, S., and Schuh, H.

Abstract

Throughout the earthquake cycle at fault zones, Earth's crust undergoes deformations. GNSS coordinate time series reveals tectonic motion, seismic displacements, and periodic signatures. Additional motion patterns are usually summarized as transient tectonic signals, i.e., unexpected accelerations with respect to standard trajectory models. As the number of permanent stations increases and as time series grow, we are increasingly able to recognize transient tectonic signals. Since some of these suspected tectonic transients have subtle magnitudes or sometimes unusual spatiotemporal features, we need to develop methods for determining which transients are artifacts and which are of a tectonic origin.Here, we investigate the impact of certain GNSS processing choices and how they affect the appearance of transients in the GNSS displacement time series solutions. In our study, we choose data from Cascadia, a region for which the occurrence of transients in the GNSS time series is well known. To control our database, we processed data based on network solutions from 150 carefully selected GNSS stations for the time between 2015 and 2020. Then, we have an opportunity to discriminate between tectonic transients and processing artifacts in the GNSS displacement time series. We will discuss the detected transients against selected GNSS-related indicators (data quality, observation residuals, troposphere delays, etc.) to identify potential GNSS artifacts aliasing into the transient signals., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published

2023