Your search keyword '"Martinis, J. M."' showing total 112 results

1. A blueprint for demonstrating quantum supremacy with superconducting qubits

Author

Neill, C., Roushan, P., Kechedzhi, K., Boixo, S., Isakov, S. V., Smelyanskiy, V., Barends, R., Burkett, B., Chen, Y., Chen, Z., Chiaro, B., Dunsworth, A., Fowler, A., Foxen, B., Graff, R., Jeffrey, E., Kelly, J., Lucero, E., Megrant, A., Mutus, J., Neeley, M., Quintana, C., Sank, D., Vainsencher, A., Wenner, J., White, T. C., Neven, H., and Martinis, J. M.

Subjects

Quantum Physics

Abstract

Fundamental questions in chemistry and physics may never be answered due to the exponential complexity of the underlying quantum phenomena. A desire to overcome this challenge has sparked a new industry of quantum technologies with the promise that engineered quantum systems can address these hard problems. A key step towards demonstrating such a system will be performing a computation beyond the capabilities of any classical computer, achieving so-called quantum supremacy. Here, using 9 superconducting qubits, we demonstrate an immediate path towards quantum supremacy. By individually tuning the qubit parameters, we are able to generate thousands of unique Hamiltonian evolutions and probe the output probabilities. The measured probabilities obey a universal distribution, consistent with uniformly sampling the full Hilbert-space. As the number of qubits in the algorithm is varied, the system continues to explore the exponentially growing number of states. Combining these large datasets with techniques from machine learning allows us to construct a model which accurately predicts the measured probabilities. We demonstrate an application of these algorithms by systematically increasing the disorder and observing a transition from delocalized states to localized states. By extending these results to a system of 50 qubits, we hope to address scientific questions that are beyond the capabilities of any classical computer.

Published

2017

2. Ergodic dynamics and thermalization in an isolated quantum system

Author

Neill, C., Roushan, P., Fang, M., Chen, Y., Kolodrubetz, M., Chen, Z., Megrant, A., Barends, R., Campbell, B., Chiaro, B., Dunsworth, A., Jeffrey, E., Kelly, J., Mutus, J., O'Malley, P. J. J., Quintana, C., Sank, D., Vainsencher, A., Wenner, J., White, T. C., Polkovnikov, A., and Martinis, J. M.

Subjects

Quantum Physics

Abstract

Statistical mechanics is founded on the assumption that all accessible configurations of a system are equally likely. This requires dynamics that explore all states over time, known as ergodic dynamics. In isolated quantum systems, however, the occurrence of ergodic behavior has remained an outstanding question. Here, we demonstrate ergodic dynamics in a small quantum system consisting of only three superconducting qubits. The qubits undergo a sequence of rotations and interactions and we measure the evolution of the density matrix. Maps of the entanglement entropy show that the full system can act like a reservoir for individual qubits, increasing their entropy through entanglement. Surprisingly, these maps bear a strong resemblance to the phase space dynamics in the classical limit; classically chaotic motion coincides with higher entanglement entropy. We further show that in regions of high entropy the full multi-qubit system undergoes ergodic dynamics. Our work illustrates how controllable quantum systems can investigate fundamental questions in non-equilibrium thermodynamics.

Published

2016

3. Scalable Quantum Simulation of Molecular Energies

Author

O'Malley, P. J. J., Babbush, R., Kivlichan, I. D., Romero, J., McClean, J. R., Barends, R., Kelly, J., Roushan, P., Tranter, A., Ding, N., Campbell, B., Chen, Y., Chen, Z., Chiaro, B., Dunsworth, A., Fowler, A. G., Jeffrey, E., Megrant, A., Mutus, J. Y., Neill, C., Quintana, C., Sank, D., Vainsencher, A., Wenner, J., White, T. C., Coveney, P. V., Love, P. J., Neven, H., Aspuru-Guzik, A., and Martinis, J. M.

Subjects

Quantum Physics, Physics - Chemical Physics

Abstract

We report the first electronic structure calculation performed on a quantum computer without exponentially costly precompilation. We use a programmable array of superconducting qubits to compute the energy surface of molecular hydrogen using two distinct quantum algorithms. First, we experimentally execute the unitary coupled cluster method using the variational quantum eigensolver. Our efficient implementation predicts the correct dissociation energy to within chemical accuracy of the numerically exact result. Second, we experimentally demonstrate the canonical quantum algorithm for chemistry, which consists of Trotterization and quantum phase estimation. We compare the experimental performance of these approaches to show clear evidence that the variational quantum eigensolver is robust to certain errors. This error tolerance inspires hope that variational quantum simulations of classically intractable molecules may be viable in the near future., Comment: 13 pages, 7 figures. This revision is to correct an error in the coefficients of identity in Table 1

Published

2015

4. Observation of topological transitions in interacting quantum circuits

Author

Roushan, P., Neill, C., Chen, Yu, Kolodrubetz, M., Quintana, C., Leung, N., Fang, M., Barends, R., Campbell, B., Chen, Z., Chiaro, B., Dunsworth, A., Jeffrey, E., Kelly, J., Megrant, A., Mutus, J., O'Malley, P., Sank, D., Vainsencher, A., Wenner, J., White, T., Polkovnikov, A., Cleland, A. N., and Martinis, J. M.

Subjects

Quantum Physics

Abstract

The discovery of topological phases in condensed matter systems has changed the modern conception of phases of matter. The global nature of topological ordering makes these phases robust and hence promising for applications. However, the non-locality of this ordering makes direct experimental studies an outstanding challenge, even in the simplest model topological systems, and interactions among the constituent particles adds to this challenge. Here we demonstrate a novel dynamical method to explore topological phases in both interacting and non-interacting systems, by employing the exquisite control afforded by state-of-the-art superconducting quantum circuits. We utilize this method to experimentally explore the well-known Haldane model of topological phase transitions by directly measuring the topological invariants of the system. We construct the topological phase diagram of this model and visualize the microscopic evolution of states across the phase transition, tasks whose experimental realizations have remained elusive. Furthermore, we developed a new qubit architecture that allows simultaneous control over every term in a two-qubit Hamiltonian, with which we extend our studies to an interacting Hamiltonian and discover the emergence of an interaction-induced topological phase. Our implementation, involving the measurement of both global and local textures of quantum systems, is close to the original idea of quantum simulation as envisioned by R. Feynman, where a controllable quantum system is used to investigate otherwise inaccessible quantum phenomena. This approach demonstrates the potential of superconducting qubits for quantum simulation and establishes a powerful platform for the study of topological phases in quantum systems.

Published

2014

5. Fast Scalable State Measurement with Superconducting Qubits

Author

Sank, Daniel, Jeffrey, Evan, Mutus, J. Y., White, T. C., Kelly, J., Barends, R., Chen, Y., Chen, Z., Chiaro, B., Dunsworth, A., Megrant, A., O'Malley, P. J. J., Neill, C., Roushan, P., Vainsencher, A., Wenner, J., Cleland, A. N., and Martinis, J. M.

Subjects

Quantum Physics

Abstract

Progress in superconducting qubit experiments with greater numbers of qubits or advanced techniques such as feedback requires faster and more accurate state measurement. We have designed a multiplexed measurement system with a bandpass filter that allows fast measurement without increasing environmental damping of the qubits. We use this to demonstrate simultaneous measurement of four qubits on a single superconducting integrated circuit, the fastest of which can be measured to 99.8% accuracy in 140ns. This accuracy and speed is suitable for advanced multi-qubit experiments including surface code error correction., Comment: Five figures

Published

2014

6. Demonstration of a Tuneable Coupler for Superconducting Qubits Using Coherent, Time Domain, Two-Qubit Operations

Author

Bialczak, R. C., Ansmann, M., Hofheinz, M., Lenander, M., Lucero, E., Neeley, M., O'Connell, A. D., Sank, D., Wang, H., Weides, M., Wenner, J., Yamamoto, T., Cleland, A. N., and Martinis, J. M.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

A major challenge in the field of quantum computing is the construction of scalable qubit coupling architectures. Here, we demonstrate a novel tuneable coupling circuit that allows superconducting qubits to be coupled over long distances. We show that the inter-qubit coupling strength can be arbitrarily tuned over nanosecond timescales within a sequence that mimics actual use in an algorithm. The coupler has a measured on/off ratio of 1000. The design is self-contained and physically separate from the qubits, allowing the coupler to be used as a module to connect a variety of elements such as qubits, resonators, amplifiers, and readout circuitry over long distances. Such design flexibility is likely to be essential for a scalable quantum computer., Comment: 9 manuscript pages, 4 manuscript figures, 3 supplementary information pages, 4 supplementary figures

Published

2010

7. Generation of Three-Qubit Entangled States using Superconducting Phase Qubits

Author

Neeley, M., Bialczak, R. C., Lenander, M., Lucero, E., Mariantoni, M., O'Connell, A. D., Sank, D., Wang, H., Weides, M., Wenner, J., Yin, Y., Yamamoto, T., Cleland, A. N., and Martinis, J. M.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Entanglement is one of the key resources required for quantum computation, so experimentally creating and measuring entangled states is of crucial importance in the various physical implementations of a quantum computer. In superconducting qubits, two-qubit entangled states have been demonstrated and used to show violations of Bell's Inequality and to implement simple quantum algorithms. Unlike the two-qubit case, however, where all maximally-entangled two-qubit states are equivalent up to local changes of basis, three qubits can be entangled in two fundamentally different ways, typified by the states $|\mathrm{GHZ}> = (|000> + |111>)/\sqrt{2}$ and $|\mathrm{W}> = (|001> + |010> + |100>)/\sqrt{3}$. Here we demonstrate the operation of three coupled superconducting phase qubits and use them to create and measure $|\mathrm{GHZ}>$ and $|\mathrm{W}>$ states. The states are fully characterized using quantum state tomography and are shown to satisfy entanglement witnesses, confirming that they are indeed examples of three-qubit entanglement and are not separable into mixtures of two-qubit entanglement., Comment: 9 pages, 5 figures. Version 2: added supplementary information and fixed image distortion in Figure 2.

Published

2010

8. Microwave Dielectric Loss at Single Photon Energies and milliKelvin Temperatures

Author

O'Connell, Aaron D., Ansmann, M., Bialczak, R. C., Hofheinz, M., Katz, N., Lucero, Erik, McKenney, C., Neeley, M., Wang, H., Weig, E. M., Cleland, A. N., and Martinis, J. M.

Subjects

Condensed Matter - Superconductivity

Abstract

The microwave performance of amorphous dielectric materials at very low temperatures and very low excitation strengths displays significant excess loss. Here, we present the loss tangents of some common amorphous and crystalline dielectrics, measured at low temperatures (T < 100 mK) with near single-photon excitation energies, using both coplanar waveguide (CPW) and lumped LC resonators. The loss can be understood using a two-level state (TLS) defect model. A circuit analysis of the half-wavelength resonators we used is outlined, and the energy dissipation of such a resonator on a multilayered dielectric substrate is considered theoretically., Comment: 4 pages, 3 figures, submitted to Applied Physics Letters

Published

2008

9. A blueprint for demonstrating quantum supremacy with superconducting qubits

Author

Neill, C., Roushan, P., Kechedzhi, K., Boixo, S., Isakov, S. V., Smelyanskiy, V., Megrant, A., Chiaro, B., Dunsworth, A., Arya, K., Barends, R., Burkett, B., Chen, Y., Chen, Z., Fowler, A., Foxen, B., Giustina, M., Graff, R., Jeffrey, E., Huang, T., Kelly, J., Klimov, P., Lucero, E., Mutus, J., Neeley, M., Quintana, C., Sank, D., Vainsencher, A., Wenner, J., White, T. C., Neven, H., and Martinis, J. M.

Published

2018

10. Temperature dependence of coherent oscillations in Josephson phase qubits

Author

Lisenfeld, J., Lukashenko, A., Ansmann, M., Martinis, J. M., and Ustinov, A. V.

Subjects

Condensed Matter - Superconductivity

Abstract

We experimentally investigate the temperature dependence of Rabi oscillations and Ramsey fringes in superconducting phase qubits driven by microwave pulses. In a wide range of temperatures, we find that both the decay time and the amplitude of these coherent oscillations remain nearly unaffected by thermal fluctuations. The oscillations are observed well above the crossover temperature from thermally activated escape to quantum tunneling for undriven qubits. In the two-level limit, coherent qubit response rapidly vanishes as soon as the energy of thermal fluctuations kT becomes larger than the energy level spacing of the qubit. Our observations shed new light on the origin of decoherence in superconducting qubits. The experimental data suggest that, without degrading already achieved coherence times, phase qubits can be operated at temperatures much higher than those reported till now., Comment: 4 pages, 4 figures

Published

2007

11. Theory of measurement crosstalk in superconducting phase qubits

Author

Kofman, A. G., Zhang, Q., Martinis, J. M., and Korotkov, A. N.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We analyze the crosstalk error mechanism in measurement of two capacitively coupled superconducting flux-biased phase qubits. The damped oscillations of the superconducting phase after the measurement of the first qubit may significantly excite the second qubit, leading to its measurement error. The first qubit, which is highly excited after the measurement, is described classically. The second qubit is treated both classically and quantum-mechanically. The results of the analysis are used to find the upper limit for the coupling capacitance (thus limiting the frequency of two-qubit operations) for a given tolerable value of the measurement error probability., Comment: 16 pages, Revtex; minor changes in the text and figures

Published

2006

12. Superconducting Qubits: A Short Review

Author

Devoret, M. H., Wallraff, A., and Martinis, J. M.

Subjects

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

Abstract

Superconducting qubits are solid state electrical circuits fabricated using techniques borrowed from conventional integrated circuits. They are based on the Josephson tunnel junction, the only non-dissipative, strongly non-linear circuit element available at low temperature. In contrast to microscopic entities such as spins or atoms, they tend to be well coupled to other circuits, which make them appealling from the point of view of readout and gate implementation. Very recently, new designs of superconducting qubits based on multi-junction circuits have solved the problem of isolation from unwanted extrinsic electromagnetic perturbations. We discuss in this review how qubit decoherence is affected by the intrinsic noise of the junction and what can be done to improve it., Comment: 41 pages, 17 figures, version with high resolution figures available at http://www.eng.yale.edu/rslab/Andreas/content/science/PubsPapers.html

Published

2004

13. Recent Results from the Cryogenic Dark Matter Search for Weakly Interacting Massive Particles

Author

Gaitskell, R. J., Abusaidi, R., Akerib, D. S., Barnes, P. D., Jr., Bauer, D. A., Bolozdynya, A., Brink, P. L., Bunker, R., Cabrera, B., Caldwell, D. O., Castle, J. P., Clarke, R. M., Colling, P., Crisler, M. B., Cummings, A., Da Silva, A., Davies, A. K., Dixon, R., Dougherty, B. L., Driscoll, D., Eichblatt, S., Emes, J., Golwala, S. R., Hale, D., Haller, E. E., Hellmig, J., Huber, M. E., Irwin, K. D., Jochum, J., Lipschultz, F. P., Lu, A., Mandic, V., Martinis, J. M., Nam, S. W., Nelson, H., Neuhauser, B., Penn, M. J., Perera, T. A., Isaac, M. C. Perillo, Pritychenko, B., Ross, R. R., Saab, T., Sadoulet, B., Schnee, R. W., Seitz, D. N., Shestople, P., Shutt, T., Smith, A., Smith, G. W., Sonnenschein, A. H., Spadafora, A. L., Stockwell, W., Taylor, J. D., White, S., Yellin, S., Young, B. A., and Cline, David B., editor

Published

2001

14. Results of the Cryogenic Dark Matter Search

Author

Schnee, R. W., Abusaidi, R., Akerib, D. S., Barnes, P. D., Jr., Bauer, D. A., Bolozdynya, A., Brink, P. L., Bunker, R., Cabrera, B., Caldwell, D. O., Castle, J. P., Clarke, R. M., Colling, P., Crisler, M. B., Cummings, A., Da Silva, A., Davies, A. K., Dixon, R., Dougherty, B. L., Driscoll, D., Eichblatt, S., Emes, J., Gaitskell, R. J., Golwala, S. R., Hale, D., Haller, E. E., Hellmig, J., Huber, M. E., Irwin, K. D., Jochum, J., Lipschultz, F. P., Lu, A., Mandic, V., Martinis, J. M., Nam, S. W., Nelson, H., Neuhauser, B., Penn, M. J., Perera, T. A., Isaac, M. C. Perillo, Pritychenko, B., Ross, R. R., Saab, T., Sadoulet, B., Seitz, D. N., Shestople, P., Shutt, T., Smith, A., Smith, G. W., Sonnenschein, A. H., Spadafora, A. L., Stockwell, W., Taylor, J. D., White, S., Yellin, S., Young, B. A., and Klapdor-Kleingrothaus, H. V., editor

Published

2001

15. Quantum logic gates in superconducting qubits

Author

Martinis, J. M., primary

Published

2014

16. Multiplexed Readout of Superconducting Bolometers

Author

Benford, D. J., Allen, C. A., Chervenak, J. A., Freund, M. M., Kutyrev, A. S., Moseley, S. H., Shafer, R. A., Staguhn, J. G., Grossman, E. N., Hilton, G. C., Irwin, K. D., Martinis, J. M., Nam, S. W., and Reintsema, O. D.

Published

2000

17. The Approaching Revolution in X-Ray Microanalysis: The Microcalorimeter Energy Dispersive Spectrometer

Author

Newbury, D. E., Wollman, D. A., Hilton, G. C., Irwin, K. D., Bergren, N. F., Rudman, D. A., and Martinis, J. M.

Published

2000

18. Microcalorimeter energy-dispersive spectrometry using a low voltage scanning electron microscope

Author

WOLLMAN, D. A., NAM, S. W., HILTON, G. C., IRWIN, K. D., BERGREN, N. F., RUDMAN, D. A., MARTINIS, J. M., and NEWBURY, D. E.

Published

2000

19. High-resolution, energy-dispersive microcalorimeter spectrometer for X-ray microanalysis

Author

WOLLMAN, D. A., IRWIN, K. D., HILTON, G. C., DULCIE, L. L., NEWBURY, D. E., and MARTINIS, J. M.

Published

1997

20. Scalable Quantum Simulation of Molecular Energies

Author

O’Malley, P. J. J., primary, Babbush, R., additional, Kivlichan, I. D., additional, Romero, J., additional, McClean, J. R., additional, Barends, R., additional, Kelly, J., additional, Roushan, P., additional, Tranter, A., additional, Ding, N., additional, Campbell, B., additional, Chen, Y., additional, Chen, Z., additional, Chiaro, B., additional, Dunsworth, A., additional, Fowler, A. G., additional, Jeffrey, E., additional, Lucero, E., additional, Megrant, A., additional, Mutus, J. Y., additional, Neeley, M., additional, Neill, C., additional, Quintana, C., additional, Sank, D., additional, Vainsencher, A., additional, Wenner, J., additional, White, T. C., additional, Coveney, P. V., additional, Love, P. J., additional, Neven, H., additional, Aspuru-Guzik, A., additional, and Martinis, J. M., additional

Published

2016

21. Ergodic dynamics and thermalization in an isolated quantum system

Author

Neill, C., primary, Roushan, P., additional, Fang, M., additional, Chen, Y., additional, Kolodrubetz, M., additional, Chen, Z., additional, Megrant, A., additional, Barends, R., additional, Campbell, B., additional, Chiaro, B., additional, Dunsworth, A., additional, Jeffrey, E., additional, Kelly, J., additional, Mutus, J., additional, O’Malley, P. J. J., additional, Quintana, C., additional, Sank, D., additional, Vainsencher, A., additional, Wenner, J., additional, White, T. C., additional, Polkovnikov, A., additional, and Martinis, J. M., additional

Published

2016

22. Demonstration of gate control of spin splitting in a high-mobility InAs/AlSb two-dimensional electron gas

Author

Shojaei, B., primary, O'Malley, P. J. J., additional, Shabani, J., additional, Roushan, P., additional, Schultz, B. D., additional, Lutchyn, R. M., additional, Nayak, C., additional, Martinis, J. M., additional, and Palmstrøm, C. J., additional

Published

2016

23. Flicker (1/f) noise in tunnel junction dc SQUIDS

Author

Koch, Roger H., Clarke, John, Goubau, W. M., Martinis, J. M., Pegrum, C. M., and van Harlingen, D. J.

Published

1983

24. Observation of topological transitions in interacting quantum circuits

Author

Roushan, P., primary, Neill, C., additional, Chen, Yu, additional, Kolodrubetz, M., additional, Quintana, C., additional, Leung, N., additional, Fang, M., additional, Barends, R., additional, Campbell, B., additional, Chen, Z., additional, Chiaro, B., additional, Dunsworth, A., additional, Jeffrey, E., additional, Kelly, J., additional, Megrant, A., additional, Mutus, J., additional, O’Malley, P. J. J., additional, Sank, D., additional, Vainsencher, A., additional, Wenner, J., additional, White, T., additional, Polkovnikov, A., additional, Cleland, A. N., additional, and Martinis, J. M., additional

Published

2014

25. Reducing the impact of intrinsic dissipation in a superconducting circuit by quantum error detection

Author

Zhong, Y. P., primary, Wang, Z. L., additional, Martinis, J. M., additional, Cleland, A. N., additional, Korotkov, A. N., additional, and Wang, H., additional

Published

2014

26. Application of microcalorimeter energy measurement to biopolymer mass spectrometry

Author

Rabin, M. W., Hilton, G. C., and Martinis, J. M.

Abstract

n/a

Published

2001

27. Transition edge sensor array development

Author

Deiker, S., Chervenak, J., Hilton, G. C., Irwin, K. D., Martinis, J. M., Nam, S., and Wollman, D. A.

Abstract

n/a

Published

2001

28. Superconducting transition-edge microcalorimeters for X-ray microanalysis

Author

Hilton, G. C., Wollman, D. A., Irwin, K. D., Dulcie, L. L., Bergren, N. F., and Martinis, J. M.

Abstract

n/a

Published

1999

29. A seven-junction electron pump: Design, fabrication, and operation

Author

Keller, M. W., Martinis, J. M., Steinbach, A. H., and Zimmerman, N. M.

Abstract

n/a

Published

1997

30. Fast Tunable Coupler for Superconducting Qubits

Author

Bialczak, R. C., primary, Ansmann, M., additional, Hofheinz, M., additional, Lenander, M., additional, Lucero, E., additional, Neeley, M., additional, O’Connell, A. D., additional, Sank, D., additional, Wang, H., additional, Weides, M., additional, Wenner, J., additional, Yamamoto, T., additional, Cleland, A. N., additional, and Martinis, J. M., additional

Published

2011

31. Quantum process tomography of a universal entangling gate implemented with Josephson phase qubits

Author

Bialczak, R. C., primary, Ansmann, M., additional, Hofheinz, M., additional, Lucero, E., additional, Neeley, M., additional, O’Connell, A. D., additional, Sank, D., additional, Wang, H., additional, Wenner, J., additional, Steffen, M., additional, Cleland, A. N., additional, and Martinis, J. M., additional

Published

2010

32. Microwave dielectric loss at single photon energies and millikelvin temperatures

Author

O’Connell, Aaron D., primary, Ansmann, M., additional, Bialczak, R. C., additional, Hofheinz, M., additional, Katz, N., additional, Lucero, Erik, additional, McKenney, C., additional, Neeley, M., additional, Wang, H., additional, Weig, E. M., additional, Cleland, A. N., additional, and Martinis, J. M., additional

Published

2008

33. Temperature Dependence of Coherent Oscillations in Josephson Phase Qubits

Author

Lisenfeld, J., primary, Lukashenko, A., additional, Ansmann, M., additional, Martinis, J. M., additional, and Ustinov, A. V., additional

Published

2007

34. Latest Results From The CDMS-II Cold Dark Matter Search

Author

Brink, P. L., primary, Akerib, D. S., additional, Armel-Funkhouser, M. S., additional, Attisha, M. J., additional, Bailey, C. N., additional, Baudis, L., additional, Bauer, D. A., additional, Bunker, R., additional, Cabrera, B., additional, Caldwell, D. O., additional, Chang, C. L., additional, Crisler, M. B., additional, Cushman, P., additional, Daal, M., additional, Dixon, R., additional, Dragowsky, M. R., additional, Driscoll, D. D., additional, Duong, L., additional, Ferril, R., additional, Filippini, J., additional, Gaitskell, R. J., additional, Hennings-Yeomans, R., additional, Holmgren, D., additional, Huber, M. E., additional, Kamat, S., additional, Lu, A., additional, Mahapatra, R., additional, Mandic, V., additional, Martinis, J. M., additional, Meunier, P., additional, Mirabolfathi, N., additional, Nelson, H., additional, Nelson, R., additional, Ogburn, R. W., additional, Perera, T. A., additional, Ramberg, E., additional, Reisetter, A., additional, Ross, R. R., additional, Saab, T., additional, Sadoulet, B., additional, Sander, J., additional, Savage, C., additional, Schnee, R. W., additional, Seitz, D. N., additional, Serfass, B., additional, Sundqvist, K. M., additional, Thompson, J.-P. F., additional, Wang, G., additional, Yellin, S., additional, and Young, B. A., additional

Published

2006

35. Exclusion limits on the WIMP-nucleon cross section from the first run of the Cryogenic Dark Matter Search in the Soudan Underground Laboratory

Author

Akerib, D. S., primary, Armel-Funkhouser, M. S., additional, Attisha, M. J., additional, Bailey, C. N., additional, Baudis, L., additional, Bauer, D. A., additional, Brink, P. L., additional, Bunker, R., additional, Cabrera, B., additional, Caldwell, D. O., additional, Chang, C. L., additional, Crisler, M. B., additional, Cushman, P., additional, Daal, M., additional, Dixon, R., additional, Dragowsky, M. R., additional, Driscoll, D. D., additional, Duong, L., additional, Ferril, R., additional, Filippini, J., additional, Gaitskell, R. J., additional, Hennings-Yeomans, R., additional, Holmgren, D., additional, Huber, M. E., additional, Kamat, S., additional, Lu, A., additional, Mahapatra, R., additional, Mandic, V., additional, Martinis, J. M., additional, Meunier, P., additional, Mirabolfathi, N., additional, Nelson, H., additional, Nelson, R., additional, Ogburn, R. W., additional, Perera, T. A., additional, Issac, M. C. Perillo, additional, Ramberg, E., additional, Rau, W., additional, Reisetter, A., additional, Ross, R. R., additional, Saab, T., additional, Sadoulet, B., additional, Sander, J., additional, Savage, C., additional, Schnee, R. W., additional, Seitz, D. N., additional, Serfass, B., additional, Sundqvist, K. M., additional, Thompson, J-P. F., additional, Wang, G., additional, Yellin, S., additional, and Young, B. A., additional

Published

2005

36. Low-leakage superconducting tunnel junctions with a single-crystal Al2O3barrier

Author

Oh, S, primary, Cicak, K, additional, McDermott, R, additional, Cooper, K B, additional, Osborn, K D, additional, Simmonds, R W, additional, Steffen, M, additional, Martinis, J M, additional, and Pappas, D P, additional

Published

2005

37. New results from the Cryogenic Dark Matter Search experiment

Author

Akerib, D. S., primary, Alvaro-Dean, J., additional, Armel, M. S., additional, Attisha, M. J., additional, Baudis, L., additional, Bauer, D. A., additional, Bolozdynya, A. I., additional, Brink, P. L., additional, Bunker, R., additional, Cabrera, B., additional, Caldwell, D. O., additional, Castle, J. P., additional, Chang, C. L., additional, Clarke, R. M., additional, Crisler, M. B., additional, Cushman, P., additional, Davies, A. K., additional, Dixon, R., additional, Driscoll, D. D., additional, Duong, L., additional, Emes, J., additional, Ferril, R., additional, Gaitskell, R. J., additional, Golwala, S. R., additional, Haldeman, M., additional, Hellmig, J., additional, Hennessey, M., additional, Holmgren, D., additional, Huber, M. E., additional, Kamat, S., additional, Kurylowicz, M., additional, Lu, A., additional, Mahapatra, R., additional, Mandic, V., additional, Martinis, J. M., additional, Meunier, P., additional, Mirabolfathi, N., additional, Nam, S. W., additional, Nelson, H., additional, Nelson, R., additional, Ogburn, R. W., additional, Perales, J., additional, Perera, T. A., additional, Perillo Isaac, M. C., additional, Rau, W., additional, Reisetter, A., additional, Ross, R. R., additional, Saab, T., additional, Sadoulet, B., additional, Sander, J., additional, Savage, C., additional, Schnee, R. W., additional, Seitz, D. N., additional, Shutt, T. A., additional, Smith, G., additional, Spadafora, A. L., additional, Thompson, J.-P. F., additional, Tomada, A., additional, Wang, G., additional, Yellin, S., additional, and Young, B. A., additional

Published

2003

38. WIMP EXCLUSION RESULTS FROM THE CDMS EXPERIMENT

Author

BRINK, P. L., primary, BAUDIS, L., additional, CABRERA, B., additional, CASTLE, J. P., additional, CHANG, C., additional, SAAB, T., additional, GAITSKELL, R. J., additional, THOMSON, J. P., additional, AKERIB, D. S., additional, DRISCOLL, D., additional, KAMAT, S., additional, PERERA, T. A., additional, SCHNEE, R. W., additional, WANG, G., additional, CRISLER, M. B., additional, DIXON, R., additional, HOLMGREN, D., additional, EMES, J. H., additional, ROSS, R. R., additional, SMITH, A., additional, SMITH, G. W., additional, MARTINIS, J. M., additional, SHUTT, T., additional, YOUNG, B. A., additional, ARMEL, M. S., additional, MANDIC, V., additional, MEUNIER, P., additional, RAU, W., additional, SADOULET, B., additional, SEITZ, D. N., additional, BAUER, D. A., additional, BUNKER, R., additional, CALDWELL, D. O., additional, LU, A., additional, MAHAPATRA, R., additional, MALONEY, C., additional, NELSON, H., additional, SANDER, J., additional, YELLIN, S., additional, and HUBER, M. E., additional

Published

2003

39. PERFORMANCE AND BACKGROUND MEASUREMENTS OF THE CDMS II TOWER I DETECTORS AT THE STANFORD UNDERGROUND FACILITY

Author

SAAB, T., primary, BRINK, P. L., additional, BAUDIS, L., additional, CABRERA, B., additional, CASTLE, J. P., additional, CHANG, C., additional, GAITSKELL, R. J., additional, THOMSON, J. P., additional, AKERIB, D. S., additional, DRISCOLL, D., additional, KAMAT, S., additional, PERERA, T. A., additional, SCHNEE, R. W., additional, WANG, G., additional, CRISLER, M. B., additional, DIXON, R., additional, HOLMGREN, D., additional, EMES, J. H., additional, ROSS, R. R., additional, SMITH, A., additional, SMITH, G. W., additional, MARTINIS, J. M., additional, SHUTT, T., additional, YOUNG, B. A., additional, ARMEL, M. S., additional, MANDIC, V., additional, MEUNIER, P., additional, RAU, W., additional, SADOULET, B., additional, SEITZ, D. N., additional, BAUER, D. A., additional, BUNKER, R., additional, CALDWELL, D. O., additional, LU, A., additional, MAHAPATRA, R., additional, MALONEY, C., additional, NELSON, H., additional, SANDER, J., additional, YELLIN, S., additional, and HUBER, M. E., additional

Published

2003

40. Exclusion limits on the WIMP-nucleon cross section from the Cryogenic Dark Matter Search

Author

Abrams, D., primary, Akerib, D. S., additional, Armel-Funkhouser, M. S., additional, Baudis, L., additional, Bauer, D. A., additional, Bolozdynya, A., additional, Brink, P. L., additional, Bunker, R., additional, Cabrera, B., additional, Caldwell, D. O., additional, Castle, J. P., additional, Chang, C. L., additional, Clarke, R. M., additional, Crisler, M. B., additional, Dixon, R., additional, Driscoll, D., additional, Eichblatt, S., additional, Gaitskell, R. J., additional, Golwala, S. R., additional, Haller, E. E., additional, Hellmig, J., additional, Holmgren, D., additional, Huber, M. E., additional, Kamat, S., additional, Lu, A., additional, Mandic, V., additional, Martinis, J. M., additional, Meunier, P., additional, Nam, S. W., additional, Nelson, H., additional, Perera, T. A., additional, Perillo Isaac, M. C., additional, Rau, W., additional, Ross, R. R., additional, Saab, T., additional, Sadoulet, B., additional, Sander, J., additional, Schnee, R. W., additional, Shutt, T., additional, Smith, A., additional, Sonnenschein, A. H., additional, Spadafora, A. L., additional, Wang, G., additional, Yellin, S., additional, and Young, B. A., additional

Published

2002

41. Position dependence in the CDMS II ZIP detectors

Author

Mandic, V., primary, Rau, W., additional, Akerib, D., additional, Brink, P., additional, Cabrera, B., additional, Castle, J. P., additional, Chang, C., additional, Crisler, M. B., additional, Driscoll, D., additional, Emes, J., additional, Gaitskell, R. J., additional, Hellmig, J., additional, Huber, M. E., additional, Kamat, S., additional, Martinis, J. M., additional, Meunier, P., additional, Perera, T. A., additional, Perillo-Issac, M., additional, Saab, T., additional, Sadoulet, B., additional, Schnee, R., additional, Seitz, D., additional, Wang, G., additional, and Young, B., additional

Published

2002

42. TES spectrophotometers for near IR/optical/UV

Author

Cabrera, B., primary, Martinis, J. M., additional, Miller, A. J., additional, Nam, S. W., additional, and Romani, R., additional

Published

2002

43. Electron Probe Microanalysiswith Cryogenic Detectors.

Author

Ascheron, Claus E., Kölsch, Hans J., Skolaut, Werner, Enss, Christian, Newbury, D. E., Irwin, K. D., Hilton, G. C., Wollman, D. A., Small, J. A., and Martinis, J. M.

Abstract

Electron probe X-ray microanalysis (EPMA) is based upon the use of a focused, high current density electron beam, 5 to 30 keV in energy, to excite characteristic X-rays from a picogram mass of a solid target. X-ray spectral measurements are currently performed with the broad bandpass semiconductor energy dispersive X-ray spectrometry (Si-EDS) and/or the high resolution crystal diffraction wavelength dispersive spectrometry (WDS). The strengths and weaknesses of WDS and EDS are mutually complementary. Nevertheless, existing EPMA/WDS/EDS technology has limitations which become extreme when applied to the newly emerging field of low voltage microanalysis, where the beam energy is less than 5 keV. The microcalorimeter EDS provides both high spectral resolution and energy dispersive operational character, two key features of the ideal spectrometer for EPMA. The NIST prototype microcalorimeter EDS achieves impressive performance for EPMA in terms of resolving key elemental interferences, detecting chemical state induced peak shifts, high sensitivity, and applicability to low voltage microanalysis. Further technical developments should extend these capabilities, and commercialization will bring the advantages of the microcalorimeter EDS to critical applications. [ABSTRACT FROM AUTHOR]

Published

2005

44. A Ratiometric Method for Johnson Noise Thermometry Using a Quantized Voltage Noise Source.

Author

Nam, S. W., Benz, S. P., Martinis, J. M., Dresselhaus, P., Tew, W. L., and White, D. R.

Subjects

TEMPERATURE measurements, NOISE generators (Electronics), DIGITAL electronics, THERMODYNAMICS

Abstract

Johnson Noise Thermometry (JNT) involves the measurement of the statistical variance of a fluctuating voltage across a resistor in thermal equilibrium. Modern digital techniques make it now possible to perform many functions required for JNT in highly efficient and predictable ways. We describe the operational characteristics of a prototype JNT system which uses digital signal processing for filtering, real-time spectral cross-correlation for noise power measurement, and a digitally synthesized Quantized Voltage Noise Source (QVNS) as an AC voltage reference. The QVNS emulates noise with a constant spectral density that is stable, programmable, and calculable in terms of known parameters using digital synthesis techniques. Changes in analog gain are accounted for by alternating the inputs between the Johnson noise sensor and the QVNS. The Johnson noise power at a known temperature is first balanced with a synthesized noise power from the QVNS. The process is then repeated by balancing the noise power from the same resistor at an unknown temperature. When the two noise power ratios are combined, a thermodynamic temperature is derived using the ratio of the two QVNS spectral densities. We present preliminary results where the ratio between the gallium triple point and the water triple point is used to demonstrate the accuracy of the measurement system with a standard uncertainty of 0.04 %. © 2003 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2003

45. TES detector noise limited readout using SQUID multiplexers.

Author

Staguhn, J. G., Allen, C. A., Benford, D. J., Chervenak, J. A., Freund, M. M., Khan, S. A., Kutyrev, A. S., Moseley, S. H., Shafer, R. A., Deiker, S., Grossman, E. N., Hilton, G. C., Irwin, K. D., Martinis, J. M., Nam, S. W., Rudman, D. A., and Wollman, D. A.

Subjects

DETECTORS, SUPERCONDUCTING quantum interference devices, MULTIPLEXING equipment

Abstract

The availability of superconducting Transition Edge Sensors (TES) with large numbers of individual detector pixels requires multiplexers for efficient readout. The use of multiplexers reduces the number of wires needed between the cryogenic electronics and the room temperature electronics and cuts the number of required cryogenic amplifiers. We are using an 8 channel SQUID multiplexer to read out one-dimensional TES arrays which are used for submillimeter astronomical observations, We present results from test measurements which show that the low noise level of the SQUID multiplexers allows accurate measurements of the TES Johnson noise, and that in operation, the readout noise is dominated by the detector noise. Multiplexers for large number of channels require a large bandwidth for the multiplexed readout signal, We discuss the resulting implications for the noise performance of these multiplexers which will be used for the readout of two dimensional TES arrays in next generation instruments. [ABSTRACT FROM AUTHOR]

Published

2002

46. Position dependence in the CDMS II ZIP detectors.

Author

Mandic, V., Rau, W., Akerib, D., Brink, P., Cabrera, B., Castle, J. P., Chang, C., Crisler, M. B., Driscoll, D., Emes, J., Gaitskell, R. J., Hellmig, J., Huber, M. E., Kamat, S., Martinis, J. M., Meunier, P., Perera, T. A., Perillo-Issac, M., Saab, T., and Sadoulet, B.

Subjects

DETECTORS, DARK matter, IONIZATION (Atomic physics)

Abstract

The Ge and Si detectors developed by the Cryogenic Dark Matter Search (CDMS) II experiment rely on the simultaneous detection of athermal phonons and ionization produced by interactions in the crystal. The athermal phonons provide both the total energy deposited in an interaction and the information about the position of the interaction. We describe extracting this information from the pulse shapes in the four phonon sensors. We present the result of measurements made on a Si detector from the first CDMS II production batch. We also investigate ways of using the event position information to extract further information about the phonon signal. © 2002 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2002

47. Exclusion Limits on the WIMP-Nucleon Cross Section from the Cryogenic Dark Matter Search

Author

Abusaidi, R., primary, Akerib, D. S., additional, Barnes, P. D., additional, Bauer, D. A., additional, Bolozdynya, A., additional, Brink, P. L., additional, Bunker, R., additional, Cabrera, B., additional, Caldwell, D. O., additional, Castle, J. P., additional, Clarke, R. M., additional, Colling, P., additional, Crisler, M. B., additional, Cummings, A., additional, Da Silva, A., additional, Davies, A. K., additional, Dixon, R., additional, Dougherty, B. L., additional, Driscoll, D., additional, Eichblatt, S., additional, Emes, J., additional, Gaitskell, R. J., additional, Golwala, S. R., additional, Hale, D., additional, Haller, E. E., additional, Hellmig, J., additional, Huber, M. E., additional, Irwin, K. D., additional, Jochum, J., additional, Lipschultz, F. P., additional, Lu, A., additional, Mandic, V., additional, Martinis, J. M., additional, Nam, S. W., additional, Nelson, H., additional, Neuhauser, B., additional, Penn, M. J., additional, Perera, T. A., additional, Perillo Isaac, M. C., additional, Pritychenko, B., additional, Ross, R. R., additional, Saab, T., additional, Sadoulet, B., additional, Schnee, R. W., additional, Seitz, D. N., additional, Shestople, P., additional, Shutt, T., additional, Smith, A., additional, Smith, G. W., additional, Sonnenschein, A. H., additional, Spadafora, A. L., additional, Stockwell, W., additional, Taylor, J. D., additional, White, S., additional, Yellin, S., additional, and Young, B. A., additional

Published

2000

48. EDS x-ray microcalorimeters with 13 eV energy resolution

Author

Wollman, D. A., primary, Hilton, G. C., additional, Irwin, K. D., additional, and Martinis, J. M., additional

Published

1996

49. Observation of the Temporal Decoupling Effect on the Macroscopic Quantum Tunneling of a Josephson Junction.

Author

Esteve, D, Martinis, J M, Urbina, C, Turlot, E, Devoret, M H, Grabert, H, and Linkwitz, S

Published

1989

50. Application of ion-impact energy measurement to electrospray ionization mass spectrometry of proteins and protein mixtures

Author

Rabin, M. W., Hilton, G. C., and Martinis, J. M.

Published

2001