75 research outputs found
Gradient Field Transduction of Nanomechanical Resonators
Das Forschungsgebiet nanomechanischer Systeme betrachtet die Bewegung von Strukturen, deren Länge in mindestens einer Richtung deutlich unter einem Mikrometer liegt. Meist werden dabei Auslenkungen untersucht, die in der Nähe einer mechanischen Resonanz angetrieben werden. Das wissenschaftliche Interesse an solchen Strukturen hat mehrere Gründe: aufgrund der kleinen Masse und oftmals geringen Dämpfung (d.h. hohe Güte) reagieren solche nanomechanischen Systeme sehr empfindlich auf Änderungen ihrer Umgebung oder ihrer eigenen Eigenschaften wie etwa ihrer Masse. Die große Vielfalt der nanomechanischen Systeme erlaubt die Kopplung an verschiedenste physikalische Größen wie (Umgebungs-)Druck, Licht, elektrische/magnitische Felder. Dies ermöglicht, die Wechselwirkung selbst zu untersuchen oder entsprechende Änderungen empfindlich zu detektieren.
Im Rahmen der vorliegenden Arbeit wurde die Resonator Bewegung von doppelseitig eingespannten Balken untersucht; diese wurden mit konventioneller Mikrofabrikation aus verspanntem Silizium-Nitrid gefertigt. Die große Zugspannung in den Balken führt zu einer hohen mechanischen Stabilität und ebenso zu hohen mechanischen Güten.
Ein Teil der Arbeit befasste sich mit der Entwicklung neuer Detektions- und Antriebsmechanismen. Unter Ausnutzung der Polarisierbarkeit des Resonators wurde ein lokaler Antrieb realisiert, der sich durch besondere Einfachkeit auszeichnet. Ebenso wurden Fortschritte in der optischen Detektion erzielt. Ein Photodetektor konnte innerhalb einer optischen Wellenlänge Abstand zum Resonator plaziert werden; dies ermöglicht die lokale Detektion seiner Bewegung.
Hochempfindliche Messungen nutzen oft optische Resonanzen; bisherige Umsetzungen basieren auf Reflexionen und sind daher auf Objekte beschränkt, die größer als die verwendete Wellenlänge sind. In einer Zusammenarbeit mit Prof. Kippenberge konnte diese Beschränkung umgangen werden, indem geführtes Licht in einem Mikro-Toroiden verwendet wurde.
Weiter wurde in der Arbeit die resonante Bewegung selbst untersucht. Im Bereich hoher Amplituden zeigt die rĂĽcktreibende Kraft nichtlineares Verhalten. Das sich dadurch ergebende bistabile Verhalten des Resonators wurde mit Hilfe von kurzen, resonanten Pulsen untersucht; schnelles Schalten wurde erreicht.
Die mechanische Dämpfung der Siliziumnitrid Resonatoren wurde untersucht. Die hohen Güten von Systemen unter Zugspannung konnte erklärt werden durch die sich ergebende erhöhte gespeicherte elastische Energie; im Gegensatz zu einem veränderten Dämpfungsverhalten
Sensing distant nuclear spins with a single electron spin
We experimentally demonstrate the use of a single electronic spin to measure
the quantum dynamics of distant individual nuclear spins from within a
surrounding spin bath. Our technique exploits coherent control of the electron
spin, allowing us to isolate and monitor nuclear spins weakly coupled to the
electron spin. Specifically, we detect the evolution of distant individual
carbon-13 nuclear spins coupled to single nitrogen vacancy centers in a diamond
lattice with hyperfine couplings down to a factor of 8 below the electronic
spin bare dephasing rate. Potential applications to nanoscale magnetic
resonance imaging and quantum information processing are discussed.Comment: Corrected typos, updated references. 5 pages, 4 figures, and
supplemental materia
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Sensing Distant Nuclear Spins with a Single Electron Spin
We experimentally demonstrate the use of a single electronic spin to measure the quantum dynamics of distant individual nuclear spins from within a surrounding spin bath. Our technique exploits coherent control of the electron spin, allowing us to isolate and monitor nuclear spins weakly coupled to the electron spin. Specifically, we detect the evolution of distant individual C13 nuclear spins coupled to single nitrogen vacancy centers in a diamond lattice with hyperfine couplings down to a factor of 8 below the electronic spin bare dephasing rate. Potential applications to nanoscale magnetic resonance imaging and quantum information processing are discussed.Physic
Measuring mechanical motion with a single spin
We study theoretically the measurement of a mechanical oscillator using a
single two level system as a detector. In a recent experiment, we used a single
electronic spin associated with a nitrogen vacancy center in diamond to probe
the thermal motion of a magnetized cantilever at room temperature {Kolkowitz et
al., Science 335, 1603 (2012)}. Here, we present a detailed analysis of the
sensitivity limits of this technique, as well as the possibility to measure the
zero point motion of the oscillator. Further, we discuss the issue of
measurement backaction in sequential measurements and find that although
backaction heating can occur, it does not prohibit the detection of zero point
motion. Throughout the paper we focus on the experimental implementation of a
nitrogen vacancy center coupled to a magnetic cantilever; however, our results
are applicable to a wide class of spin-oscillator systems. Implications for
preparation of nonclassical states of a mechanical oscillator are also
discussed.Comment: 17 pages, 6 figure
Nonlinear Switching Dynamics in a Nanomechanical Resonator
The oscillatory response of nonlinear systems exhibits characteristic
phenomena such as multistability, discontinuous jumps and hysteresis. These can
be utilized in applications leading, e.g., to precise frequency measurement,
mixing, memory elements, reduced noise characteristics in an oscillator or
signal amplification. Approaching the quantum regime, concepts have been
proposed that enable low backaction measurement techniques or facilitate the
visualisation of quantum mechanical effects. Here we study the dynamic response
of nanoelectromechanical resonators in the nonlinear regime aiming at a more
detailed understanding and an exploitation for switching applications. Whereas
most previous investigations concentrated on dynamic phenomena arising at the
onset of bistability, we present experiments that yield insight into the
non-adiabatic evolution of the system while subjected to strong driving pulses
and the subsequent relaxation. Modeling the behaviour quantitatively with a
Duffing oscillator, we can control switching between its two stable states at
high speeds, exceeding recently demonstrated results by 10,000
Measuring nanomechanical motion with an imprecision far below the standard quantum limit
We demonstrate a transducer of nanomechanical motion based on cavity enhanced
optical near-fields capable of achieving a shot-noise limited imprecision more
than 10 dB below the standard quantum limit (SQL). Residual background due to
fundamental thermodynamical frequency fluctuations allows a total imprecision 3
dB below the SQL at room temperature (corresponding to 600 am/Hz^(1/2) in
absolute units) and is known to reduce to negligible values for moderate
cryogenic temperatures. The transducer operates deeply in the quantum
backaction dominated regime, prerequisite for exploring quantum backaction,
measurement-induced squeezing and accessing sub-SQL sensitivity using
backaction evading techniques
Selective high frequency mechanical actuation driven by the VO2 electronic instability
Micro- and nano-electromechanical resonators are a fundamental building block
of modern technology, used in environmental monitoring, robotics, medical tools
as well as fundamental science. These devices rely on dedicated electronics to
generate their driving signal, resulting in an increased complexity and size.
Here, we present a new paradigm to achieve high-frequency mechanical actuation
based on the metal-insulator transition of VO, where the steep
variation of its electronic properties enables to realize high-frequency
electrical oscillations. The dual nature of this phase change, which is both
electronic and structural, turns the electrical oscillations into an intrinsic
actuation mechanism, powered by a small DC voltage and capable to selectively
excite the different mechanical modes of a microstructure. Our results pave the
way towards the realization of micro- and nano-electro-mechanical systems with
autonomous actuation from integrated DC power sources such as solar cells or
micro-batteries.Comment: Main text: 6 pages, 4 figures Supplemental Material: 16 pages, 7
section
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Efficient Readout of a Single Spin State in Diamond via Spin-to-Charge Conversion
Efficient readout of individual electronic spins associated with atomlike impurities in the solid state is essential for applications in quantum information processing and quantum metrology. We demonstrate a new method for efficient spin readout of nitrogen-vacancy (NV) centers in diamond. The method is based on conversion of the electronic spin state of the NV to a charge-state distribution, followed by single-shot readout of the charge state. Conversion is achieved through a spin-dependent photoionization process in diamond at room temperature. Using NVs in nanofabricated diamond beams, we demonstrate that the resulting spin readout noise is within a factor of 3 of the spin projection noise level. Applications of this technique for nanoscale magnetic sensing are discussed.Physic
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