Invited speaker: Peter Knott
Affiliation: Fraunhofer-Institut für Hochfrequenzphysik und Radartechnik
Title: RADAR Systems – Technology and Challenges
Time and room: 13:30 h
, lecture hall IAP
During the last decade, numerous developments have not only improved and matured technology and signal processing methods of RADAR systems, but also paved the road for many new applications besides its traditional domains in defence and space. The rapid progress in performance of highly integrated electronic components (digital, analogue or mixed-signal) has enabled several trends such as miniaturisation and cost reduction of sensor devices, a migration to higher frequencies in the millimetre and Terahertz domain, or real-time execution of mathematically complex signal and array processing methods. On the other hand, the electromagnetic spectrum is a scarce and strongly controlled resource that is proving to be increasingly valuable. Radar devices must be able to handle more signal bandwidth with greater receiver sensitivity and are competing with an increasing number of other systems for communication, navigation, or wireless connectivity. In this environment, it is necessary to understand the different requirements and find strategies of a co-existence without performance degradation.
The presentation gives an overview of recent developments at Fraunhofer FHR and application examples such as airborne and ground based surveillance, Digital Beam Forming AESA systems, or Cognitive Radar Architecture.
Invited speaker: Jan Klaers
Affiliation: ETH Zürich
Title: A Minimalist Nano-mechanical Engine Beyond the Carnot Limit
Time and room: 17:30 h
, lecture hall IAPHeat engines, as employed in cars, ships and airplanes, are everyday examples showing that heat can produce directed motion. The efficient conversion of thermal energy to mechanical work by an engine is, however, an ongoing technological challenge. Since the pioneering work of Carnot, it is known that the efficiency of engines is bounded by a fundamental upper limit ‑ the Carnot limit. Nowadays, micro- and nanotechnological methods allow to test thermodynamics far away from the thermodynamic limit. Highly miniaturized forms of heat engines have been experimentally realized, where the working medium is represented by a single particle instead of 10^23 particles as in the macroscopic world. Theoretical studies suggest that the efficiency of such engines may overcome the standard Carnot limit by employing stationary, non-equilibrium reservoirs that are characterized by a temperature as well as further parameters, for example, quantum coherent, quantum correlated and squeezed thermal reservoirs. In a proof-of-principle experiment, we demonstrate that the efficiency of a minimalist nano-mechanical heat engine coupled to squeezed thermal noise is not bounded by the standard Carnot limit. Furthermore, a cycle process can be realized that allows to extract mechanical work from a single squeezed thermal reservoir. These results quantitatively test our understanding of non-equilibrium thermodynamics at small scales and provide a new perspective on the design of efficient, highly miniaturized engines.
Invited speaker: Tommaso Roscilde
Affiliation: ENS Lyon
Title: Quantum correlations: Where are they? How do they build up? How to measure them?
Time and room: 17:15 h, lecture hall IAP
When a system is composed of many parts, "more is different" (as P. W. Anderson famously wrote) if and only if there are correlations among the various parts. If the constituents are quantum mechanical atoms, spins, oscillators, etc., "more" can be even "more different", as correlations can take forms which are impossible in classical mechanics. The most famous, yet elusive form of quantum correlation is represented by entanglement, a property well defined and investigated for pure states, and envisioned as a resource for nearly all technological tasks harnessing quantum many-body systems. In the real life of mixed states incoherent fluctuations appear in the game, making the distinction of quantum vs. classical correlations less sharp. At the same time, the exquisite level of control achieved by experiments in atomic, molecular and optical (AMO) physics enables nowadays to engineer correlated phases of quantum many-body systems, so that the ability to characterize and control quantum correlations becomes a fundamental question, as well as (possibly) a technological one.
In this colloquium I will try to offer a broad overview of the theoretical importance of quantum correlations, starting from their very definition - to which we contributed recently with a statistical physics approach which allows to calculate them in generic systems, and potentially to measure them for a large class of quantum many-body systems relevant to experiments in AMO physics and beyond. I will moreover discuss the centrality of quantum correlations in the dynamics that leads a closed quantum system to relax to an equilibrium state, contrasting the case of short-range interactions with that of long-range ones: this contrast allows to enlighten the role of elementary excitations (and in particular of their dispersion relation) as the "carriers" of quantum correlations.
Invited speaker: David Hunger
Affiliation: LMU München
Title: Quantum- and Nanooptics with Tunable Microcavities
Time and room: 17:15 h, lecture hall IAP
Spatio-temporal confinement of light can dramatically enhance light-matter interactions. To achieve this capability on an accessible platform, we have developed microscopic Fabry-Perot cavities based on laser-machined optical fibers [1].
We employ such cavities to realize efficient and narrow-band single-photon sources by means of Purcell enhancement of fluorescence emission. We study color centers in diamond such as the Nitrogen-Vacancy center [2] and explore different regimes of the cavity enhancement, aiming at applications in quantum cryptography, all-optical quantum computation, and efficient spin-state readout.
In the context of sensitive microscopy, we use microcavities for imaging and spectroscopy applications. We have developed scanning cavity microscopy as a versatile method for spatially and spectrally resolved maps of various optical properties of a sample with ultra-high sensitivity. We demonstrate the technique by quantitative imaging of the extinction cross-section of gold nanoparticles and measurements of the birefringence and extinction contrast of gold nanorods [3]. Finally, we show that the Purcell effect can be used for cavity-enhanced Raman spectroscopy and hyperspectral imaging [4]. Simultaneous enhancement of absorptive, dispersive, and scattering signals promises intriguing potential for optical studies of nanomaterials, molecules and biological nanosystems.
[1] D. Hunger et al., New J. Phys. 12, 065038 (2010)
[2] H. Kaupp et al., Phys Rev Applied 6, 054010 (2016)
[3] M. Mader et al., Nature Commun. 6, 7249 (2015)
[4] T. Hümmer et al., Nature Commun. 7, 12155 (2016)
Invited speaker: Hendrik Bluhm
Affiliation: RWTH Aachen
Title: Semiconductor Spin Qubits - From Proof of Principle Demonstrations to High Fidelity Quantum Gates
Time and room: 17:15 h, lecture hall IAP
Qubits based on electron spins trapped in fabricated semiconductor nanostructures such as gate controlled quantum dots or individual donors are considered promising candidates for scalable solid state quantum computing, which promises an exponential speedup for certain computational tasks.
Starting from an outline of the development of key concepts, I will give a (selective) overview of the current state of the art of GaAs and Si based spin qubit devices. Key results include single shot readout, high fidelity single-qubit manipulation, and first demonstrations of two-qubit gates. One particular focus of my talk will be effects from the hyperfine interaction of nuclear spins with the electron spin qubit, which is a source of strong decoherence when present and unavoidable in GaAs devices. The intricate physics emerging from hyperfine coupling is now rather well understood and we have developed effective methods to reduce the associated dephasing and achieve high fidelity qubit control.