Atom interferometry with ultracold atoms for inertial sensing

In light pulse atom interferometry wave packets are spatially separated and recombined in a coherent manner by interacting with laser pulses. Typically, two photon transitions are used to perform Rabi oscillations between two internal or/and external states to construct atom-optical elements, like beam splitters or mirrors. The phase difference accumulated between two atomictrajectories can be used to measure quantities such as accelerations or rotations. The velocity distribution and size of the employed atomic sources can significantly limit the efficiency of the atom-light interactions and thus the performance of the interferometer. To overcome this limitation, ensembles with momentum distributions far below the recoil of a photon are used, such as collimated Bose-Einstein condensates (BEC). Exploiting the properties of a BEC opens up a wide range of possibilities for new techniques and concepts, especially for increasing the sensitivity of measurements performed in small volumes. This work presents some of these novelties. The technique of an innovative (re-)launch mechanism helps to effectively increase the available interferometry time in compact gravimeter setups. A symmetric large momentum transfer in the form of a twin-lattice enables the enclosure of large space-time areas suitable for rotation measurements with high sensitivities. The exploitation of a BEC in combination with momentum transfer by double Bragg diffraction contributed to the development of a new concept. Using a single BEC, it is possible to create two simultaneous interferometers, which are employed to differentiate between rotations and accelerations. Its symmetry allows this geometry to be extended to form the basis of a six-axis quantum inertial measurement unit. Last but not least, the (re-)launch in combination with the symmetric splitting also provides the basis for a multi-loop atom interferometer. With this concept, an area can be enclosed that offers unique scalability for rotational sensors. Each atom interferometer is affected by the quality of its interrogating light fields. Therefore specific detrimental effects are pointed out in this work and possible mitigation strategies are presented subsequently. One way to reduce the susceptibility of light beams to distortions at apertures is to change their profile from the commonly used Gaussian profile to a more locally limited intensity distribution. For this purpose, the application of flat-top beam profiles is investigated. This brings the added benefit of a uniform power distribution, which helps to increase the beam area in which the ensemble of atoms can be manipulated with the same properties. Imperfections can also lead to position-dependent dipole forces that have a parasitic effect on the output of an interferometer. Especially for large momentum transfer techniques this has proven to be a limitation which can necessitate a compensation mechanism. To this end, a laser system is constructed that achieves the required high laser powers and includes additional frequency components. Many of the interferometry methods and concepts introduced are well suited for compact or transportable systems. For this purpose, a laser system based on telecommunication fiber components is presented, which represents an all-in-one solution for the generation, preparation and subsequent beam splitting of ultracold atoms. Inspired by all of the above, the future vision of a quantum sensor for inertial navigation applications is discussed

Multi-loop atomic Sagnac interferometry

The sensitivity of light and matter-wave interferometers to rotations is based on the Sagnac effect and increases with the area enclosed by the interferometer. In the case of light, the latter can be enlarged by forming multiple fibre loops, whereas the equivalent for matter-wave interferometers remains an experimental challenge. We present a concept for a multi-loop atom interferometer with a scalable area formed by light pulses. Our method will offer sensitivities as high as $$2\times 10^{-11}$$ rad/s at 1 s in combination with the respective long-term stability as required for Earth rotation monitoring

Twin-lattice atom interferometry

Inertial sensors based on cold atoms have great potential for navigation, geodesy, or fundamental physics. Similar to the Sagnac effect, their sensitivity increases with the space-time area enclosed by the interferometer. Here, we introduce twin-lattice atom interferometry exploiting Bose-Einstein condensates. Our method provides symmetric momentum transfer and large areas in palm-sized sensor heads with a performance similar to present meter-scale Sagnac devices

Association of a Functional Variant in the Wnt Co-Receptor LRP6 with Early Onset Ileal Crohn's Disease

Ileal Crohn's Disease (CD), a chronic small intestinal inflammatory disorder, is characterized by reduced levels of the antimicrobial peptides DEFA5 (HD-5) and DEFA6 (HD-6). Both of these α-defensins are exclusively produced in Paneth cells (PCs) at small intestinal crypt bases. Different ileal CD–associated genes including NOD2, ATG16L1, and recently the β-catenin–dependant Wnt transcription factor TCF7L2 have been linked to impaired PC antimicrobial function. The Wnt pathway influences gut mucosal homeostasis and PC maturation, besides directly controlling HD-5/6 gene expression. The herein reported candidate gene study focuses on another crucial Wnt factor, the co-receptor low density lipoprotein receptor-related protein 6 (LRP6). We analysed exonic single nucleotide polymorphisms (SNPs) in a large cohort (Oxford: n = 1,893) and prospectively tested 2 additional European sample sets (Leuven: n = 688, Vienna: n = 1,628). We revealed an association of a non-synonymous SNP (rs2302685; Ile1062Val) with early onset ileal CD (OR 1.8; p = 0.00034; for homozygous carriers: OR 4.1; p = 0.00004) and additionally with penetrating ileal CD behaviour (OR 1.3; p = 0.00917). In contrast, it was not linked to adult onset ileal CD, colonic CD, or ulcerative colitis. Since the rare variant is known to impair LRP6 activity, we investigated its role in patient mucosa. Overall, LRP6 mRNA was diminished in patients independently from the genotype. Analysing the mRNA levels of PC product in biopsies from genotyped individuals (15 controls, 32 ileal, and 12 exclusively colonic CD), we found particularly low defensin levels in ileal CD patients who were carrying the variant. In addition, we confirmed a direct relationship between LRP6 activity and the transcriptional expression of HD-5 using transient transfection. Taken together, we identified LRP6 as a new candidate gene in ileal CD. Impairments in Wnt signalling and Paneth cell biology seem to represent pathophysiological hallmarks in small intestinal inflammation and should therefore be considered as interesting targets for new therapeutic approaches

Twin-lattice atom interferometry

Inertial sensors based on cold atoms have great potential for navigation, geodesy, or fundamental physics. Similar to the Sagnac effect, their sensitivity increases with the space-time area enclosed by the interferometer. Here, we introduce twin-lattice atom interferometry exploiting Bose-Einstein condensates of rubidium-87. Our method provides symmetric momentum transfer and large areas offering a perspective for future palm-sized sensor heads with sensitivities on par with present meter-scale Sagnac devices. Our theoretical model of the impact of beam splitters on the spatial coherence is highly instrumental for designing future sensors

QGyro : Schlussbericht zum Verbundvorhaben Quanten-Inertialsensorsystem (QGyro)

Das Verbundvorhaben QGyro (Quanten-Inertialsensorsystem) ist ein Teil der High-Tech-Strategie der Bundesregierung und erhält Finanzierung durch das Bundesministerium für Wirtschaft und Klimaschutz (BMWK) mit Unterstützung der Raumfahrtagentur am Deutschen Zentrum für Luft- und Raumfahrt DLR e.V. (Förderkennzeichen 50RK1957). Im Rahmen dieses Forschungsvorhabens wurden mithilfe der Quantentechnologie innovative Konzepte für die Navigation von Plattformen entwickelt. Das Hauptziel des Projekts ist die Untersuchung von Hybridansätzen zur Inertialsensorik, bei der Quantensensoren mit klassischen inertialen Messeinheiten miteinander kombiniert werden um Fehler in der Positionsbestimmung zu reduzieren. Ein Hauptaugenmerk lag auf der Entwicklung neuartiger Quantensensoren. Ein erster Ansatz war die Schaffung eines einachsigen, quantenbasierten Inertialsensors als Proof-of-Concept. Dies beinhaltet den Sensorkopf, aber auch die Perepherie, wie Lasersysteme und Elektronik. Darüber hinaus wurden Entwicklungen in Richtung von sechsachsigen quantenbasierten Intertialsensoren angestoßen und Realisierungskonzepte erarbeitet. Ein besonderer Fokus lag auf der Stabilisierung und aktiven Ausrichtung des entwickelten Messkopfes, was durch Simulationen und experimentelle Tests nachgewiesen werden konnte. Dies beinhaltete die Entwicklung eines Teststandes, die Erarbeitung eines Atom-StrapDown-Algorithmus zur Kombination von Quanten-Inertialsensoren und klassischer Inertialsensorik sowie die Umsetzung einer stabilisierten Plattform für den Sensorkopf. Die erfolgreiche Umsetzung wurde in enger Zusammenarbeit mit Forschungseinrichtungen an der Leibniz Universität Hannover (Institut für Erdmessung, Institut für Quantenoptik) sowie etablierten Unternehmen wie der iMAR GmbH erreicht. Das Projekt QGyro trägt dazu bei, die High-Tech-Strategie der Bundesregierung im Bereich der Quantentechnologie und Navigation voranzutreiben.The collaborative project QGyro (quantum inertial sensor system) is part of the German Federal Government’s High-Tech Strategy and receives funding from the German Federal Ministry of Economics and Climate Protection (BMWK) with support from the Space Agency at the German Aerospace Center DLR e.V. (funding code 50 RK 1957). This research project used quantum technology to develop innovative concepts for the navigation of kinematic platforms. The main goal of the project is to investigate hybrid approaches for inertial sensors, combining quantum technology with classical inertial measurement devices in order to reduce errors in positioning. A primary focus has been the development of novel quantum sensors. A first approach considered the creation of a single-axis, quantum-based inertial sensor as a proof-of-concept. This includes the sensor head, and also the peripherals, such as laser systems and electronics. Furthermore, developments towards a six-axis quantum-based inertial sensor were initiated and realization concepts were elaborated. Further focus was on the stabilization and active alignment of the developed sensing head. For this purpose, a stabilized platform was designed and built that can compensate linear accelerations during the measurement time of the quantum sensor. A so-called Atom Strapdown algorithm was designed and implemented for inertial navigation for the combination of quantum inertial sensors and classical inertial sensors. This algorithm has been tested, optimized and validated in extensive simulation studies. Moreover, a successful application of the algorithm to real data was achieved by emulating the CAI observations with a navigation-grade IMU during the generation of the hybrid scenario. Algorithms for determining the uncertainties of the atomic interferometer were further developed and validated on prototype measurement series. Successful implementation was achieved in close collaboration with research institutions at Leibniz Universität Hannover (Institute of Geodesy, Institute of Quantum Optics) as well as established companies such as iMAR GmbH. The QGyro project contributes to advancing the German government’s high-tech strategy in the field of quantum technology and navigation.Deutsche Raumfahrtagentur im Deutschen Zentrum für Luft- und Raumfahrt e.V./Systemuntersuchungen und Technologie für die Satellitennavigation/BMWK 50 RK 1957/E

Momentum Entanglement for Atom Interferometry

Compared to light interferometers, the flux in cold-atom interferometers is low and the associated shot noise is large. Sensitivities beyond these limitations require the preparation of entangled atoms in different momentum modes. Here, we demonstrate a source of entangled atoms that is compatible with state-of-the-art interferometers. Entanglement is transferred from the spin degree of freedom of a Bose-Einstein condensate to well-separated momentum modes, witnessed by a squeezing parameter of -3.1 (8) dB. Entanglement-enhanced atom interferometers promise unprecedented sensitivities for quantum gradiometers or gravitational wave detectors

Technology roadmap for cold-atoms based quantum inertial sensor in space

Recent developments in quantum technology have resulted in a new generation of sensors for measuring inertial quantities, such as acceleration and rotation. These sensors can exhibit unprecedented sensitivity and accuracy when operated in space, where the free-fall interrogation time can be extended at will and where the environment noise is minimal. European laboratories have played a leading role in this field by developing concepts and tools to operate these quantum sensors in relevant environment, such as parabolic flights, free-fall towers, or sounding rockets. With the recent achievement of Bose-Einstein condensation on the International Space Station, the challenge is now to reach a technology readiness level sufficiently high at both component and system levels to provide "off the shelf"payload for future generations of space missions in geodesy or fundamental physics. In this roadmap, we provide an extensive review on the status of all common parts, needs, and subsystems for the application of atom-based interferometers in space, in order to push for the development of generic technology components

Terrestrial Very-Long-Baseline Atom Interferometry:Workshop Summary

This document presents a summary of the 2023 Terrestrial Very-Long-Baseline Atom Interferometry Workshop hosted by CERN. The workshop brought together experts from around the world to discuss the exciting developments in large-scale atom interferometer (AI) prototypes and their potential for detecting ultralight dark matter and gravitational waves. The primary objective of the workshop was to lay the groundwork for an international TVLBAI proto-collaboration. This collaboration aims to unite researchers from different institutions to strategize and secure funding for terrestrial large-scale AI projects. The ultimate goal is to create a roadmap detailing the design and technology choices for one or more km-scale detectors, which will be operational in the mid-2030s. The key sections of this report present the physics case and technical challenges, together with a comprehensive overview of the discussions at the workshop together with the main conclusions