Your search keyword '"Gieseler, Jan"' showing total 16 results

1. Multiple injections of energetic electrons associated with the flare/CME event on 9 October 2021

Author

Jebaraj, Immanuel Christopher, Kouloumvakos, Athanasios, Dresing, Nina, Warmuth, Alexander, Wijsen, Nicolas, Palmroos, Christian, Gieseler, Jan, Vainio, Rami, Krupar, Vratislav, Magdalenic, Jasmina, Wiegelmann, Thomas, Schuller, Frederic, Battaglia, Andrea, Fedeli, Annamaria, Jebaraj, Immanuel Christopher, Kouloumvakos, Athanasios, Dresing, Nina, Warmuth, Alexander, Wijsen, Nicolas, Palmroos, Christian, Gieseler, Jan, Vainio, Rami, Krupar, Vratislav, Magdalenic, Jasmina, Wiegelmann, Thomas, Schuller, Frederic, Battaglia, Andrea, and Fedeli, Annamaria

Abstract

We study the solar energetic particle (SEP) event observed on 9 October 2021, by multiple spacecraft including Solar Orbiter (SolO). The event was associated with an M1.6 flare, a coronal mass ejection (CME) and a shock wave. During the event, high-energy protons and electrons were recorded by multiple instruments located within a narrow longitudinal cone. An interesting aspect of the event was the multi-stage particle energization during the flare impulsive phase and also what appears to be a separate phase of electron acceleration detected at SolO after the flare maximum. We aim to investigate and identify the multiple sources of energetic electron acceleration. We utilize SEP electron observations from the Energetic Particle Detector (EPD) and hard X-ray (HXR) observations from the Spectrometer/Telescope for Imaging X-rays (STIX) on-board SolO, in combination with radio observations at a broad frequency range. We focus on establishing an association between the energetic electrons and the different HXR and radio emissions associated with the multiple acceleration episodes. We have found that the flare was able to accelerate electrons for at least 20 minutes during the nonthermal phase observed in the form of five discrete HXR pulses. We also show evidence that the shock wave has contributed to the electron acceleration during and after the impulsive flare phase. The detailed analysis of EPD electron data shows that there was a time difference in the release of low- and high-energy electrons, with the high-energy release delayed. Also, the observed electron anisotropy characteristics suggest different connectivity during the two phases of acceleration., Comment: 17 pages, 10 figures (main text). 3 pages, 3 figures (appendix). In review

Published

2023

2. Relativistic electron beams accelerated by an interplanetary shock

Author

Jebaraj, Immanuel C., Dresing, Nina, Krasnoselskikh, Vladimir, Agapitov, Oleksiy V., Gieseler, Jan, Trotta, Domenico, Wijsen, Nicolas, Larosa, Andrea, Kouloumvakos, Athanasios, Palmroos, Christian, Dimmock, Andrew, Kolhoff, Alexander, Kuehl, Patrick, Fleth, Sebastian, Fedeli, Annamaria, Valkila, Saku, Lario, David, Khotyaintsev, Yuri V., Vainio, Rami, Jebaraj, Immanuel C., Dresing, Nina, Krasnoselskikh, Vladimir, Agapitov, Oleksiy V., Gieseler, Jan, Trotta, Domenico, Wijsen, Nicolas, Larosa, Andrea, Kouloumvakos, Athanasios, Palmroos, Christian, Dimmock, Andrew, Kolhoff, Alexander, Kuehl, Patrick, Fleth, Sebastian, Fedeli, Annamaria, Valkila, Saku, Lario, David, Khotyaintsev, Yuri V., and Vainio, Rami

Abstract

Collisionless shock waves have long been considered amongst the most prolific particle accelerators in the universe. Shocks alter the plasma they propagate through and often exhibit complex evolution across multiple scales. Interplanetary (IP) traveling shocks have been recorded in-situ for over half a century and act as a natural laboratory for experimentally verifying various aspects of large-scale collisionless shocks. A fundamentally interesting problem in both helio and astrophysics is the acceleration of electrons to relativistic energies (more than 300 keV) by traveling shocks. This letter presents first observations of field-aligned beams of relativistic electrons upstream of an IP shock observed thanks to the instrumental capabilities of Solar Orbiter. This study aims to present the characteristics of the electron beams close to the source and contribute towards understanding their acceleration mechanism. On 25 July 2022, Solar Orbiter encountered an IP shock at 0.98 AU. The shock was associated with an energetic storm particle event which also featured upstream field-aligned relativistic electron beams observed 14 minutes prior to the actual shock crossing. The distance of the beam's origin was investigated using a velocity dispersion analysis (VDA). Peak-intensity energy spectra were anaylzed and compared with those obtained from a semi-analytical fast-Fermi acceleration model. By leveraging Solar Orbiter's high-time resolution Energetic Particle Detector (EPD), we have successfully showcased an IP shock's ability to accelerate relativistic electron beams. Our proposed acceleration mechanism offers an explanation for the observed electron beam and its characteristics, while we also explore the potential contributions of more complex mechanisms., Comment: Main text: 6 pages, 2 figures. Supplementary material: 6 pages, 7 figures

Published

2023

3. Solar Energetic Particle Time Series Analysis with Python

Author

Palmroos, Christian, Gieseler, Jan, Dresing, Nina, Morosan, Diana E., Asvestari, Eleanna, Yli-Laurila, Aleksi, Price, Daniel J., Valkila, Saku, Vainio, Rami, Palmroos, Christian, Gieseler, Jan, Dresing, Nina, Morosan, Diana E., Asvestari, Eleanna, Yli-Laurila, Aleksi, Price, Daniel J., Valkila, Saku, and Vainio, Rami

Abstract

Solar Energetic Particles (SEPs) are charged particles accelerated within the solar atmosphere or the interplanetary space by explosive phenomena such as solar flares or Coronal Mass Ejections (CMEs). Once injected into the interplanetary space, they can propagate towards Earth, causing space weather related phenomena. For their analysis, interplanetary in-situ measurements of charged particles are key. The recently expanded spacecraft fleet in the heliosphere not only provides much-needed additional vantage points, but also increases the variety of missions and instruments for which data loading and processing tools are needed. This manuscript introduces a series of Python functions that will enable the scientific community to download, load, and visualize charged particle measurements of the current space missions that are especially relevant to particle research as time series or dynamic spectra. In addition, further analytical functionality is provided that allows the determination of SEP onset times as well as their inferred injection times. The full workflow, which is intended to be run within Jupyter Notebooks and can also be approachable for Python laymen, will be presented with scientific examples. All functions are written in Python, with the source code publicly available at GitHub under a permissive license. Where appropriate, available Python libraries are used, and their application is described.

Published

2022

4. Solar-MACH: An open-source tool to analyze solar magnetic connection configurations

Author

Gieseler, Jan, Dresing, Nina, Palmroos, Christian, von Forstner, Johan L. Freiherr, Price, Daniel J., Vainio, Rami, Kouloumvakos, Athanasios, Rodríguez-García, Laura, Trotta, Domenico, Génot, Vincent, Masson, Arnaud, Roth, Markus, Veronig, Astrid, Gieseler, Jan, Dresing, Nina, Palmroos, Christian, von Forstner, Johan L. Freiherr, Price, Daniel J., Vainio, Rami, Kouloumvakos, Athanasios, Rodríguez-García, Laura, Trotta, Domenico, Génot, Vincent, Masson, Arnaud, Roth, Markus, and Veronig, Astrid

Abstract

The Solar MAgnetic Connection HAUS tool (Solar-MACH) is an open-source tool completely written in Python that derives and visualizes the spatial configuration and solar magnetic connection of different observers (i.e., spacecraft or planets) in the heliosphere at different times. For doing this, the magnetic connection in the interplanetary space is obtained by the classic Parker Heliospheric Magnetic Field (HMF). In close vicinity of the Sun, a Potential Field Source Surface (PFSS) model can be applied to connect the HMF to the solar photosphere. Solar-MACH is especially aimed at providing publication-ready figures for the analyses of Solar Energetic Particle events (SEPs) or solar transients such as Coronal Mass Ejections (CMEs). It is provided as an installable Python package (listed on PyPI and conda-forge), but also as a web tool at solar-mach.github.io that completely runs in any web browser and requires neither Python knowledge nor installation. The development of Solar-MACH is open to everyone and takes place on GitHub, where the source code is publicly available under the BSD 3-Clause License. Established Python libraries like sunpy and pfsspy are utilized to obtain functionalities when possible. In this article, the Python code of Solar-MACH is explained, and its functionality is demonstrated using real science examples. In addition, we introduce the overarching SERPENTINE project, the umbrella under which the recent development took place., Comment: 14 pages, 5 figures

Published

2022

5. Calibration of RADMON Radiation Monitor Onboard Aalto-1 CubeSat

Author

Oleynik, Philipp, Vainio, Rami, Punkkinen, Arttu, Dudnik, Oleksiy, Gieseler, Jan, Hedman, Hannu-Pekka, Hietala, Heli, Hæggström, Edward, Niemelä, Petri, Peltonen, Juhani, Praks, Jaan, Punkkinen, Risto, Säntti, Tero, Valtonen, Eino, Oleynik, Philipp, Vainio, Rami, Punkkinen, Arttu, Dudnik, Oleksiy, Gieseler, Jan, Hedman, Hannu-Pekka, Hietala, Heli, Hæggström, Edward, Niemelä, Petri, Peltonen, Juhani, Praks, Jaan, Punkkinen, Risto, Säntti, Tero, and Valtonen, Eino

Abstract

RADMON is a small radiation monitor designed and assembled by students of the University of Turku and the University of Helsinki. It is flown on-board Aalto-1, a 3-unit CubeSat in low Earth orbit at about 500 km altitude. The detector unit of the instrument consists of two detectors, a Si solid-state detector and a CsI(Tl) scintillator, and utilizes the \textDelta{E}-E technique to determine the total energy and species of each particle hitting the detector. We present the results of the on-ground and in-flight calibration campaigns of the instrument, as well as the characterization of its response through extensive simulations within the Geant4 framework. The overall energy calibration margin achieved is about 5\%. The full instrument response to protons and electrons is presented and the issue of proton contamination of the electron channels is quantified and discussed., Comment: 27 pages, 9 figures

Published

2019

6. Calibration of RADMON Radiation Monitor Onboard Aalto-1 CubeSat

Author

Oleynik, Philipp, Vainio, Rami, Punkkinen, Arttu, Dudnik, Oleksiy, Gieseler, Jan, Hedman, Hannu-Pekka, Hietala, Heli, Hæggström, Edward, Niemelä, Petri, Peltonen, Juhani, Praks, Jaan, Punkkinen, Risto, Säntti, Tero, Valtonen, Eino, Oleynik, Philipp, Vainio, Rami, Punkkinen, Arttu, Dudnik, Oleksiy, Gieseler, Jan, Hedman, Hannu-Pekka, Hietala, Heli, Hæggström, Edward, Niemelä, Petri, Peltonen, Juhani, Praks, Jaan, Punkkinen, Risto, Säntti, Tero, and Valtonen, Eino

Abstract

RADMON is a small radiation monitor designed and assembled by students of the University of Turku and the University of Helsinki. It is flown on-board Aalto-1, a 3-unit CubeSat in low Earth orbit at about 500 km altitude. The detector unit of the instrument consists of two detectors, a Si solid-state detector and a CsI(Tl) scintillator, and utilizes the \textDelta{E}-E technique to determine the total energy and species of each particle hitting the detector. We present the results of the on-ground and in-flight calibration campaigns of the instrument, as well as the characterization of its response through extensive simulations within the Geant4 framework. The overall energy calibration margin achieved is about 5\%. The full instrument response to protons and electrons is presented and the issue of proton contamination of the electron channels is quantified and discussed., Comment: 27 pages, 9 figures

Published

2019

7. Levitated Nanoparticles for Microscopic Thermodynamics—A Review

Author

Gieseler, Jan, Millen, James, Gieseler, Jan, and Millen, James

Abstract

Levitated Nanoparticles have received much attention for their potential to perform quantum mechanical experiments even at room temperature. However, even in the regime where the particle dynamics are purely classical, there is a lot of interesting physics that can be explored. Here we review the application of levitated nanoparticles as a new experimental platform to explore stochastic thermodynamics in small systems, J.G. acknowledges support from the European Union (SEQOO, H2020-MSCA-IF-2014)and is thankful for the stimulating discussions and feedback from Christoph Dellago, Martin Frimmer,Lukas Novotnyand Udo Seifert. J. M. acknowledges support from the Austrian Science Fund (FWF, P27297) andfrom the European COST network MP1209. J.M. is grateful for discussions with B. A. Stickler., Peer Reviewed, Postprint (published version)

Published

2018

8. The sandwich in the middle: using collective effects for stronger optomechanical coupling

Author

Gieseler, Jan and Gieseler, Jan

Abstract

Peer Reviewed, Postprint (updated version)

Published

2018

9. An empirical modification of the force field approach to describe the modulation of galactic cosmic rays close to Earth in a broad range of rigidities

Author

Gieseler, Jan, Heber, Bernd, Herbst, Konstantin, Gieseler, Jan, Heber, Bernd, and Herbst, Konstantin

Abstract

On their way through the heliosphere, Galactic Cosmic Rays (GCRs) are modulated by various effects before they can be detected at Earth. This process can be described by the Parker equation, which calculates the phase space distribution of GCRs depending on the main modulation processes: convection, drifts, diffusion and adiabatic energy changes. A first order approximation of this equation is the force field approach, reducing it to a one-parameter dependency, the solar modulation potential $\phi$. Utilizing this approach, it is possible to reconstruct $\phi$ from ground based and spacecraft measurements. However, it has been shown previously that $\phi$ depends not only on the Local Interstellar Spectrum (LIS) but also on the energy range of interest. We have investigated this energy dependence further, using published proton intensity spectra obtained by PAMELA as well as heavier nuclei measurements from IMP-8 and ACE/CRIS. Our results show severe limitations at lower energies including a strong dependence on the solar magnetic epoch. Based on these findings, we will outline a new tool to describe GCR proton spectra in the energy range from a few hundred MeV to tens of GeV over the last solar cycles. In order to show the importance of our modification, we calculate the global production rates of the cosmogenic radionuclide $^{10}$Be which is a proxy for the solar activity ranging back thousands of years.

Published

2017

10. An empirical modification of the force field approach to describe the modulation of galactic cosmic rays close to Earth in a broad range of rigidities

Author

Gieseler, Jan, Heber, Bernd, Herbst, Konstantin, Gieseler, Jan, Heber, Bernd, and Herbst, Konstantin

Abstract

On their way through the heliosphere, Galactic Cosmic Rays (GCRs) are modulated by various effects before they can be detected at Earth. This process can be described by the Parker equation, which calculates the phase space distribution of GCRs depending on the main modulation processes: convection, drifts, diffusion and adiabatic energy changes. A first order approximation of this equation is the force field approach, reducing it to a one-parameter dependency, the solar modulation potential $\phi$. Utilizing this approach, it is possible to reconstruct $\phi$ from ground based and spacecraft measurements. However, it has been shown previously that $\phi$ depends not only on the Local Interstellar Spectrum (LIS) but also on the energy range of interest. We have investigated this energy dependence further, using published proton intensity spectra obtained by PAMELA as well as heavier nuclei measurements from IMP-8 and ACE/CRIS. Our results show severe limitations at lower energies including a strong dependence on the solar magnetic epoch. Based on these findings, we will outline a new tool to describe GCR proton spectra in the energy range from a few hundred MeV to tens of GeV over the last solar cycles. In order to show the importance of our modification, we calculate the global production rates of the cosmogenic radionuclide $^{10}$Be which is a proxy for the solar activity ranging back thousands of years.

Published

2017

11. Macroscopic Quantum Resonators (MAQRO) : 2015 update

Author

Kaltenbaek, Rainer, Aspelmeyer, Markus, Barker, Peter F., Bassi, Angelo, Bateman, James, Bongs, Kai, Bose, Sougato, Braxmaier, Claus, Brukner, Caslav, Christophe, Bruno, Chwalla, Michael, Cohadon, Pierre-Francois, Cruise, Adrian Michael, Curceanu, Catalina, Dholakia, Kishan, Diosi, Lajos, Doeringshoff, Klaus, Ertmer, Wolfgang, Gieseler, Jan, Guerlebeck, Norman, Hechenblaikner, Gerald, Heidmann, Antoine, Herrmann, Sven, Hossenfelder, Sabine, Johann, Ulrich, Kiesel, Nikolai, Kim, Myungshik, Laemmerzahl, Claus, Lambrecht, Astrid, Mazilu, Michael, Milburn, Gerard J., Mueller, Holger, Novotny, Lukas, Paternostro, Mauro, Peters, Achim, Pikovski, Igor, Zanoni, Andre Pilan, Rasel, Ernst M., Reynaud, Serge, Riedel, Charles Jess, Rodrigues, Manuel, Rondin, Loic, Roura, Albert, Schleich, Wolfgang P., Schmiedmayer, Joerg, Schuldt, Thilo, Schwab, Keith C., Tajmar, Martin, Tino, Guglielmo M., Ulbricht, Hendrik, Ursin, Rupert, Vedral, Vlatko, Kaltenbaek, Rainer, Aspelmeyer, Markus, Barker, Peter F., Bassi, Angelo, Bateman, James, Bongs, Kai, Bose, Sougato, Braxmaier, Claus, Brukner, Caslav, Christophe, Bruno, Chwalla, Michael, Cohadon, Pierre-Francois, Cruise, Adrian Michael, Curceanu, Catalina, Dholakia, Kishan, Diosi, Lajos, Doeringshoff, Klaus, Ertmer, Wolfgang, Gieseler, Jan, Guerlebeck, Norman, Hechenblaikner, Gerald, Heidmann, Antoine, Herrmann, Sven, Hossenfelder, Sabine, Johann, Ulrich, Kiesel, Nikolai, Kim, Myungshik, Laemmerzahl, Claus, Lambrecht, Astrid, Mazilu, Michael, Milburn, Gerard J., Mueller, Holger, Novotny, Lukas, Paternostro, Mauro, Peters, Achim, Pikovski, Igor, Zanoni, Andre Pilan, Rasel, Ernst M., Reynaud, Serge, Riedel, Charles Jess, Rodrigues, Manuel, Rondin, Loic, Roura, Albert, Schleich, Wolfgang P., Schmiedmayer, Joerg, Schuldt, Thilo, Schwab, Keith C., Tajmar, Martin, Tino, Guglielmo M., Ulbricht, Hendrik, Ursin, Rupert, and Vedral, Vlatko

Abstract

Do the laws of quantum physics still hold for macroscopic objects - this is at the heart of Schrodinger's cat paradox - or do gravitation or yet unknown effects set a limit for massive particles? What is the fundamental relation between quantum physics and gravity? Ground-based experiments addressing these questions may soon face limitations due to limited free-fall times and the quality of vacuum and microgravity. The proposed mission Macroscopic Quantum Resonators (MAQRO) may overcome these limitations and allow addressing such fundamental questions. MAQRO harnesses recent developments in quantum optomechanics, high-mass matter-wave interferometry as well as state-of-the-art space technology to push macroscopic quantum experiments towards their ultimate performance limits and to open new horizons for applying quantum technology in space. The main scientific goal is to probe the vastly unexplored 'quantum-classical' transition for increasingly massive objects, testing the predictions of quantum theory for objects in a size and mass regime unachievable in ground-based experiments. The hardware will largely be based on available space technology. Here, we present the MAQRO proposal submitted in response to the 4th Cosmic Vision call for a medium-sized mission (M4) in 2014 of the European Space Agency (ESA) with a possible launch in 2025, and we review the progress with respect to the original MAQRO proposal for the 3rd Cosmic Vision call for a medium-sized mission (M3) in 2010. In particular, the updated proposal overcomes several critical issues of the original proposal by relying on established experimental techniques from high-mass matter-wave interferometry and by introducing novel ideas for particle loading and manipulation. Moreover, the mission design was improved to better fulfill the stringent environmental requirements for macroscopic quantum experiments., QC 20200313

Published

2016

12. Macroscopic Quantum Resonators (MAQRO) : 2015 update

Author

Kaltenbaek, Rainer, Aspelmeyer, Markus, Barker, Peter F., Bassi, Angelo, Bateman, James, Bongs, Kai, Bose, Sougato, Braxmaier, Claus, Brukner, Časlav, Christophe, Bruno, Chwalla, Michael, Cohadon, Pierre-François, Cruise, Adrian Michael, Curceanu, Catalina, Dholakia, Kishan, Diósi, Lajos, Döringshoff, Klaus, Ertmer, Wolfgang, Gieseler, Jan, Gürlebeck, Norman, Hechenblaikner, Gerald, Heidmann, Antoine, Herrmann, Sven, Hossenfelder, Sabine, Johann, Ulrich, Kiesel, Nikolai, Kim, Myungshik, Lämmerzahl, Claus, Lambrecht, Astrid, Mazilu, Michael, Milburn, Gerard J., Müller, Holger, Novotny, Lukas, Paternostro, Mauro, Peters, Achim, Pikovski, Igor, Zanoni, André Pilan, Rasel, Ernst M., Reynaud, Serge, Riedel, Charles Jess, Rodrigues, Manuel, Rondin, Loïc, Roura, Albert, Schleich, Wolfgang P., Schmiedmayer, Jörg, Schuldt, Thilo, Schwab, Keith C., Tajmar, Martin, Tino, Guglielmo M., Ulbricht, Hendrik, Ursin, Rupert, Vedral, Vlatko, Kaltenbaek, Rainer, Aspelmeyer, Markus, Barker, Peter F., Bassi, Angelo, Bateman, James, Bongs, Kai, Bose, Sougato, Braxmaier, Claus, Brukner, Časlav, Christophe, Bruno, Chwalla, Michael, Cohadon, Pierre-François, Cruise, Adrian Michael, Curceanu, Catalina, Dholakia, Kishan, Diósi, Lajos, Döringshoff, Klaus, Ertmer, Wolfgang, Gieseler, Jan, Gürlebeck, Norman, Hechenblaikner, Gerald, Heidmann, Antoine, Herrmann, Sven, Hossenfelder, Sabine, Johann, Ulrich, Kiesel, Nikolai, Kim, Myungshik, Lämmerzahl, Claus, Lambrecht, Astrid, Mazilu, Michael, Milburn, Gerard J., Müller, Holger, Novotny, Lukas, Paternostro, Mauro, Peters, Achim, Pikovski, Igor, Zanoni, André Pilan, Rasel, Ernst M., Reynaud, Serge, Riedel, Charles Jess, Rodrigues, Manuel, Rondin, Loïc, Roura, Albert, Schleich, Wolfgang P., Schmiedmayer, Jörg, Schuldt, Thilo, Schwab, Keith C., Tajmar, Martin, Tino, Guglielmo M., Ulbricht, Hendrik, Ursin, Rupert, and Vedral, Vlatko

Abstract

Do the laws of quantum physics still hold for macroscopic objects - this is at the heart of Schrodinger's cat paradox - or do gravitation or yet unknown effects set a limit for massive particles? What is the fundamental relation between quantum physics and gravity? Ground-based experiments addressing these questions may soon face limitations due to limited free-fall times and the quality of vacuum and microgravity. The proposed mission Macroscopic Quantum Resonators (MAQRO) may overcome these limitations and allow addressing such fundamental questions. MAQRO harnesses recent developments in quantum optomechanics, high-mass matter-wave interferometry as well as state-of-the-art space technology to push macroscopic quantum experiments towards their ultimate performance limits and to open new horizons for applying quantum technology in space. The main scientific goal is to probe the vastly unexplored 'quantum-classical' transition for increasingly massive objects, testing the predictions of quantum theory for objects in a size and mass regime unachievable in ground-based experiments. The hardware will largely be based on available space technology. Here, we present the MAQRO proposal submitted in response to the 4th Cosmic Vision call for a medium-sized mission (M4) in 2014 of the European Space Agency (ESA) with a possible launch in 2025, and we review the progress with respect to the original MAQRO proposal for the 3rd Cosmic Vision call for a medium-sized mission (M3) in 2010. In particular, the updated proposal overcomes several critical issues of the original proposal by relying on established experimental techniques from high-mass matter-wave interferometry and by introducing novel ideas for particle loading and manipulation. Moreover, the mission design was improved to better fulfill the stringent environmental requirements for macroscopic quantum experiments.

Published

2016

13. Spatial gradients of GCR protons in the inner heliosphere derived from Ulysses COSPIN/KET and PAMELA measurements

Author

Gieseler, Jan, Heber, Bernd, Gieseler, Jan, and Heber, Bernd

Abstract

During the transition from solar cycle 23 to 24 from 2006 to 2009, the Sun was in an unusual solar minimum with very low activity over a long period. These exceptional conditions included a very low interplanetary magnetic field (IMF) strength and a high tilt angle, which both play an important role in the modulation of galactic cosmic rays (GCR) in the heliosphere. Thus, the radial and latitudinal gradients of GCRs are very much expected to depend not only on the solar magnetic epoch, but also on the overall modulation level. We determine the non-local radial and the latitudinal gradients of protons in the rigidity range from ~0.45 to 2 GV. This was accomplished by using data from the satellite-borne experiment Payload for Antimatter Matter Exploration and Light-nuclei Astrophysics (PAMELA) at Earth and the Kiel Electron Telescope (KET) onboard Ulysses on its highly inclined Keplerian orbit around the Sun with the aphelion at Jupiter's orbit. In comparison to the previous A>0 solar magnetic epoch, we find that the absolute value of the latitudinal gradient is lower at higher and higher at lower rigidities. This energy dependence is therefore a crucial test for models that describe the cosmic ray transport in the inner heliosphere.

Published

2016

14. Spatial gradients of GCR protons in the inner heliosphere derived from Ulysses COSPIN/KET and PAMELA measurements

Author

Gieseler, Jan, Heber, Bernd, Gieseler, Jan, and Heber, Bernd

Abstract

During the transition from solar cycle 23 to 24 from 2006 to 2009, the Sun was in an unusual solar minimum with very low activity over a long period. These exceptional conditions included a very low interplanetary magnetic field (IMF) strength and a high tilt angle, which both play an important role in the modulation of galactic cosmic rays (GCR) in the heliosphere. Thus, the radial and latitudinal gradients of GCRs are very much expected to depend not only on the solar magnetic epoch, but also on the overall modulation level. We determine the non-local radial and the latitudinal gradients of protons in the rigidity range from ~0.45 to 2 GV. This was accomplished by using data from the satellite-borne experiment Payload for Antimatter Matter Exploration and Light-nuclei Astrophysics (PAMELA) at Earth and the Kiel Electron Telescope (KET) onboard Ulysses on its highly inclined Keplerian orbit around the Sun with the aphelion at Jupiter's orbit. In comparison to the previous A>0 solar magnetic epoch, we find that the absolute value of the latitudinal gradient is lower at higher and higher at lower rigidities. This energy dependence is therefore a crucial test for models that describe the cosmic ray transport in the inner heliosphere.

Published

2016

15. Cooling and manipulation of a levitated nanoparticle with an optical fiber trap

Author

Universitat Politècnica de Catalunya. Institut de Ciències Fotòniques, Mestres, Pau, Berthelot, Johann, Spasenović, Marko, Gieseler, Jan, Novotny, Lukas, Quidant, Romain, Universitat Politècnica de Catalunya. Institut de Ciències Fotòniques, Mestres, Pau, Berthelot, Johann, Spasenović, Marko, Gieseler, Jan, Novotny, Lukas, and Quidant, Romain

Abstract

Accurate delivery of small targets in high vacuum is a pivotal task in many branches of science and technology. Beyond the different strategies developed for atoms, proteins, macroscopic clusters, and pellets, the manipulation of neutral particles over macroscopic distances still poses a formidable challenge. Here, we report an approach based on a mobile optical trap operated under feedback control that enables cooling and long range 3D manipulation of a silica nanoparticle in high vacuum. We apply this technique to load a single nanoparticle into a high-finesse optical cavity through a load-lock vacuum system. We foresee our scheme to benefit the field of optomechanics with levitating nano-objects as well as ultrasensitive detection and monitoring., Peer Reviewed, Postprint (published version)

Published

2015

16. Dynamics of optically levitated nanoparticles in high vacuum

Author

Universitat Politècnica de Catalunya. Institut de Ciències Fotòniques, Quidant, Romain, Novotny, Lukas, Gieseler, Jan, Universitat Politècnica de Catalunya. Institut de Ciències Fotòniques, Quidant, Romain, Novotny, Lukas, and Gieseler, Jan

Abstract

Premi extraordinari doctorat 2013-2014, Nanotechnology was named one of the key enabling technologies by the European Commission and its tremendous impact was envisioned early by 20th century physicist R.Feynman in his now oft-quoted talk "Plenty of Room at the bottom". Nanotechnology and nanoscience deal with structures barely visible with an optical microscope, yet much bigger than simple molecules. Matter at this mesoscale is often awkward to explore as it contains too many atoms to be easily understood by straightforward application of quantum mechanics (although the fundamental laws still apply). Yet, these systems are not so large as to be completely free of quantum effects; thus, they do not simply obey the classical physics governing the macroworld. It is precisely in this intermediate regime, the mesoworld, that unforeseen properties of collective systems emerge. To fully exploit the potential of nanotechnology, a thorough understanding of these properties is paramount. The objective of the present thesis is to investigate and to control the dynamics of an optically levitated particle in high vacuum, a system which belongs to the broader class of nanomechanical oscillators. Nanomechanical oscillators exhibit high resonance frequencies, diminished active masses, low power consumption and high quality factors - significantly higher than those of electrical circuits. These attributes make them suitable for sensing, transduction and signal processing. Furthermore, nanomechanical systems are expected to open up investigations of the quantum behavior of mesoscopic systems. Testing the predictions of quantum theory on macroscopic scales is one of today's outstanding challenges of modern physics and addresses fundamental questions on our understanding of the world. The state-of-the-art in nanomechanics itself has exploded in recent years, driven by a combination of interesting new systems and vastly improved fabrication capabilities. Despite major break-throughs, including ground state cooling, observati, Award-winning, Postprint (published version)

Published

2014