EC-SLI experiment

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Isotope Separator On Line Device
(ISOLDE)
List of ISOLDE experimental setups
COLLAPS, CRIS, EC-SLI, IDS, ISS, ISOLTRAP, LUCRECIA, Miniball, MIRACLS, SEC, VITO, WISArD
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MEDICIS Medical Isotopes Collected from ISOLDE
508Solid State Physics Laboratory
The EC-SLI experiment at ISOLDE EC-SLI.jpg
The EC-SLI experiment at ISOLDE

The Emission Channeling with Short-Lived Isotopes (EC-SLI) experiment is a permanent setup located within the ISOLDE facility and CERN. The purpose of the experiment is to study lattice locations of dopants and impurities in both single crystals and epitaxial thin films. The experiment uses short-lived isotopes from the ISOLDE on-line beamline, as well as longer-lived isotopes from three off-line beamlines. [1]

Contents

Background

The EC-SLI experiment uses the method of emission channelling (EC) to identify the position of short-lived isotopes in a single crystal lattice. [2] Radioactive isotope probes are introduced into the crystal using ion implantation, and a positron-sensitive detector detects its decay particles. The particles that the isotope emits interact with the electrons and nuclei of the crystal's atoms, and experience channeling and blocking effects on their way out of the crystal. [3]

The yield of the emitted particles is dependent on the position of the detector relative to the crystallographic axes. Therefore, the position of the isotope within the lattice can be determined by taking measurements of electron intensity and comparing them to simulated results. [4] The emission patterns produced are characteristic of the lattice sites occupied by the isotopes, determining its functional properties (i.e. n-type or p-type doping). [5] The benefits of emission chanelling include an increase in efficiency by roughly four orders of magnitude and the study of elements lighter than the host atoms used. [6]

Experimental setup

Interior view of the EC-SLI experimental setup EC-SLI interior.jpg
Interior view of the EC-SLI experimental setup

The experimental setup for the EC-SLI experiment is assembled on an adjustable frame structure with three sections: a beam tube and collimation chamber, experimental, and a vacuum block. It is mounted to the GHM beamline at the ISOLDE facility. [7]

The emission channelling measurements take place in a cylindrical-shaped chamber after the samples are implanted and cooled. Upon flanges inserted along the chamber's perimeter, are auxiliary devices including a cryogenic cooler, Faraday cup, view ports and a load lock. Special format flanges mount electron detector cases, links to the vacuum station, a lightening quartz lamp, the thermal shield actuator feedthrough, and goniometers, at various points around the chamber. Two rigidly aligned collimators connect to a beam transport tube, allowing the ISOLDE ion beams to be optimally transported and focused. [7]

Results

The EC-SLI experiment has been successfully involved in determining the lattice locations of short-lived isotopes in a variety of semiconductor materials. [8] The focus of emission channeling experiments at ISOLDE are investigations into lattice locations of transition metal probes, and p-type doping using short-lived alkaline earth probes or long-lived probes. [6]

A current research aim is to continue the characterisation of quantum colour centres in diamond using the emission channeling technique, in order to correlate lattice locations with optical properties. [9]

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<span class="mw-page-title-main">ISOLDE</span> Physics facility at CERN

The ISOLDE Radioactive Ion Beam Facility, is an on-line isotope separator facility located at the centre of the CERN accelerator complex on the Franco-Swiss border. Created in 1964, the ISOLDE facility started delivering radioactive ion beams (RIBs) to users in 1967. Originally located at the Synchro-Cyclotron (SC) accelerator, the facility has been upgraded several times most notably in 1992 when the whole facility was moved to be connected to CERN's ProtonSynchroton Booster (PSB). ISOLDE is currently the longest-running facility in operation at CERN, with continuous developments of the facility and its experiments keeping ISOLDE at the forefront of science with RIBs. ISOLDE benefits a wide range of physics communities with applications covering nuclear, atomic, molecular and solid-state physics, but also biophysics and astrophysics, as well as high-precision experiments looking for physics beyond the Standard Model. The facility is operated by the ISOLDE Collaboration, comprising CERN and sixteen (mostly) European countries. As of 2019, close to 1,000 experimentalists around the world are coming to ISOLDE to perform typically 50 different experiments per year.

<span class="mw-page-title-main">WITCH experiment</span>

WITCH, or experiment IS433, was a double Penning trap experiment to measure the recoil energy of decaying nuclei. A spectrometer in combination with a position-sensitive microchannel plate detector (MCP) was used to count ions while scanning their energy. The experiment was located at the ISOLDE Radioactive Ion Beam Facility in CERN. The beam from ISOLDE was bunched by REXTRAP after which it was transferred to the WITCH set-up.

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<span class="mw-page-title-main">COLLAPS experiment</span>

The COLinear LAser SPectroscopy (COLLAPS) experiment is located in the ISOLDE facility at CERN. The purpose of the experiment is to investigate ground and isomeric state properties of exotic, short lived nuclei, including spins, electro-magnetic moments and charge radii. The experiment has been operating since the late 1970s, and is the oldest active experiment at ISOLDE.

<span class="mw-page-title-main">CRIS experiment</span>

The Collinear Resonance Ionization Spectroscopy (CRIS) experiment is located in the ISOLDE facility at CERN. The experiment aims to study ground-state properties of exotic nuclei and produce high purity isomeric beams used for decay studies. CRIS does this by using the high resolution technique of fast beam collinear laser spectroscopy, with the high efficiency technique of resonance ionization.

<span class="mw-page-title-main">ISOLDE Decay Station experiment</span>

The ISOLDE Decay Station (IDS) is a permanent experiment located in the ISOLDE facility at CERN. The purpose of the experiment is to measure decay properties of radioactive isotopes using spectroscopy techniques for a variety of applications, including nuclear engineering and astrophysics. The experimental setup has been operational since 2014.

<span class="mw-page-title-main">ISOLTRAP experiment</span>

The high-precision mass spectrometer ISOLTRAP experiment is a permanent experimental setup located at the ISOLDE facility at CERN. The purpose of the experiment is to make precision mass measurements using the time-of-flight (ToF) detection technique. Studying nuclides and probing nuclear structure gives insight into various areas of physics, including astrophysics.

<span class="mw-page-title-main">Miniball experiment</span>

The Miniballexperiment is a gamma-ray spectroscopy setup regularly located in the ISOLDE facility at CERN, along with other locations including GSI, Cologne, PSI and RIKEN (HiCARI). Miniball is a high-resolution germanium detector array, specifically designed to work with low-intensity radioactive ion beams (RIB) post-accelerated by HIE-ISOLDE, to analyse the decays of short-lived nuclei with the capability of Doppler correction. The array has been used for successful Coulomb-excitation and transfer-reaction experiments with exotic RIBs. Results from Miniball experiments have been used to determine and probe nuclear structure.

<span class="mw-page-title-main">MIRACLS experiment</span>

The Multi Ion Reflection Apparatus for CoLlinear Spectroscopy (MIRACLS) is a permanent experiment setup being constructed at the ISOLDE facility at CERN. The purpose of the experiment is to measure properties of exotic radioisotopes, from precise measurements of their hyperfine structure. MIRACLS will use laser spectroscopy for measurements, aiming to increase the sensitivity of the technique by trapping ion bunches in an ion trap.

<span class="mw-page-title-main">SEC experiment</span>

The Scattering Experiments Chamber (SEC) experiment is a permanent experimental setup located in the ISOLDE facility at CERN. The station facilitates diversified reaction experiments, especially for studying low-lying resonances in light atomic nuclei via transfer reactions. SEC does not detect gamma radiation, and therefore is complementary to the ISOLDE Solenoidal Spectrometer (ISS) and Miniball experiments.

<span class="mw-page-title-main">UA9 experiment</span>

The Underground Area 9 (UA9) experiment is a high-energy physics experiment using particle beams from the Super Proton Synchrotron (SPS), at CERN. The purpose of the experiment is to investigate how using tiny bent crystals could allow the collimation of beams in modern hadron colliders to improve. UA9 was approved in 2008, and is in-progress as of 2013.

<span class="mw-page-title-main">VITO experiment</span>

The Versatile Ion polarisation Technique Online (VITO) experiment is a permanent experimental setup located in the ISOLDE facility at CERN, in the form of a beamline. The purpose of the beamline is to perform a wide range of studies using spin-polarised short-lived atomic nuclei. VITO uses circularly-polarised laser light to obtain polarised radioactive beams of different isotopes delivered by ISOLDE. These have already been used for weak-interaction studies, biological investigations, and more recently nuclear structure research. The beamline is located at the site of the former Ultra High Vacuum (UHV) beamline hosting ASPIC.

<span class="mw-page-title-main">WISArD experiment</span> Experimental setup at CERN

The Weak Interaction Studies with 32Ar Decay (WISArD) experiment is a permanent experimental setup located in the ISOLDE facility, at CERN. The purpose of the experiment is to investigate the weak interaction by looking for beta-delayed protons emitted from a nucleus. In the absence of online isotope production during Long Shutdown 2, the experimental setup has also been used to measure the shape of the beta energy spectrum. A goal of the experiment is to search for physics beyond the Standard Model (SM) by expanding the existing limits on currents in the weak interaction.

References

  1. Wahl, Ulrich; Augustyns, Valérie; Correia, João Guilherme; Costa, Ângelo; David Bosne, Eric; Lima, Tiago; Lippertz, Gertjan; Lino, Pereira; Manuel, da Silva; Kritiaan, Temst; Vantomme, André (10 Jan 2017). "Emission channeling with short-lived isotopes (EC-SLI) of acceptor dopants in nitride semiconductors". ISOLDE and Neutron Time-of-Flight Experiments Committee.
  2. Hofsäss, Hans; Lindner, Gerhard (1991-03-01). "Emission channeling and blocking". Physics Reports. 201 (3): 121–183. doi:10.1016/0370-1573(91)90121-2. ISSN   0370-1573.
  3. Langouche, G.; Soares, J. C.; Stoquert, J. P. (1992-04-01). Nuclear Methods in Semiconductor Physics. Elsevier. ISBN   978-0-444-59681-9.
  4. O'Donnell, Kevin Peter; Dierolf, Volkmar (2010). Rare earth doped III-nitrides for optoelectronic and spintronic applications. Topics in applied physics. Dordrecht, the Netherlands New York Bristol, UK: Springer in association with Canopus Academic Pub. ISBN   978-90-481-2877-8.
  5. "EC-SLI | ISOLDE". isolde.cern. Retrieved 2023-07-18.
  6. 1 2 Wahl, U.; Correia, J. G.; Costa, A.; David-Bosne, E. (6 December 2013). "Emission Channeling with Short-Lived Isotopes (EC-SLI) at CERN's ISOLDE facility" (PDF). Proceedings of the First International African Symposium on Exotic Nuclei (IASEN 2013).
  7. 1 2 Silva, M. R.; Wahl, U.; Correia, J. G.; Amorim, L. M.; Pereira, L. M. C. (18 July 2013). "A versatile apparatus for on-line emission channeling experiments". Rev Sci Instrum. 84 (7). doi:10.1063/1.4813266. PMID   23902062.
  8. Wahl, U.; Correia, J. G.; Decoster, S.; Pereira, L.; Marques, C. P.; Amorim, L.; da Silva, M.R. "Recent results from electron emission channeling on-line experiments" (PDF). Retrieved 18 July 2023.
  9. Pereira, L. M. C.; Wahl, U.; Correia, J. G.; Biesmans, B.; Costa, A. R. G.; da Silva, M. R.; David Bosne, E.; Lamelas, A.; Magchiels, G.; Moens, J.; Tunhuma, S. M.; Villarreal, R.; Vantomme, A. (10 Jan 2023). "Quantum colour centers in diamond studied by emission channeling with short-lived isotopes (EC-SLI) and radiotracer photoluminescence" (PDF). Addendum to IS668 to the ISOLDE and Neutron Time-of-Flight Committee.
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