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Statick

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Title: Statick


1
  • Statické momenty jader metody jejich merení

2
Merení statických momentu jader
  • Static moments of nuclei are measured via
    interaction of the nuclear charge distribution
    and magnetism with electromagnetic fields in its
    immediate surroundings. This can be the
    electromagnetic fields induced by the atomic
    electrons or the fields induced by the bulk
    electrons and first neighboring nuclei for nuclei
    implanted in a crystal, usually in combination
    with an external magnetic field.

3
Atomic hyperfine structure
  • Not only the radial distribution of the nuclear
    charge (monopole moment) but also the higher
    multipole electromagnetic moments of nuclei with
    a spin I ? 0 influence the atomic energy levels.
    By interacting with the multipole fields of the
    shell electrons they cause an additional
    splitting called hyperfine structure. For all
    practical purposes it is sufficient to consider
    only the magnetic dipole and the electric
    quadrupole interaction of the nucleus with the
    shell electrons.
  • The shell electrons in states with a total
    angular momentum J ? 0 produce a magnetic field
    at the site of the nucleus. This gives a dipole
    interaction energy E -µ B. The spectroscopic
    quadrupole moment of a nucleus with I 1
    interacts with an electric field gradient
    produced by the shell electrons in a state with J
    1 according to E eQ (?2V/?z2).

4
Externally applied EM fields
  • When a nucleus with spin I is implanted into a
    solid (or liquid) material, the interaction
    between the nuclear spin and its environment is
    no longer governed by the atomic electrons. For
    an atom imbedded in a dense medium, the
    interaction of the atomic nucleus with the
    electromagnetic fields induced by the medium is
    much stronger than the interaction with its
    atomic electrons.
  • The lattice structure of the medium now plays a
    determining role. This hyperfine interaction is
    observed in the response of the nuclear spin
    system to the internal electromagnetic fields of
    the medium, often in combination with externally
    applied (static or radio-frequency) magnetic
    fields.

5
Interakce jádra s vnejšími aplikovanými poli
  • Experimental techniques based on measuring the
    angular distribution of the radioactive decay are
    often more sensitive than the atomic HF methods,
    and in some cases also allow more precise
    measurements of the nuclear g factor and
    quadrupole moment. This angular distribution is
    influenced by the interaction of the nuclear
    moments with externally applied magnetic fields
    and/or electric field gradients after
    implantation into a crystal
  • The radioactive decay intensity is measured as a
    function of time (TDPAD) or as a function of an
    external variable, e.g., a static magnetic field
    or the frequency of an applied radio-frequency
    magnetic field (b-NMR). The former are called
    time differential measurements and the latter
    time integrated measurements.

6
Metody
  • Mößbaueruv jev
  • Omezeno jen na izotopy a hladiny meritelné pomocí
    Mossbauera
  • PAC (Time-Differential Perturbed Angular
    Distribution - TDPAD)
  • NMR
  • ß-NMR pro hladiny s krátkou dobou života
  • Nízkoteplotní orientace
  • Velikost hyperjemného pole nezávisí pro daný
    prvek na izotopu
  • Lze zmerit pole pomocí jednoho izotopu a pak
    merit momenty u dalších izotopu

7
TDPAD
  • Spin-oriented isomeric states implanted into a
    suitable host will exhibit a non-isotropic
    angular distribution pattern, provided the
    isomeric ensemble orientation is maintained
    during its lifetime. If an electric field
    gradient (EFG) is present at the implantation
    site of the nucleus, the nuclear quadrupole
    interaction will reduce the spin orientation and
    thus the measured anisotropy.
  • If the implantation host is placed into a strong
    static magnetic field (order of 0.11 Tesla), the
    anisotropy is maintained. If the field is applied
    parallel to the symmetry axis of the spin
    orientation, the reaction-induced spin
    orientation can be measured.
  • If a static magnetic field is placed
    perpendicular to the axial symmetry axis of the
    spin orientation, the Larmor precession of the
    isomeric spins in the applied field can be
    observed as a function of time 93, provided
    that the precession period is of the same order
    as the isomeric lifetime (or shorter).
  • Can also be used to measure the quadrupole
    moments of these isomeric states, by implantation
    into a single crystal or a polycrystalline
    material with a non-cubic lattice structure
    providing a static electric field gradient.

8
Príklady
  • TDPAD spectra for the ?-decay of the Ip 29/2-,
    t1/2 9 ns isomeric rotational bandhead in
    193Pb, implanted respectively in a lead foil to
    measure its magnetic interaction (MI) and in
    cooled polycrystalline mercury to measure its
    quadrupole interaction (QI).
  • Detectors are placed in a plane perpendicular to
    the magnetic field direction (? 90?) and at
    nearly 90 ? with respect to each other (f1 f2
    90), the R(t) function in which the Larmor
    precession is reflected, is given by

9
Príklady
  • R(t) curves obtained in the study of g-factors of
    Ip 9/2 isomers in neutron-rich isotopes of
    nickel and iron. The isomers, with lifetimes of
    13.3 µs and 250 ns, respectively, have been
    produced in a projectile fragmentation reaction
    at the LISE high-resolution in-flight separator
    at GANIL.

10
ß-NMR
  • Time-differential measurements are only suited
    for short-lived nuclear states, mainly because of
    relaxation effects causing a dephasing of the
    Larmor precession frequencies with time
    (typically in less than 100 µs). To measure
    nuclear moments of longer-lived isomeric states
    and also for ground states, a time-integrated
    measurement is required. Time integration of
    R(t), taking into account the nuclear decay time,
    will lead to a constant anisotropy.
  • Therefore, a time-integrated measurement of the
    angular distribution of this system will not
    allow one to deduce information on the nuclear
    moments. Hence a second interaction, which breaks
    the axial symmetry of the Hamiltonian, needs to
    be added to the system.
  • One possibility to introduce a symmetry breaking
    in the system, is by adding a radio-frequency
    (rf) magnetic field perpendicular to the static
    magnetic field (and to the spin-orientation
    axis).
  • If the nuclei are implanted into a crystal with a
    cubic lattice symmetry or with a noncubic crystal
    structure inducing an electric field gradient,
    respectively, one can deduce the nuclear g-factor
    or the quadrupole moment from the resonances
    induced by the applied rf field between the
    nuclear hyperfine levels.

11
ß-NMR
  • Consider an ensemble of nuclei submitted to a
    static magnetic field B0 and
  • an rf magnetic field with frequency ? and rf
    field strength B1. If the applied rf frequency
    matches the Larmor frequency the orientation of
    an initially spin-oriented ensemble will be
    resonantly destroyed by the rf field. For
    ß-decaying nuclei that are initially polarized,
    this resonant destruction of the polarization can
    be measured via the change in the asymmetry of
    the ß-decay.
  • For an ensemble of nuclei with the polarization
    axis parallel to the static field direction, the
    angular distribution for allowed ß-decay can be
    written as
  • with the NMR perturbation factor G1011 describing
    the NMR as a function of the rf frequency or as a
    function of the static field strength. At
    resonance, the initial asymmetry is fully
    destroyed if sufficient rf power is applied,
    which corresponds to G1011 0. Out of resonance
    we observe the full initial asymmetry and G1011
    1.

12
ß-NMR
  • All forms of magnetic resonance require
    generation of nuclear spin polarization out of
    equilibrium followed by a detection of how that
    polarization evolves in time.
  • In conventional NMR a relatively small nuclear
    polarization is generated by applying a large
    magnetic field after which it is tilted with a
    small RF magnetic field. An inductive pickup coil
    is used to detect the resulting precession of the
    nuclear magnetization. Typically one needs about
    1018 nuclear spins to generate a good NMR signal
    with stable nuclei. Consequently conventional NMR
    is mostly a bulk probe of matter. On the other
    hand, in related nuclear methods such as muon
    spin rotation (µSR) or ß-detected NMR (ß-NMR) a
    beam of highly polarized radioactive nuclei (or
    muons) is generated and then implanted into the
    material. The polarization tends to be much
    higher between 10 and 100. Most importantly,
    the time evolution of the spin polarization is
    monitored through the anisotropic decay
    properties of the nucleus or muon which requires
    about 10 orders of magnitude fewer spins. For
    this reason nuclear methods are well suited to
    studies of dilute impurities, small structures or
    interfaces where there are few nuclear spins.

13
Príklad
  • NMR curve for 11Be implanted in metallic Be at T
    50K. At this temperature the spin-lattice
    relaxation time T1 is of the order of the nuclear
    lifetime t 20 s.

14
Príklad
  • Nuclear magnetic resonances for 8Li (I 2)
    implanted into different non-cubic crystals. This
    illustrates the influence of the implantation
    host on the quadrupole frequency as well as on
    the resonance line widths. The nuclear level
    splitting for a nucleus with spin I 2,
    submitted to a magnetic field and an EFG, and the
    corresponding transition frequencies are shown
    for one- and two-photon transitions. The five
    levels are non-equidistant, resulting in four
    equidistant one-photon resonances in the NMR
    spectrum

15
ß-NMR
  • At radioactive ion beam facilities such as ISOLDE
    and ISAC it is possible to generate intense
    (gt108/s) highly polarized (80) beams of low
    energy radioactive nuclei.
  • Furthermore one has the added possibility to
    control the depth of implantation on an
    interesting length scale (6400 nm).
  • Although in principle any beta emitting isotope
    can be studied with ß-NMR the number of isotopes
    suitable for use as a probe in condensed matter
    is much smaller. The most essential requirements
    are
  • (1) a high production efficiency
  • (2) a method to efficiently polarize the nuclear
    spins and
  • (3) a high ß decay asymmetry.
  • Other desirable features are
  • (4) small Z to reduce radiation damage on
    implantation,
  • (5) a small value of spin so that the ß-NMR
    spectra are relatively simple and
  • (6) a radioactive lifetime that is not much
    longer than a few seconds.

16
Isotope Spin Quadrupole moment (mb) T1/2 (s) ? (MHz/T) beta-Decay asymmetry (A) production rate (s-1)
µ 1/2 2.2x10-6 135.5 0.33 75
8Li 2 32 0.842 6.3018 0.33 108
11Be 1/2 13.8 22 0.33 107
15O 1/2 122 10.8 .7 108
17Ne 1/2 0.1 .33 106
  • Table gives a short list of the isotopes we have
    identified as suitable for development at ISAC.
    Production rates of 106/s are easily obtainable
    at ISAC. 8Li is the easiest to polarize and
    therefore was selected as the first one to
    develop as a probe at ISAC

17
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19
LMR
  • Another possibility to NMR is Beta-Ray Detected
    Level Mixing Resonance (b-LMR)
  • Here, the axial symmetry is broken via combining
    a quadrupole and a dipole interaction with their
    symmetry axes non-collinear. This gives rise to
    resonant changes in the angular distribution at
    the magnetic field values where the nuclear
    hyperfine levels are mixing.
  • The resonances observed in a LMR experiment are
    not induced by the interaction with a rf field,
    but by misaligning the magnetic dipole and
    electric quadrupole interactions. This
    experimental technique does not need an
    additional rf field to induce changes of the spin
    orientation. The change of the spin orientation
    is induced by the quantum mechanical
    anti-crossing or mixing of levels, which occurs
    in quantum ensembles where the axial symmetry is
    broken.

20
  • Nuclear HF levels of a nucleus with spin I 3/2
    submitted to a combined static magnetic
    interaction and an axially symmetric quadrupole
    interaction
  • (a) for collinear interactions, ß 0?
  • (b) and (c) for non-collinear interactions with ß
    5? and ß 20?, respectively.
  • Crossing or mixing of hyperfine levels occurs at
    well-defined values for the ratio of the involved
    interactions frequencies, if
  • (d) At these positions, resonances are observed
    in the decay angular distribution of oriented
    radioactive nuclei, from which the nuclear spin
    and moments can be deduced

21
Atomic hyperfine structure
  • For a particular atomic level characterized by
    the angular momentum J, the coupling with the
    nuclear spin I gives a new total angular momentum
    F, F I J, I - J F I J. The HF
    interaction removes the degeneracy of the
    different F levels and produces a splitting into
    2J 1 or 2I1 hyperfine structure levels for J lt
    I and J gt I, respectively.
  • Example of the atomic fine and hyperfine
    structure of 8Li. For free atoms the electron
    angular momentum J couples to the nuclear spin I,
    giving rise to the HF structure levels F. The
    atomic transitions between the 2S1/2 ground state
    to the first excited 2P states of the Li atom are
    called the D1 and D2 lines

22
  • Using vector coupling rules the HF structure
    energies of all F levels
  • The determination of nuclear moments from
    hyperfine structure is particularly appropriate
    for radioactive isotopes, because the electronic
    parts Be(0) and Vzz(0) are usually known from
    independent measurements of moments and hyperfine
    structure on the stable isotope(s) of the same
    element.

23
Optical pumping
  • Polarization of a fast beam by optical pumping
    was introduced for the ß-asymmetry detection of
    optical resonance in collinear laser
    spectroscopy.
  • Most applications took advantage of the
    additional option to perform nuclear magnetic
    resonance spectroscopy with ß-asymmetry detection
    (ß-NMR) on a sample obtained by implantation of
    the polarized beam into a suitable crystal
    lattice. Whatever is the particular goal of such
    an experiment, it is important to achieve a high
    degree of nuclear polarization.
  • Repeated absorption and spontaneous emission of
    photons results in an accumulation of the atoms
    in one of the extreme MF states for which the
    total angular momentum F J I, for an S state
    just composed of the electron spin and the
    nuclear spin, is polarized.
  • Optical pumping within the hyperfine structure
    Zeeman levels for polarization of the nuclear
    spin. The example shows the case of I 1 for the
    case of 28Na

24
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25
Optical pumping
  • If a weak magnetic field defines the quantization
    axis in the direction of the atomic and the laser
    beam, each absorption of a circularly polarized
    photon introduces one unit of angular momentum in
    the atomic system. This can be expressed by the
    selection rule ?MF 1 for s light, with s and
    s- being the conventional notations for the
    circular polarization of the light with respect
    to the direction of the magnetic field.
  • Repeated absorption and spontaneous emission of
    photons results in an accumulation of the atoms
    in one of the extreme MF states for which the
    total angular momentum F J I, for an S state
    just composed of the electron spin and the
    nuclear spin, is polarized.

26
Collinear Laser Spectroscopy
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28
Merení rozmeru (polomeru) atomových jader
29
Measurement of nuclear radius
  • Distribution of charge can not be the same as
    distribution of matter
  • Four methods outlined for charge matter radius
  • Diffraction (electron) scattering (form factor)
  • Atomic x-rays
  • Muonic x-rays
  • Mirror Nuclides
  • Three methods outlined for nuclear matter radius
  • Rutherford scattering (via strong interaction)
  • Alpha particle decay
  • ?-mesic x-rays
  • (cross section of fast neutrons)

30
Diffraction scattering
q momentum transfer
  • Measure the scattering intensity as a function
    of ? to infer the distribution of charge in the
    nucleus,

31
Diffraction scattering
.
  • Density of electric charge in the nucleus is
    almost constant
  • The charge distribution does not have a sharp
    boundary
  • Edge of nucleus is diffuse - skin
  • Depth of the skin 2.3 fm
  • RMS radius is calculated from the charge
    distribution and, neglecting the skin, it can be
    shown

Modulus squared of charge form factors (a)
calculated by solving the Dirac equation with
HFBCS proton densities (b)
32
Atomic X-rays
  • Assume the nucleus is uniform charged sphere.
  • Potential V is obtained in two regions
  • Inside the sphere
  • Outside the sphere
  • For an electron in a given state, its energy
    depends on
  • Assume does not change appreciably if Vpt?
    Vsphere
  • Then, ?E Esphere - Ept
  • Assume can be
  • ?E between sphere and point nucleus for
  • Compare this ?E to measurement and we have R.

33
Atomic X-rays
  • In reality, we will need two measurements to get
    R
  • Consider a 2p ?1s transition for (Z,A) and (Z,A)
    where
  • A (A-1) or (A1) what x-ray does this
    give?
  • Assume that the first term will be 0 larger
    radius (smaller influence)
  • Then, use ?E1s from previous slide for each E1s
    term
  • This x-ray energy difference is called the
    isotope shift
  • One can use optical transitions instead of x-ray
    transitions

34
Use for short-lived nuclei
  • Let A, A and mA, mA be the mass numbers and
    atomic masses of the isotopes involved. Then for
    an atomic transition i the isotope shift, i.e.
    the difference between the optical transition
    frequencies of both isotopes, is given by
  • This means that both the field shift (first term)
    and the mass shift (second term) are factorized
    into an electronic and a nuclear part. The
    knowledge of the electronic factors Fi (field
    shift constant) and Mi (mass shift constant)
    allows one to extract the quantity dr2 of the
    nuclear charge distribution. These atomic
    parameters have to be calculated theoretically or
    semi-empirically.
  • For unstable isotopes high-resolution optical
    spectroscopy is a unique approach to get precise
    information on the nuclear charge radii, because
    it is sensitive enough to be performed on the
    minute quantities of (short-lived) radioactive
    atoms produced at accelerator facilities.
  • Other techniques are suitable only for stable
    isotopes of which massive targets are available.

35
Use for short-lived nuclei
  • Elastic electron scattering even gives details of
    the charge distribution, and X-ray spectroscopy
    on muonic atoms is dealing with systems for which
    the absolute shifts with respect to a point
    nucleus can be calculated. Thus both methods give
    absolute values of r2 and not only differences.
    Eventually, the combination of absolute radii for
    stable isotopes and differences of radii for
    radioactive isotopes provides absolute radii for
    nuclei all over the range that is accessible to
    optical spectroscopy.

36
Muonic X-rays
  • Similar to standard X-rays measurement
  • Muons are heavier than electrons (106 MeV x 511
    keV) which causes the difference in the radius
    and energy (energy difference)

Prompt X-ray spectra from deuteron The curves
are the results of the fitting and the
components of pµ X-rays and dµ X-rays are also
shown respectively.
37
Coulomb Energy Differences
  • Coulomb energy of the charge distribution
  • Consider mirror nuclides
  • Can be determined from the b-decay of mirror
    nuclides (from maximum electron/positron energy)
    the only difference in mirror nuclides is
    expected due to the Coulomb energy
  • Change in the Coulomb energy can be expected to
    depend as A2/3 (from A/R)

38
Coulomb Energy Differences
Maximum energy of b-ray spectrum (MeV)
  • From experimental evidence analyzing mirror
    nuclei, we know that nuclear forces are
    symmetrical in neutrons and protons and that
    nuclear binding between two neutrons is the same
    as that between two protons.
  • In the figure the fact that the experimental
    values tend to lie on a straight line indicates
    that these nuclei have coulomb energy which
    correspond to a constant-density model RCR0A1/3
  • Dotted lines for R01.4 and 1.610-13 cm clearly
    constitute an interval for the Coulomb-energy
    unit radius.

A2/3
39
Measurement of nuclear radius
  • Distribution of charge can not be the same as
    distribution of matter
  • Four methods outlined for charge matter radius
  • Diffraction scattering (form factor)
  • Atomic x-rays
  • Muonic x-rays
  • Mirror Nuclides
  • Three methods outlined for nuclear matter radius
  • Rutherford scattering
  • Alpha particle decay
  • ?-mesic x-rays
  • (cross section of fast neutrons)

40
a-decay lifetime
  • The penetration of a depends very critically on
    the shape and the height of the of the potential
    energy barrier and on the kinetic energy of a
    after penetration. The height of the barrier is
    given by the nuclear radius, since the particle
    is under the influence of the Colomb repulsion
    without any compensating nuclear attraction when
    its distance from the center is larger than R.
    The probability of penetration is closely
    connected with the decay lifetime.
  • In principle, the theory of a-decay allows
    determination of the nuclear radius R from the
    decay lifetime and energy of a particle.

Example of influence of the radius on lifetime
simple calculations
41
Cross section of fast neutrons
  • In principle could be used, in reality it is
    rather problematic
  • According to the elemental theory of scattering
    (QM) the total cross section of a particle s
    sel sreaction 2p(R l)2 ,where l is an
    uncertainty in the position of the incident
    particle (probably equivalent to the
    wavelength of the the particle)
  • In the case of fast neutrons, l is very small and
    there is no Coulomb interaction

42
Merení hmot jader
43
  • Quantities which can be measured
  • Maximum energy of a decay (Q-value) (n,g), b
    decay
  • Frequency measurement determination of q/m
  • storage rings
  • mass spectrometer (ISOLTRAP) ISOL isotope
    separator on line
  • For mass measurements on radioactive nuclides,
    the two worlds most prominent instruments today,
    both in terms of the final mass uncertainty
    reached and its sensitivity and the number of
    measurements performed, are the
  • experimental storage ring (ESR) at GSI
    (Darmstadt) and
  • Penning trap mass spectrometer ISOLTRAP at
    ISOLDE/CERN.

Based on H.-J. Kluge et al. / Nuclear
Instruments and Methods in Physics Research A 532
(2004) 4855 Klaus Blaum / Physics Reports 425
(2006) 1-78
44
ESR
  • At the ESR, two new, complementary techniques,
    Schottky-Mass-Spectrometry (SMS) and
    Isochronous-Mass-Spectrometry (IMS), have been
    developed during the last years and were used in
    several experimental runs for mapping large areas
    of the nuclidic mass surface.
  • The target is located at the entrance of the
    FRagment Separator (FRS), a magnetic high
    resolution spectrometer. Depending on the
    operation mode, the FRS can provide cocktail
    beams (a mixture of nuclei, which are
    characterized by similar mass-to-charge ratio) or
    monoisotopic beams. At relativistic velocities
    the reaction products leave the production target
    as highly-charged ions and mainly bare ions
    occur. The ions are injected as a bunch of about
    400 ns pulse length into the ESR. After
    injection, the ESR is used as high-resolution
    mass analyzer, and the masses are determined from
    the precise measurement of their revolution
    frequencies.
  • For an unambiguous relation between frequency and
    mass, the second (velocity dependent) term on the
    rhs of the equation on next slide must be
    canceled and two methods apply. For SMS, the ESR
    is operated with gt 2.4, electron cooling is
    applied so that Dv/v ? 0 and the revolution
    frequency is determined from a Schottky-noise
    analysis. For IMS, the ESR is operated in the
    isochronous mode at gt 1.4 Ions are injected
    with a suitable velocity so that their Lorentz
    factor g gt and their revolution frequency is
    determined from their time-of-flight (TOF) for
    each turn.

45
ESR
  • When relativistic ions (from heavy ion
    synchrotron - SIS), accelerated to almost the
    velocity of light, collide with a thick target, a
    broad spectrum of nuclei with mass and charge
    numbers below those of the projectile nucleus fly
    onward, close to the velocity of the primary
    beam. An exotic nucleus can be separated from
    this mixture almost free of background. This is
    accomplished by deflecting the ions in
    electromagnetic fields and, in addition, slowing
    them down in thick layers of matter. This is the
    basic principle of the FRS fragment separator at
    GSI.

46
FRSESR mass measurements
  • Schematic view of the principle of mass
    measurement in the ESR. The motion of up to four
    different species labeled by (m/q)1...4, is
    indicated. For SMS (left) ions are cooled and
    have the same mean velocity v whereas for IMS
    (right) the ions are hot and have different
    velocities. gt is an ion-optical parameter, which
    characterizes the transition point of the ESR

47
Detection in IMS
  • In the IMS mode of the storage ring the
    revolution times of each individual stored ion
    are measured by a destructive time-of-flight
    technique. To this end the ions cross a very
    thin, metallized carbon foil, being typically a
    few g.cm-2 thick, mounted in the ring aperture,
    and eject at each passage -electrons which are
    guided by electric and magnetic fields to a
    suitable detector. In this way, every ion
    produces periodically at each passage a
    time-stamp. With a proper data analysis software
    the fast-sampled sum signal can be assigned to
    individual ions and their mass can be determined
    via the measured time of flight. Due to energy
    loses in the foil only a few hundred to a few
    thousand turns can be observed for one and the
    same ion.

48
Detection in SMS
  • The SMS method in a storage ring is based on the
    detection of image charges and provides, as in
    the case of a Penning trap, single-ion
    sensitivity. The revolution frequency of the
    highly charged ions is determined from a
    Schottky-noise analysis, i.e., at each turn the
    induced mirror charges of the circulating ions on
    two electrostatic pick-up electrodes is
    monitored. Typically the 3034th harmonics of the
    signals are picked up by a resonant circuit. The
    signals of both pick-up plates are amplified with
    low-noise amplifiers and then summed. The Fourier
    transformed signal delivers the frequency and
    thus the mass spectrum. At a charge state of q
    30 the detection sensitivity is high enough to
    detect single ions.

49
FRSESR mass measurements
  • In the ESR. After cooling, the nuclides are
    sorted according to their mass-to-charge
    ratio in the spectrum (increasing mass-to-charge
    ratio with decreasing revolution frequency). The
    nuclides with known masses (indicated by full
    letters in the Fig. on next slide) are used as
    calibrants of the spectrum and thus the so far
    unknown masses can be obtained. The inset shows
    that low-lying isomeric states can be resolved
    and that the measurement reaches ultimate
    sensitivity, i.e., even single ions can be
    detected and their mass can be determined with a
    precision in the order of 50 keV. This is ideally
    adapted to the requirements of an experiment with
    exotic nuclei, which are produced in tiniest
    amounts, some of them with rates of the order of
    a few ions per day.
  • Neutron deficient nuclei were produced by bismuth
    fragmentation.
  • Neutron-rich nuclei are of special interest.
    These neutron-rich nuclei can be produced at the
    FRS by fission of high-energy uranium
    projectiles. IMS is used, which has the potential
    to investigate nuclides with half-lives down to
    the microsecond range because no cooling is
    required.

50
FRSESR mass measurements
  • Frequency spectrum of cooled exotic nuclei. The
    inset, which shows ground and isomeric excited
    state of fully stripped 143Sm, demonstrates the
    ultimate sensitivity of SMS to detect single ions.

51
FRSESR mass measurements
  • The performance of SMS depends strongly on the
    features of electron cooling. Thus, a large
    cooling force is desired, but a high electron
    current causes rapid beam loss due to charge
    exchange by the capture of electrons from the
    electron cooler.
  • Mass precission about 35 keV
  • With IMS, where no cooling is required at all.
    There, the ions make only a few thousand
    revolutions before they are lost due to the
    energy loss in the foil of the TOF-detector
  • Mass precision of typically 100 keV is achieved

52
The ISOLTRAP experiment
  • ISOLTRAP is a triple trap mass spectrometer
    connected to the on-line mass separator ISOLDE.
    There, the radionuclides are produced by
    bombarding a thick target with 1.4 GeV proton.
    The produced nuclides diffuse out of the target
    and are ionized either by surface, plasma or
    resonant laser ionization. The 60 keV ion beam is
    mass separated in a magnetic spectrometer with a
    resolving power of up to 8000 and delivered to
    different experiments.
  • ISOLTRAP measures the mass m via the
    determination of the cyclotron frequency nc
    (1/2p)(q/m)B of ions with charge q stored in a
    homogeneous and stable magnetic field B. The main
    components of the ISOLTRAP setup are shown in the
    Fig. on next page. It consists of three traps
    that perform specific tasks (i) the
    radiofrequency quadrupole (RFQ) used as a beam
    conditioning trap in which the 60-keV ISOLDE beam
    is decelerated, cooled, and bunched to adapt the
    beam to the requirements of ISOLTRAP with respect
    to its time structure and emittance (ii) the
    preparation Penning trap, in which contaminant
    ions are removed by a mass-selective buffer gas
    cooling technique and (iii) the precision
    Penning trap for the actual mass measurement.
  • A stable alkali reference ion source located
    upstream of the RFQ trap allows testing and
    preparation of the complete setup before
    radioactive-beam experiments.

53
The ISOLTRAP experiment
  • Sketch of the triple trap mass spectrometer
    ISOLTRAP at ISOLDE/CERN. Micro-channel plate
    (MCP) detectors are used to monitor the ion
    transfer as well as to record the TOF resonance
    (MCP5) for the determination of the cyclotron
    frequency. The inset shows the cyclotron
    resonance of 33Ar with the fit of a
    theoretically expected curve

54
Penning trap
  • An ideal Penning trap consists of a strong
    homogenous magnetic field and a weak quadrupolar
    electrostatic potential.
  • As a Paul trap, a Penning trap also consists of
    ring and endcap electrodes. Quite often so-called
    guard or correction electrodes are placed between
    endcaps and the ring to compensate for the
    truncation of the hyperbolical electrodes.
  • Two types of geometry configurations are commonly
    used hyperbolic and cylindrical. Both constructs
    have their own benefits although in precision
    experiments usually hyperbolical are favored due
    to better production of quadrupolar electric
    field. On the other hand, cylindrical electrodes
    are easier to manufacture and sometimes more open
    geometry offer other benefits such as better
    conductance of gas.

In contrast to a Paul trap, full confinement is
achieved with static trapping fields (R 1cm).
55
Paul trap
  • In a Paul trap the trapping effect is achieved
    solely with electric fields. They consist of a
    ring electrode and two endcap electrodes that in
    ideal case are hyperboles of revolution.
    Confinement of ions is achieved by using both DC
    and AC electric fields. Motion of ions is
    described with Mathieu equations which in short
    describes the suitable combinations of frequency
    and amplitude of the electric field for storing
    ions with certain m/q ratio.

Radio-frequency Paul trap consisting of two end
caps and a ring electrode. (a) Cutaway view
(after G. Kamas, ed., Time and Frequency Users's
Manual, National Bureau of Standards Technical
Note 695, 1977). (b) Cross section, showing the
amplitude of the instantaneous oscillations for
several locations in the trap.
56
Paul trap
From http//mathworld.wolfram.com
  • In nuclear physics Paul traps are used mainly for
    storing and cooling ions. Some trap structures
    are prepared so that the center of the trap is
    exposed for example for lasers and particle
    detectors.

57
Penning trap
For the storage of charged particles in a Penning
trap a strong homogeneous magnetic field B for
radial confinement and a weak static electric
field for axial trapping are superposed. The
latter is created by a voltage U0 (or Udc)
applied between the ring electrode and the two
end electrodes.
  • An ion with a charge-to-mass ratio q/m stored in
    a pure magnetic field B B(z) in the
    z-direction and with a velocity component v
    perpendicular to the direction of the magnetic
    field will experience a Lorentz force FL qv
    B. This force confines the charged particle in
    the radial direction and the ion performs a
    circular motion with angular frequency wc
    (q/m)B.
  • Since there is no binding in the direction of the
    magnetic field lines, i.e. in the axial
    direction, a three-dimensional confinement is
    obtained in the Penning trap by superposing a
    weak static electric quadrupole potential F(z,
    r) (U0/2d2)(z2 - r2/2) given in cylindrical
    coordinates.

58
Penning trap
For an ideal electric quadrupole field there are
three eigenfrequencies of the ion motion
In order that the motion be bounded, the roots in
Eqs. must be real, leading to the trapping
condition
  • Schematic trajectory (three-dimensional and
    projection onto the xy-plane) with ideally three
    independent eigenmotions of an ion in a Penning
    trap a harmonic oscillation in the axial
    direction (axial motion with frequency wz), and
    a radial motion that is a superposition of the
    modified cyclotron motion with frequency w and
    the magnetron motion with frequency w-

59
Cooling of ions in the RFQ trap
  • The operating principle of a linear RFQ is based
    on the radial confinement of ions in the
    quadrupolar field of a four-rod structure. The
    time-averaged radial centering force can be
    described as a harmonic pseudo-potential well.
    The ISOLTRAP RFQ is in addition filled with He as
    buffer gas, thus ions are not only radially
    confined but also cooled by collisions with
    buffer gas atoms, and the four rods are 26-fold
    segmented and an axial DC potential is applied in
    order to allow the accumulation of a number of
    ions in cooled bunches.
  • The total length of the RFQ is about 1m and the
    trap is operated at gas pressures of about 1 Pa,
    at a radiofrequency of typically 1 MHz, and at
    peak-to-peak RF amplitudes of up to 250 V,
    depending on the ion mass. After an accumulation
    period of about 510 ms the ions are ejected
    towards the preparation trap through a pulsed
    drift tube in which their energy is adapted to
    ground potential.

Left Radiofrequency quadrupole mass filter
electrodes having hyperbolic cross-section.
Right Equipotential lines for a quadrupole field
generated with the electrode structure shown left.
electrodes of a linear paul trap (RFQ)
60
Cooling in a Penning trap
  • In ISOLTRAPs preparation Penning trap a
    combination of He buffer gas collisions and
    application of a resonant azimuthal quadrupole
    radiofrequency excitation at the true cyclotron
    frequency nc is used. Both, cyclotron and axial
    oscillations are damped by buffer gas collisions.
    Due to the potential energy loss by collisions
    with the buffer gas atoms the magnetron radius
    increases. A mass selective recentering of the
    ions by a radiofrequency field that couples the
    modified cyclotron and the magnetron motion
    avoids ion loses.
  • This mass selective technique allows ions to be
    cooled to a temperature equivalent to that of the
    buffer gas and to eliminate at the same time
    contaminant ions of other masses present in the
    trap. Using this technique, a mass resolving
    power of 105 could be demonstrated with 100 ms
    cooling time.

61
Mass determination in Penning trap
  • Two methods are used for measuring cyclotron
    frequencies in high-accuracy mass spectrometry
    with ion traps
  • manipulation of the ion motion by radiofrequency
    fields and measurement of the time of flight
    (TOF) of the ions from the ion trap after
    ejection to an ion detector placed outside the
    magnetic field and
  • broad-/ narrow-band observation of the
    oscillating image currents induced by the motion
    of the ion in the trap electrodes (detection by
    image charges).

62
TOF measurement in a Penning trap
  • The ions cyclotron frequency nc is probed by
    excitation of the ions motion by a radiofrequency
    signal and measurement of the TOF to the
    micro-channel-plate (MCP) detector. The cyclotron
    resonance is determined by repetition of this
    sequence and measurement of the TOF as a function
    of the frequency of the applied signal. The value
    of the magnetic field B is measured by a
    determination of the cyclotron frequency of a
    reference ion with well-known mass both before
    and after the measurements of the cyclotron
    frequency of the ion of interest.

An example for 33Ar is shown. A fit of the
resonance curve to the theoretical function
yields the cyclotron frequency nc.
63
TOF measurement in a Penning trap from
different paper
  • In the time-of-flight ioncyclotron resonance
    (TOF-ICR) detection technique the ions are first
    prepared at a well-defined radius of the
    magnetron motion. Here, the orbital frequency
    and, therefore, the orbital magnetic moment m as
    well as the associated energy E m.B , are
    small. By application of a resonant quadrupolar
    excitation, with an appropriate choice of
    amplitude and excitation time, the magnetron
    motion is completely converted into the
    (modified) cyclotron motion while the radial
    radius remains constant.
  • When the ions are ejected from the trap after one
    full conversion (by lowering the trapping
    potential of the downstream end electrode) at
    initially low axial velocity they drift along the
    axis out of the magnetic field. In passing
    through the magnetic field gradient the ions get
    accelerated due to the gradient force and thus
    the axial velocity of the ions increases.
  • In each of several experimental cycles, different
    excitation frequencies are applied. Since the
    magnetic moment and the radial energy of the ions
    are larger in resonance due to the higher
    frequency of the cyclotron motion as compared to
    the magnetron frequency, the resonantly excited
    ions arrive earlier at the detector than those
    ions that have been excited non-resonantly.
  • A variation of the quadrupole frequency rf
    results in a characteristic time-of-flight
    cyclotron resonance curve. The theoretically
    expected line shape for such a resonance is
    mainly determined by the Fourier transformation
    of the rectangular time excitation profile and is
    similar to the absolute value of the so called
    sinc(x)-function f(x)sin(ax)/(ax).

64
Image charges detection
  • With the detection of the image charges a full
    resonance spectrum after one experimental cycle
    can be obtained instead of repeated probing of
    the expected cyclotron frequency.
  • The signal of the charged particle stored in a
    Penning trap is picked up by means of an attached
    narrow-band electronic resonance circuit working
    under cryogenic conditions (T 4.2K). It enables
    the detection of a single ion as well as further
    successive measurements with the same ion.
  • Generally the axial oscillation is monitored.

Experimental setup for a sensitive, narrow-band
detection of a single stored ion. Due to a tuned
resonance circuit with a high quality factor Q an
improved detection sensitivity is reached.
65
The ISOLTRAP experiment
  • ISOLTRAP looks back on a highly successful
    physics program. In total the masses of 271
    radionuclides throughout the entire nuclear chart
    of the nuclides have been determined since its
    installation at the original ISOLDE facility in
    1992. The
  • relative uncertainty is typically dm/m 10-7 and
    even almost up to one order of magnitude better
    in some special cases

66
Micro-channel plate detector
  • A micro-channel plate is a slab made from highly
    resistive material of typically 2 mm thickness
    with a regular array of tiny tubes or slots
    (microchannels) leading from one face to the
    opposite, densely distributed over the whole
    surface. The microchannels are typically
    approximately 10 mm in diameter (6 mm in high
    resolution MCPs) and spaced apart by
    approximately 15 mm they are parallel to each
    other and often enter the plate at a small angle
    to the surface (8).
  • A single x-ray interacting in a channel of the
    MCP produces a charge pulse of about 1000
    electrons that emerge from the rear of the plate.
    Since the individual tubes confine the pulse, the
    spatial pattern of electron pulses at the rear of
    the plate preserve the pattern (image) of x-rays
    incident on the front surface. When coupled to an
    additional MCP and an electronic readout and
    display the MCP becomes an x-ray image
    intensifier.
  • a small photomultiplier

67
  • THE END
  • zazvonil zvonec a pohádek je konec

68
Merení hmot jader
  • An ideal Penning trap consists of a strong
    homogenous magnetic field and a weak quadrupolar
    electrostatic potential. In contrast to a Paul
    trap, full confinement is achieved with static
    trapping fields. As a Paul trap, a Penning trap
    also consists of ring and endcap electrodes.
    Quite often so-called guard or correction
    electrodes are placed between endcaps and the
    ring to compensate for the truncation of the
    hyperbolical electrodes. Two types of geometry
    configurations are commonly used hyperbolic and
    cylindrical. Both constructs have their own
    benefits although in precision experiments
    usually hyperbolical are favored due to better
    production of quadrupolar electric field. On the
    other hand, cylindrical electrodes are easier to
    manufacture and sometimes more open geometry
    offer other benefits such as better conductance
    of gas.

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On-Line NMR/ON
  • Nuclear Magnetic Resonance on Oriented Nuclei is
    done at 10 mK temperatures.
  • Polarised radioactive nuclei are exposed to an RF
    field of variable frequency.
  • When the Zeeman splitting frequency is found
    resonant absorption changes the
  • sublevel populations and hence also the observed
    anisotropy a resonance in the
  • anisotropy versus frequency plot.

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  • COLlinear LAser SPectroscopy

80
On-Line Laser spectroscopy Collinear and
In-Source Methods Atomic
Hyperfine Structure splitting
In Source, Doppler width resolution 250
MHz Collinear Concept - add constant energy to
ions
68Cu
?Econstd(1/2mv2)mvdv

Resolution 1 MHz, resulting from the velocity
compression of the line shape through energy
increase.
In Cu ion, electron states involved are s1/2 and
p1/2.

With nuclear spin I these each form a doublet
with F ( I J) I 1/2 and I -
1/2. Transitions between these doublets give four
lines in two pairs with related splittings. -
poor resolution (In Source) only for the A
(large magnetic dipole) splitting - good
resolution (Collinear) for both A and B (smaller
electric quadrupole splitting)

81
The NSCL Fragment Separator, MSU
Fragmentation b-NMR Fragments are polarised in
their creation. Implanted in cubic materials,
their polarisation can be detected by measurement
of the asymmetry of their beta decay. Application
of a magnetic field creates a Zeeman splitting
which is deduced from resonant destruction of the
asymmetry, yielding the nuclear g-factor.
82

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  • The spectroscopic quadrupole moment can be
    related to an intrinsic quadrupole moment Q0
    reflecting the nuclear deformation ß, only if
    certain assumptions about the nuclear structure
    are made. An assumption that is often made (but
    is not always valid!), is that the nuclear
    deformation is axially symmetric with the nuclear
    spin having a well-defined direction with respect
    to the symmetry axis of the deformation (strong
    coupling). In this case, the intrinsic and the
    spectroscopic quadrupole moment are related as
    follows

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  • SCATTERING OF HIGH-ENERGY NEUTRONS BY NUCLEI
  • cross section of the very fast neutrons (usually
    14 and 25 MeV neutrons used) reaches the value
    2pR2
  • THE YIELD OF NUCLEAR REACTIONS INITIATED BY
    PROTONS OR a-PARTICLES
  • Comparison of excitation functions with theory
    can give information about nuclear radius
  • Scattering of e- of high energy (200 MeV)
  • Diffraction pattern is expected if the charge is
    expected to be uniformly distributed around the
    nucleus (not point-like)
  • Assuming different values of R and b, one can try
    to find the best fit observed angular distribution

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