J. Schoenes scite author profile

We show, with the help of polarized neutrons, that the cubic magnets Fe1-xCoxSi with Dzyaloshinskii-Moriya interaction can be switched between left (for x=0.1, 0.15) and right (for x=0.2, 0.25, 0.3, 0.5) chiral states of the spin helix. The absolute structure was evaluated using x-ray diffraction. The crystals are shown to be enantiopure and the structural chirality changes from right handed for x<0.2 to left handed for x>0.2. These compounds are compared with the etalon sample of MnSi which is identified as having the left-handed chirality both in the magnetic and crystallographic sense.

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Optical properties and electronic structure of UO2

Schoenes¹

1978

163

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The near normal incidence reflectivity of UO2 single crystals has been measured in the photon energy range from 0.03 eV to 13 eV. From the reflectivity spectrum the complex dielectric function ε (ω) =ε1(ω)+iε2(ω) has been derived by means of the Kramers-Kronig relation. In addition the absorption coefficient was determined from a direct transmission measurement on thin single crystal plates in the weakly absorbing spectral region below the absorption edge. An energy level scheme is proposed which allows a self-consistent assignment of the structure in ε2 with optical transitions between maxima in the density of states. The energy gap found at 2.1±0.1 eV is attributed to a 5f2→5f16deg transition. A crystal field splitting 10Dq=2.8 eV is derived for the 6d conduction states. Good agreement is obtained within this model with XPS measurements and a recent molecular cluster approximation. It disagrees with a previous interpretation of reflectivity data.

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Hall-effect and resistivity study of the heavy-fermion systemURu2Si2
Schoenes
¹
,
Schönenberger
²
,
Franse
³

et al. 1987
Phys. Rev. B
152
16
100
0
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Electronic transitions, crystal field effects and phonons in UO2

Schoenes

1980

Physics Reports

157

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J. Schoenes

Electronic structure and Coulomb correlation energy in UO2 single crystal

Crystal Handedness and Spin Helix Chirality inFe1−xCoxSi

Optical properties and electronic structure of UO2

Hall-effect and resistivity study of the heavy-fermion systemURu2Si2
Schoenes
¹
,
Schönenberger
²
,
Franse
³

et al. 1987
Phys. Rev. B
152
16
100
0
View full text Add to dashboard Cite

Electronic transitions, crystal field effects and phonons in UO2

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J. Schoenes

Electronic structure and Coulomb correlation energy in UO2 single crystal

Crystal Handedness and Spin Helix Chirality inFe1−xCoxSi

Optical properties and electronic structure of UO2

Hall-effect and resistivity study of the heavy-fermion systemURu2Si2Schoenes1, Schönenberger2, Franse3 et al. 1987Phys. Rev. B152161000View full textAdd to dashboardCite

Electronic transitions, crystal field effects and phonons in UO2

Contact Info

Product

Resources

About

Hall-effect and resistivity study of the heavy-fermion systemURu2Si2
Schoenes
¹
,
Schönenberger
²
,
Franse
³

et al. 1987
Phys. Rev. B
152
16
100
0
View full text Add to dashboard Cite