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Chirality-Controlled Enantiopure Crystal Growth of a Transition Metal Monosilicide by a Floating Zone Method

We performed a crystal growth to obtain chirality-controlled enantiopure crystals using a laser-diode-heated floating zone (LDFZ) method with a composition-gradient feed rod. It has been argued that the crystal handedness of $T$Si ($T$ : transition metal) is fixed depending on $T$ in the case of the ones grown by the conventional methods. We found that right-handed single crystals of CoSi and MnSi were grown from the composition gradient feed rods that consist of FeSi--CoSi and FeSi--MnSi, respectively. The obtained CoSi and MnSi crystals inherit the chirality from the seed part of FeSi, which grows in a right-handed structure, and thus have the chirality opposite to that for the crystals in the literature. The LDFZ method with the feed rods with various combinations of $T$Si compounds enables a flexible control of the chirality of $T$Si and will be useful for clarifying the interplay between the crystalline chirality and chirality-induced physical responses.

preprint2022arXivOpen access
Yusuke KousakaSatoshi IwasakiTaisei SayoHiroshi TanidaTakeshi MatsumuraShingo ArakiJun AkimitsuYoshihiko Togawa
cond-mat.mtrl-sci
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Yusuke KousakaSatoshi IwasakiTaisei SayoHiroshi TanidaTakeshi MatsumuraShingo ArakiJun AkimitsuYoshihiko Togawa

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