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Literature DB >> 29809211

Designing shape anisotropic SmCo₅ particles by chemical synthesis to reveal the morphological evolution mechanism.

Zhenhui Ma¹, Ming Yue¹, Qiong Wu¹, Chenglin Li¹, Yongsheng Yu².

Abstract

In this work, we describe a new protocol to synthesize SmCo5 single crystal particles with remarkable shape anisotropy (hexagonal and rodlike), which exhibit a giant coercivity of 36.6 kOe and a high Mr/Ms value of 0.95 after an alignment. On this basis, the morphological evolution mechanism is illustrated by employing the template effect.

Entities: Chemical

Year: 2018 PMID： 29809211 DOI： 10.1039/c8nr02893a

Source DB: PubMed Journal: Nanoscale ISSN： 2040-3364 Impact factor: 7.790

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Cited

4 in total

1. Enhancement of anisotropy energy of SmCo₅ by ceasing the coupling at 2c sites in the crystal lattice with Cu substitution.

Authors: Syed Kamran Haider; Hieu Minh Ngo; Dongsoo Kim; Young Soo Kang
Journal: Sci Rep Date: 2021-05-12 Impact factor: 4.379

2. High coercivity SmCo₅ synthesized with assistance of colloidal SiO₂.

Authors: Hao Tang; Mohammad Aref Hasen Mamakhel; Mogens Christensen
Journal: Sci Rep Date: 2021-02-25 Impact factor: 4.379

3. Calcium vapor synthesis of extremely coercive SmCo₅.

Authors: Sarah E Baker; Alexander A Baker; Christine A Orme; Matthew A Worthington; Tian T Li; Edwin M Sedillo; Jessica Dudoff; Jonathan R I Lee; Joshua D Kuntz; Scott K McCall
Journal: RSC Adv Date: 2022-01-28 Impact factor: 3.361

4. A Self-Assembly of Single Layer of Co Nanorods to Reveal the Magnetostatic Interaction Mechanism.

Authors: Hongyu Du; Min Zhang; Ke Yang; Baohe Li; Zhenhui Ma
Journal: Nanomaterials (Basel) Date: 2022-07-21 Impact factor: 5.719

4 in total

Designing shape anisotropic SmCo5 particles by chemical synthesis to reveal the morphological evolution mechanism.

1. Enhancement of anisotropy energy of SmCo5 by ceasing the coupling at 2c sites in the crystal lattice with Cu substitution.

2. High coercivity SmCo5 synthesized with assistance of colloidal SiO2.

3. Calcium vapor synthesis of extremely coercive SmCo5.

4. A Self-Assembly of Single Layer of Co Nanorods to Reveal the Magnetostatic Interaction Mechanism.

Designing shape anisotropic SmCo₅ particles by chemical synthesis to reveal the morphological evolution mechanism.

1. Enhancement of anisotropy energy of SmCo₅ by ceasing the coupling at 2c sites in the crystal lattice with Cu substitution.

2. High coercivity SmCo₅ synthesized with assistance of colloidal SiO₂.

3. Calcium vapor synthesis of extremely coercive SmCo₅.