Your search keyword '"ZHANG Jingyan"' showing total 7 results

1. Magnetic Structure-Dependent Spin Texture Lattice in Hexagonal MnFeCoGe Magnets

Author

Xu, Jiawang, Xi, Lei, Xing, Shouyuan, Sheng, Junchao, Li, Shihao, Wang, Liming, Kan, Xucai, Ma, Tianping, Zang, Yipeng, Bao, Bin, Zhou, Zhonghao, Yang, Mengmeng, Gao, Yawei, Wang, Dingsong, Wang, Guyue, Zheng, Xinqi, Zhang, Jingyan, Du, Haifeng, Xu, Juping, Yin, Wen, Zhang, Ying, Zhou, Shiming, Shen, Baogen, and Wang, Shouguo

Abstract

Topological spin textures are of great significance in magnetic information storage and spintronics due to their high storage density and low drive current. In this work, the transformation of magnetic configuration from chaotic labyrinth domains to uniform stripe domains was observed in MnFe1–xCoxGe magnets. This change occurs due to the noncollinear magnetic structure switching to a uniaxial ferromagnetic structure with increasing Co content, as identified by neutron diffraction results and Lorentz transmission electron microscopy (L-TEM). Of utmost importance, a hexagonal lattice of high-density robust type-II magnetic bubble lattice was established for x= 0.8 through out-of-plane magnetic field stimulation and field-cooling. The dimensions of the type-II magnetic bubbles were found to be tuned by the sample thickness. Therefore, the stabilization of complex magnetic spin textures, associated with enhanced uniaxial ferromagnetic interaction and magnetic dipole–dipole interaction in MnFe1–xCoxGe through magnetic structure manipulation, as further confirmed by the micromagnetic simulations, will provide a convenient and efficient strategy for designing topological spin textures with potential applications in spintronic devices.

Published

2024

2. Vacuolization in Cytoplasm and Cell Membrane Permeability Enhancement Triggered by Micrometer-Sized Graphene Oxide

Author

Wu, Congyu, primary, Wang, Chong, additional, Zheng, Jing, additional, Luo, Chao, additional, Li, Yanfang, additional, Guo, Shouwu, additional, and Zhang, Jingyan, additional

Published

2015

3. Stabilization and Induction of Oligonucleotide i-Motif Structure via Graphene Quantum Dots

Author

Chen, Xin, primary, Zhou, Xuejiao, additional, Han, Ting, additional, Wu, Jiaying, additional, Zhang, Jingyan, additional, and Guo, Shouwu, additional

Published

2012

4. Photo-Fenton Reaction of Graphene Oxide: A New Strategy to Prepare Graphene Quantum Dots for DNA Cleavage

Author

Zhou, Xuejiao, primary, Zhang, Yan, additional, Wang, Chong, additional, Wu, Xiaochen, additional, Yang, Yongqiang, additional, Zheng, Bin, additional, Wu, Haixia, additional, Guo, Shouwu, additional, and Zhang, Jingyan, additional

Published

2012

5. DNA Cleavage System of Nanosized Graphene Oxide Sheets and Copper Ions

Author

Ren, Hongliu, primary, Wang, Chong, additional, Zhang, Jiali, additional, Zhou, Xuejiao, additional, Xu, Dafeng, additional, Zheng, Jing, additional, Guo, Shouwu, additional, and Zhang, Jingyan, additional

Published

2010

6. Stabilization and Induction of Oligonucleotide i-Motif Structure viaGraphene Quantum Dots

Author

Chen, Xin, Zhou, Xuejiao, Han, Ting, Wu, Jiaying, Zhang, Jingyan, and Guo, Shouwu

Abstract

DNA i-motif structures have been found in telomeric, centromeric DNA and many in the promoter region of oncogenes; thus they might be attractive targets for gene-regulation processes and anticancer therapeutics. We demonstrate in this work that i-motif structures can be stabilized by graphene quantum dots (GQDs) under acidic conditions, and more importantly GQDs can promote the formation of the i-motif structure under alkaline or physiological conditions. We illustrate that the GQDs stabilize the i-motif structure through end-stacking of the bases at its loop regions, thus reducing its solvent-accessible area. Under physiological or alkaline conditions, the end-stacking of GQDs on the unfolded structure shifts the equilibrium between the i-motif and unfolded structure toward the i-motif structure, thus promoting its formation. The possibility of fine-tuning the stability of the i-motif and inducing its formation would make GQDs useful in gene regulation and oligonucleotide-based therapeutics.

Published

2013

7. Stabilization and induction of oligonucleotide i-motif structure via graphene quantum dots.

Author

Chen X, Zhou X, Han T, Wu J, Zhang J, and Guo S

Subjects

Drug Stability, Materials Testing, DNA chemistry, DNA ultrastructure, Graphite chemistry, Quantum Dots

Abstract

DNA i-motif structures have been found in telomeric, centromeric DNA and many in the promoter region of oncogenes; thus they might be attractive targets for gene-regulation processes and anticancer therapeutics. We demonstrate in this work that i-motif structures can be stabilized by graphene quantum dots (GQDs) under acidic conditions, and more importantly GQDs can promote the formation of the i-motif structure under alkaline or physiological conditions. We illustrate that the GQDs stabilize the i-motif structure through end-stacking of the bases at its loop regions, thus reducing its solvent-accessible area. Under physiological or alkaline conditions, the end-stacking of GQDs on the unfolded structure shifts the equilibrium between the i-motif and unfolded structure toward the i-motif structure, thus promoting its formation. The possibility of fine-tuning the stability of the i-motif and inducing its formation would make GQDs useful in gene regulation and oligonucleotide-based therapeutics.

Published

2013