无液氦低温强磁场扫描探针显微镜

德国Attocube Systems AG公司成立于2002年，作为纳米科学领域年轻的仪器供应商，Attocube Systems AG以其掌握的纳米精度定位成果和强大的技术实力，在短短的几年中研制开发了低震动无液氦磁体与恒温器、多种低温磁场下工作的扫描探针显微镜、端环境应用纳米精度位移器、皮米精度位移激光干涉器等系列产品，深受用户赞誉。自成立以来，Attocube Systems AG已经获得了许多荣誉，包括Finalist for the 27th Innovation  Award of the German Ecomomy 2007和 00 Innovation Award 2013 等。

无液氦低温强磁场扫描探针显微镜

参数与技术特点：

+  无液氦，闭路可循环系统

+  特设计，超低震动（0.12 nm RMS）

+  温度范围：1.5 K...300 K 或 4 K...300 K

+  磁场强度：高可达15T 

+  多功能测量平台：AFM/MFM/ct-AFM/PRFM/CFM/RAMAN

+  超高温度稳定性

+  全自动控制，触摸屏控制 

+  快速冷却：1-2小时样品冷却

相关阅读：

1、无液氦低温强磁场共聚焦显微镜 - attoCFM

2、低温强磁场原子力/磁力/扫描霍尔显微镜 - attoAFM/attoMFM/attoSHPM

3、磁共振显微镜/低温强磁场磁共振显微镜 - attoCSFM

4、低震动无液氦磁体与恒温器 - attoDRY系列

5、atto3DR低温双轴旋转台

部分发表文献：

1.  Chaoyang Lu et.al, Coherently driving a single quantum two-level system with dichromatic laser pulses, Nature Physics, 15,941-945,(2019)

2.  Chaoyang Lu et.al, Towards optimal single-photon sources from polarized microcavities. Nature Photonics, 13, 770–775 (2019)

3.  Yuanbo Zhang et. Al, “Signatures of tunable superconductivity in a trilayer graphene moiré superlattice”Nature, 572, 215-219 (2019)

4.  P. Maletinsky et. Al, Probing magnetism in 2D materials at the nanoscale with single-spin microscopy, Science, 364, 973 (2019)

5.  Haomin WANG et al, “Isolating hydrogen in hexagonal boron nitride bubbles by a plasma treatment”.Nature communications, 10, 2815 (2019)

6.  Mingyuan Huang et.al, Magnetic Order-Induced Polarization Anomaly of Raman Scattering in 2D Magnet CrI3, Nano Letters, 2020,20,1, 729-734

7.  Alexander H?gele et. al, Cavity-control of interlayer excitons in van der Waals heterostructures, Nature communications, 2019,10:3697.

8.  Hanxuan Lin, et al. Unexpected Intermediate State Photoinduced in the Metal-Insulator Transition of Submicrometer Phase-Separated Manganites. Phys. Rev. Lett. 120, 267202(2018)

9.  Chaoyang Lu et.al, High-efficiency multiphoton boson sampling. Nature Photonics, 11, 361-365, (2017)

10.  K. Yasuda, et al. Quantized chiral edge conduction on domain walls of a magnetic topological insulator. Science 2017, 358, 1311-1314

11.  Zhu, Y. et al. Chemical ordering suppresses large-scale electronic phase separation in doped manganites. Nature communications, 2016,7:11260.

12.  Yang, W.;et al. Electrically Tunable Valley-Light Emitting Diode (vLED) Based on CVD-Grown Monolayer WS2. Nano Letters 2016, 16, 1560-1567.

13.  Surajit Saha; et al. Long-range magnetic coupling across a polar insulating layer, Nature communications, 2016,7:11015.

14.  He, Y. M.; et al. Single quantum emitters in monolayer semiconductors. Nature Nanotechnology 2015, 10, 497-502.

15.  Nazin, G.; et al. Visualization of charge transport through Landau levels in graphene. Nature Physics 2010, 6, 870-874.

16.  Proton magnetic resonance imaging using a nitrogen–vacancy spin sensor. Nature   Nanotechnology, 2015,10,120-124.

17.  Nanoscale nuclear magnetic imaging with chemical contrast. Nature Nanotechnology, 2015, 10, 125-128.

18.  Observation of biexcitons in monolayer WSe2. Nature Physics, 2015, 11, 477-481.

19.  Visualization of a ferromagnetic metallic edge state in manganite strips. Nature Communications, 2015, 6:6179.

20.  Observation of Excitonic Fine Structure in a 2D Transition-Metal   Dichalcogenide Semiconductor. ACS Nano, 2015, 9, 647-655.

21.  Energy losses of nanomechanical resonators induced by atomic force   microscopy-controlled mechanical impedance mismatching. Nature Communications, 2014, 5:3345.

22.  Deterministic and electrically tunable bright single-photon source. Nature Communications, 2014, 5:3240.

23.  Dynamic Visualization of Nanoscale Vortex Orbits. ACS Nano, 2014, 8, 2782-2787.

24.  Transition from slow Abrikosov to fast moving Josephson vortices in iron   pnictide superconductors. Nature Materials, 2013, 12, 134-138.

25.  Stray-field imaging of magnetic vortices with a single diamond spin. Nature Communications, 2013, 4:2279.

26.  Realization of pristine and locally tunable one-dimensional electron   systems in carbon nanotubes. Nature Nanotechnology, 2013, 8, 569-574.

27.  Strong magnetophonon resonance induced triple G-mode splitting in   graphene on graphite probed by micromagneto Raman spectroscopy. Physical Review B, 2013, 88, 165407.

28.  Origin of negative magnetoresistance of GaAs/(Ga,Mn)As core-shell   nanowires. Physical Review B, 2013, 87, 245303.

29.  Magnetic Imaging on the Nanometer Scale Using Low-Temperature Scanning Probe Techniques. Microscopy Today, 2011, 19, 34-38.

30.  Visualization of charge transport through Landau levels in graphene. Nature Physics, 2010, 6, 870-874.

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