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德國Attocube Systems AG公司成立于2002年，作為納米科學領域年輕的儀器供應商，Attocube Systems AG以其掌握的納米精度定位**成果和強大的技術實力，在短短的幾年中研制開發(fā)了低震動無液氦磁體與恒溫器、多種低溫磁場下工作的掃描探針顯微鏡、極端環(huán)境應用納米精度位移器、皮米精度位移激光干涉器等系列產(chǎn)品，深受用戶贊譽。自成立以來，Attocube Systems AG已經(jīng)獲得了許多榮譽，包括Finalist for the 27th Innovation Award of the German Ecomomy 2007和 ****00 Innovation Award 2013 等。

無液氦低溫強磁場掃描探針顯微鏡

參數(shù)與技術特點：

+ 無液氦，閉路可循環(huán)系統(tǒng)

+ 獨特設計，超低震動（0.12 nm RMS）

+ 溫度范圍：1.5 K...300 K 或 4 K...300 K

+ 磁場強度：**可達15T

+ 多功能測量平臺：AFM/MFM/ct-AFM/PRFM/CFM/RAMAN

+ 超高溫度穩(wěn)定性

+ 全自動控制，觸摸屏控制

+ 快速冷卻：1-2小時樣品冷卻

相關閱讀：

1、無液氦低溫強磁場共聚焦顯微鏡 - attoCFM

2、低溫強磁場原子力/磁力/掃描霍爾顯微鏡 - attoAFM/attoMFM/attoSHPM

3、磁共振顯微鏡/低溫強磁場磁共振顯微鏡 - attoCSFM

4、低震動無液氦磁體與恒溫器 - attoDRY系列

5、atto3DR低溫雙軸旋轉臺

部分發(fā)表文獻：

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.

部分用戶列表

attocube公司產(chǎn)品以其穩(wěn)定的性能、極高的精度和良好的用戶體驗得到了國內(nèi)外眾多科學家的認可和肯定。attocube公司的產(chǎn)品在國內(nèi)也得到了低溫、超導、真空等研究領域**科學家和研究組的歡迎......