*已經(jīng)進(jìn)行到了如火如荼的階段,，無論是集體顏值超高的德國還是有著*射手的阿根廷,，本屆*的表現(xiàn)都讓我們的心情跌宕起伏,。我們不難發(fā)現(xiàn)阿根廷縱然擁有梅西這樣的*射手，旦失去中場的強(qiáng)力支持,，進(jìn)攻就會顯得很不連貫,，以至于出線歷程險象環(huán)生。而德國隊(duì)的表現(xiàn)更是讓球迷哭泣,，感覺他們?nèi)鄙傩┲袌龅暮诵哪哿驼嬲娜宋铮灾劣陉P(guān)鍵時刻不能完成致命擊,。“Teamwork”這個詞真是對足球準(zhǔn)確的詮釋了,。

    我們的科學(xué)研究情況也是這樣,，個前沿的研究課題要想取得突破離不開的科研人員,，同樣也離不開多種進(jìn)設(shè)備的協(xié)同工作,。目前量子材料,、量子信息和低溫光學(xué)是為活躍的研究方向,。這些域都有著自己的色儀器,，好像儀器中的“前鋒”,；另外還有為這些設(shè)備提供研究環(huán)境和平臺使得它們能夠協(xié)同工作的低溫光學(xué)恒溫器，這就好像儀器中的“中場核心”,。前鋒固不可少,，而中場核心更是決定比賽走勢的*,。今天我們就為大家來介紹中場隊(duì)員——Montana超精細(xì)無液氦低溫光學(xué)恒溫器,。

 圖1 Montana超精細(xì)無液氦低溫光學(xué)恒溫器

    日前亞洲套Montana超精細(xì)無液氦低溫光學(xué)恒溫器超穩(wěn)定高阻尼系統(tǒng)HILA落戶中國香港。在過去短短兩個月中,，Montana超精細(xì)無液氦低溫光學(xué)恒溫器微系統(tǒng)所,、復(fù)旦大學(xué)以及中國科學(xué)技術(shù)大學(xué)陸朝陽研究組順完成了安裝,。

    Montana超精細(xì)無液氦低溫光學(xué)恒溫器作為低溫光學(xué)和量子信息域重要的設(shè)備之,，為各種測量儀器提供低溫光學(xué)研究環(huán)境,。目前Montana超精細(xì)無液氦低溫光學(xué)恒溫器已經(jīng)發(fā)展成為型號齊全，功能全面，應(yīng)用域?yàn)閺V泛的低溫光學(xué)恒溫器,。如果將科研看成場比賽的話，那么Montana超精細(xì)無液氦低溫光學(xué)恒溫器長期以來扮演著低溫光學(xué)與量子信息科研比賽的“中場核心”,，在科研道路上披荊斬棘幫助用戶“攻城略地”,。

 圖2 Quantum Design工程師（右）與微系統(tǒng)所用戶

    Montana Instruments 始終不滿足于眼前的成績,，在不斷探索繼續(xù)前進(jìn),，在與多種第三方測量設(shè)備的兼容上都取得了突破,，甚至已經(jīng)成為NanoMOKE和FMR設(shè)備進(jìn)行低溫測量的推薦方案。目前Montana超精細(xì)無液氦低溫光學(xué)恒溫器提供的第三方設(shè)備集成方案包含各種磁體,、各種顯微鏡,、多種拉曼光譜儀,、MOKE、鐵磁共振,、多種波段光譜儀,、各種電學(xué)測量設(shè)備,、微區(qū)掃描SQUID、STM等幾十種設(shè)備,。MI工程師業(yè)的使客戶省去了繁瑣的實(shí)驗(yàn)搭建環(huán)節(jié),，大大提高科研效率。更為可喜的是,，2017年Cryostation詞已經(jīng)正式獲批注冊商標(biāo)，象征著MI在低溫光學(xué)域的影響力和地位,。

    如果說Montana超精細(xì)無液氦低溫光學(xué)恒溫器以前是名的中場核心,，現(xiàn)在已經(jīng)成長為球隊(duì)的。這樣的成績源于科學(xué)家對Montana Instruments的肯定激勵我們朝著更廣的應(yīng)用域,，更深的研究細(xì)節(jié)奮勇前進(jìn),！

附：Montana超精細(xì)無液氦低溫光學(xué)恒溫器光譜學(xué)域文章舉例
Raman Spectroscopy
2017 - David D. Awschalom (University of Chicago) - Nature Physics - Accelerated quantum control using superadiabatic dynamics in a solid-state lambda system
2017 - Amir Safavi-Naeini (Stanford University) - Phys. Rev. Applied - Engineering Phonon Leakage in Nanomechanical Resonators
2016 - Douglas Nason (Rice University) - ACS Nano - Plasmonic heating in Au nanowires at low temperatures: The role of thermal boundary resistance
2016 - Kenneth S. Burch (Boston College) - Review of Scientific Instruments - Low vibration high numerical aperture automated variable temperature Raman microscope
Photoluminescence, Fluorescence, Single Molecule Spectroscopy, Super Resolution Microscopy
2018 - Hui Deng (University of Michigan) - Nature Comms - Photonic-crystal exciton-polaritons in monolayer semiconductors
2017 - Hongkun Park (Harvard University) - Nature Nanotechnology - Probing dark excitons in atomically thin semiconductors via near-field coupling to surface plasmon polaritons
2017 - Kartik Srinivasan (NIST) - Review of Scientific Instruments - Cryogenic photoluminescence imaging system for nanoscale positioning of single quantum emitters
2016 - Xiaodong Xu (University of Washington) - Science - Valley-Polarized Exciton Dynamics in a 2D Semiconductor Heterostructure
2014 - Edo Waks (University of Maryland) - Nature Photonics - All-optical coherent control of vacuum Rabi oscillations
Optical Transmission, Optical Absorption Spectroscopy, Pump-Probe Techniques
2018 - Carlos Silva (Georgia Tech) - Phys. Rev. Materials - Stable biexcitons in two-dimensional metal-halide perovskites with strong dynamic lattice disorder
2016 - Alan Bristow (West Virginia University) - SPIE - Two-dimensional coherent spectroscopy of excitons, biexcitons and exciton-polaritons
2015 - Mikael Afzelius (University of Geneva, Switzerland) - Phys. Rev. Lett - Coherent spin control at the quantum level in an ensemble-based optical memory
Optical Reflection, Pump-Probe Techniques
2018 - Hongkun Park (Harvard University) - Phys. Rev. Lett - Large Excitonic Reflectivity of Monolayer MoSe2 Encapsulated in Hexagonal Boron Nitride
2017 - Lilian Childress (McGill University) - Optics Express - A High-Mechanical Bandwidth Fabry-Perot Fiber Cavity
2017 - Jun Ye (JILA, NIST) - Phys. Rev. Lett - Ultrastable Silicon Cavity in a Continuously Operating Closed-Cycle Cryostat at 4 K
Optical Cavities
2018 - Jelena Vuckovic (Stanford University) - Nano Lett - Strongly Cavity-Enhanced Spontaneous Emission from Silicon-Vacancy Centers in Diamond
2017 - Jun Ye (JILA, NIST) - Phys. Rev. Lett - Ultrastable Silicon Cavity in a Continuously Operating Closed-Cycle Cryostat at 4 K
2017 - Kartik Srinivasan (NIST) - Science - Quantum correlations from a room-temperature optomechanical cavity
2016 - Alberto Amo (CNRS, Université Paris-Saclay) - Nature Comms - Interaction-induced hopping phase in driven-dissipative coupled photonic microcavities
2015 - Paul Barclay (University of Calgary, Canada) - Phys. Rev. X - Single-Crystal Diamond Nanobeam Waveguide Optomechanics