浅析电子型掺杂铜氧化物超导体的退火过程

铜氧化物高温超导体的发现, 打破了基于电声子相互作用BCS理论所预言的超导转变温度极限, 掀开了高温超导材料探索和高温超导机理研究的序幕. 根据掺杂类型的不同, 铜氧化物超导材料可以分为空穴型掺杂和电子型掺杂两类. 受限于样品, 对电子型掺杂铜氧化物的研究工作远少于空穴型掺杂体系. 本文简要回顾有关电子型掺杂铜氧化物超导体近期研究成果, 通过对比电子型掺杂和空穴型掺杂铜氧化物的相图来阐明电子型掺杂铜氧化物的研究对探索高温超导机理的必要性, 并特别针对电子型掺杂样品制备中的关键因素“退火过程”展开讨论. 结合课题组最新实验结果和相关实验报道我们发现电子型掺杂铜氧化物超导体在制备过程中除受到温度和氧分压的影响外, 退火效果还受到界面应力的强烈调制. 在综合考虑样品生长过程中温度、气氛及应力等多种因素的基础上, 探讨了“保护退火”方法导致电子型体系化学掺杂相图变化的起因.     

脉冲激光沉积技术制备超导薄膜的研究进展

超导薄膜不仅在超导应用方面扮演着举足轻重的角色，而且是超导机理研究的良好载体，是连接超导应用和机理的桥梁。脉冲激光沉积(PLD)是最常用的超导薄膜制备技术之一。本文综述了PLD技术制备铜氧化物、铁基、氮化物、钛氧化物等超导薄膜的研究进展，并介绍了与高温超导薄膜应用相关的两种PLD新技术：超导带材和大面积薄膜制备。最后，本文介绍了基于材料基因工程的高通量组合薄膜技术在高温超导研究上的典型成功案例。继续发展和使用该实验技术，构建与高温超导相关的高维相图和定量规律，有望实现机理研究实验上从量变到质变的全面突破。     

Doping Mn into(Li_(1-x)Fe_x)OHFe_(1-y)Se superconducting crystals via ion-exchange and ion-release/introduction syntheses

We report the success in introducing Mn into(Li_(1-_x)Fe_x)OHFe_(1-y) Se superconducting crystals by applying two different hydrothermal routes, ion e_xchange(1-step) and ion release/introduction(2-step). The micro-region _x-ray diffraction and energy dispersive _x-ray spectroscopy analyses indicate that Mn has been doped into the lattice, and its content in the 1-step fabricated sample is higher than that in the 2-step one. Magnetic susceptibility and electric transport properties reveal that Mn doping influences little on the superconducting transition, regardless of 1-step or 2-step routes. By contrast, the characteristic temperature T*, at which the negative Hall coefficient reaches its minimum, is significantly reduced by Mn doping.This implies that the hole carriers contribution is obviously modified, and hence the hole band might have no direct relationship with the superconductivity in(Li_(1-_x)Fe_x)OHFe_(1-y) Se superconductors. Our present hydrothermal methods of ion e_xchange and ion release/introduction provide an efficient way for elements substitution/doping into(Li_(1-_x)Fe_x)OHFe_(1-y) Se superconductors, which will promote the in-depth investigations on the role of multiple electron and hole bands and their interplay with the high-temperature superconductivity in the FeSe-based superconductors.     

Electronic structure and nematic phase transition in superconducting multiple-layer FeSe films grown by pulsed laser deposition method

We report comprehensive angle-resolved photoemission investigations on the electronic structure of single crystal multiple-layer FeSe films grown on CaF_2 substrate by pulsed laser deposition(PLD) method. Measurements on FeSe/CaF_2 samples with different superconducting transition temperatures T_c of 4 K, 9 K, and 14 K reveal electronic difference in their Fermi surface and band structure. Indication of the nematic phase transition is observed from temperature-dependent measurements of these samples; the nematic transition temperature is 140-160 K, much higher than ~90 K for the bulk FeSe. Potassium deposition is applied onto the surface of these samples; the nematic phase is suppressed by potassium deposition which introduces electrons to these FeSe films and causes a pronounced electronic structure change. We compared and discussed the electronic structure and superconductivity of the FeSe/CaF_2 films by PLD method with the FeSe/SrTiO_3 films by molecular beam epitaxy(MBE) method and bulk FeSe. The PLD-grown multilayer FeSe/CaF_2 is more hole-doped than that in MBE-grown multiple-layer FeSe films. Our results on FeSe/CaF_2 films by PLD method establish a link between bulk FeSe single crystal and FeSe/SrTiO_3 films by MBE method, and provide important information to understand superconductivity in FeSe-related systems.     

铁硒基超导研究新进展:高质量(Li,Fe)OHFeSe单晶薄膜

单晶薄膜形态的高温超导材料对于相关基础科学研究和应用开发都极为重要.多带的铁基高温超导体往往呈现丰富的物理现象,并具有较高的超导临界参数.特别是近年发现的插层（Li,Fe）OHFeSe超导体,无论对高温超导机理还是应用研究而言,都日益受到重视,已成为铁基家族中重要的典型材料.但是,该化合物含有OH键,加热易分解.因此,现有的常规高温成膜技术均不适用于生长该薄膜材料.为解决这一生长难题,我们最近发明了基体辅助水热外延生长法,实现了超导薄膜制备技术上的突破.本文简要介绍用此软化学成膜技术首次成功制备出（Li,Fe）OHFeSe单晶薄膜.该薄膜材料具有优良的结晶质量和较高的超导临界参数,特别是其高的临界电流密度和上临界场对应用开发有实际价值.因此,（Li,Fe）OHFeSe超导单晶薄膜的成功合成,为机理研究和应用开发分别提供了重要的实验载体和备选材料.另外,该薄膜技术也有望应用于其他功能材料的探索与合成,尤其是对常规手段难以获取的材料更具重大价值.     

高质量FeSe单晶薄膜的制备及相关性能表征

在铁基超导体中,FeSe具有最简单的晶体结构和化学组成,而且其超导转变温度具有较大的调控空间,因此适合作为超导机理研究和应用的载体.高质量样品的研制是物性研究和器件应用的前提,本文系统地研究了利用激光脉冲沉积技术制备FeSe薄膜的工艺条件,在多种衬底上成功地制备出高质量的β-FeSe薄膜,并首次实现了超导临界转变温度从小于2 K到14 K的连续调控,这为FeSe超导机理研究提供了样品支持.为探究FeSe薄膜超导电性变化的起因,从β-FeSe超导电性与晶格常数c正相关出发,基于简单的费米面填充假设,第一性原理计算可以很好地解释晶格常数c的变化规律,但该假设并不能完全符合角分辨光电子能谱实验给出的电子结构演变过程.因此β-FeSe薄膜的超导电性、晶格结构和电子结构三者之间的关系还有待澄清,该问题的解决将为FeSe超导机理研究提供重要的线索,而上述系列高质量的β-FeSe薄膜样品恰好能为该问题的研究提供理想的载体.本文根据实验和已有的相关研究结果,详细介绍了FeSe薄膜的脉冲激光沉积制备及其优化,以期为后续的薄膜研究应用提供参考.