富勒烯C_(60)掺杂的共轭高聚物混合薄膜的光谱性质

测量了不同富勒烯C60 掺杂浓度的聚对亚苯基亚乙烯衍生物 (MEH PPV)混合薄膜的紫外 可见吸收光谱、稳态荧光和时间分辨荧光光谱。观察到MEH PPV吸收峰受到明显的抑制以及荧光峰的猝灭。证明混合薄膜内 ,由于π π共轭体系的强相互作用在基态发生MEH PPV向C60 的电子转移 ,形成电荷转移络合物。在光激发下会发生MEH PPV向C60 的激发传递进一步抑制了发光跃迁过程 ,导致了MEH

铝掺杂及温度对氧化锌薄膜发光特性的影响

使用水热法在石英衬底上制备了掺铝氧化锌(AZO)薄膜,采用X射线衍射仪、扫描电子显微镜和低温光致发光谱技术对薄膜的微结构和发光性能进行了表征。结果表明,薄膜由氧化锌纳米锥构成,纳米锥直径大部分都在100 nm以下,且具有明显的沿c轴择优生长的特征。此种方法制备的AZO薄膜在室温下存在两个较宽的发光峰,即紫外-紫光发光峰和绿光-红光发光峰。铝掺杂强烈地影响两个发光峰的相对强度。随着掺杂量的增大,(1)紫外-紫光发光峰的相对强度和绝对强度都迅速增大,并在铝掺杂量达到10%时达到最大值,(2)绿光-红光发光峰中,各子发光峰的相对强度也发生一定变化,主要表现为长波子发光峰的发光强度的相对增大。铝掺杂还导致薄膜的发光谱中出现一个极少见的位于355 nm处的发光峰,该发光峰随铝掺杂量的增大而增强。薄膜的低温光致发光谱表明,随着薄膜温度由10 K升高到267 K,薄膜的紫外-紫光发光峰变化不明显,但绿光-红光发光峰的强度则随着温度的增加而快速单调减小,呈现荧光热猝灭现象。由发光中心的多声子发射造成的非辐射激子复合应该是造成这种热猝灭的主要原因。

CdZnTe晶体光致发光谱“负热淬灭”现象研究

采用改进的垂直布里奇曼法生长了直径为60mm的CdZnTe晶体,测试了其在10K～150K范围的PL谱。对760nm和825nm处的峰积分强度随温度变化关系进行研究发现,在30～50K范围内,PL谱峰的强度呈现反常温度依赖现象,即随着温度的升高而减小,也就是所谓的"负热淬灭"现象,这在CdZnTe晶体中属首次观察到。进一步分析表明,随着温度的增加,其PL谱强度变化的过程包含了三个无辐射过程和一个负热淬灭过程。与没有发生"负热淬灭"现象的CdZnTe晶体对比,两者XRD图谱呈现明显差异。讨论了发生负热淬灭现象的原因以及可能路径。

气源MBE外延自组装GeSi量子点的光致荧光

利用气源分子束外延技术(MBE)制作了GeSi自组装量子点样品。利用原子力显微镜(AFM)和光致荧光(PL)光谱研究了该量子点的形貌和光学性质。气源MBE在较低温度下生长的量子点材料具有较高的量子点覆盖度。200 K以下载流子以局域激子形式束缚在量子点中,激子束缚能约为17 meV。升温至200 K,载流子的输运过程发生变化。对量子点PL积分强度与温度关系曲线进行拟合得到量子点中空穴跃迁至浸润层的热激活能为129 meV。

时间分辨荧光光谱研究铁电材料锶钡铌氧(SBN)及铬离子掺杂的锶钡铌氧(SBN：Cr(3＋))的荧光热猝灭和光猝灭

本文使用稳态及时间分辨荧光光谱法对陶瓷相铁电材料Sr_xBa_(1-x)Nb_2O_6(SBN-x)及Cr^(3+)掺杂的Sr_xBa_(1-x)Nb_2O_6(SBN:Cr^(3+))的光生载流子的复合动力学进行了研究。带边激发条件下SBN-70非辐射复合过程在温度高于137K时已快于辐射复合,说明SBN在765nm处对应的发光中心极容易受到晶格振动影响,使激发态电子转而通过声子参与的无辐射跃迁回到基态。对于Cr^(3+)离子掺杂的SBN-70,使用395nm和480nm激发得到发光中心的热激活能分别为Ea=380.9±61.0meV和Ea=374.6±51.4meV。发现了SBN低温下很强的光致荧光猝灭性质,其产生原因可能归属为样品对激发光的吸收造成的捕获电子态对发光的二次吸收。

N掺杂ZnO中的缺陷与光致发光

采用金属有机物化学汽相沉淀法(MOCVD)在蓝宝石衬底(0002)上生长了高质量的ZnO掺氮薄膜,继后在氧气氛中对薄膜进行1000℃快速热退火,重点对退火后样品的发光特性进行变温光致发光谱的研究。低温下,在3.377、3.362、3.332eV附近有三个明显的近紫外发光峰,分别对应自由激子发射(FXA)、施主束缚激子(D0X)和其双电子伴线(TES),随着温度升高,施主热解离,导致D0X峰强下降,而FXA增强,同时DAP峰也向e-A0峰转变。深能级可见光区有台阶状精细结构,被指认为从浅施主及其激发态到锌空位的跃迁及其多级声子峰,并且观察到明显的负热淬灭效应,讨论了其产生原因。

Facile Preparation, Characterization of Flexible Organic Solar Cells Using P3HT-MWCNTS Composite Photoactive Layer

Multiwalled carbon nanotubes (MWCNTs) mixed in poly(3-hexylthiophene) (P3HT) were used as a photoactive layer for organic solar cells (OSC). The flexible OSCs of a structure of PET/rGO-P3HT/P3CT/PCBM/LiF-Al were prepared by spincoating. The UV-Vis absorption spectra of the photoactive films and current-voltage characteristics of the OSCs showed the advantage of the composite devices above the pristine-polymeric ones. Under illumination of light with a 100 mW/cm2-powerdensity, the photoelectrical conversion efficiency (PCE) of the OSCs with 3.0 wt% MWNCTs embedded in the photoactive layer possess a value as large as 2.35%. The obtained results suggest further useful applications of the flexible large-area solar cells.

Borophene-ZnO heterostructures:Preparation and application as broadband photonic nonvolatile memory

High-performance photonic nonvolatile memory which combines data storage and photosensing can achieve low power consumption and ensure computational energy efficiency.Heterostructure has been theoretically and experimentally proved to have synergistic effects between two materials,which can lead to promising electronic and optical properties for advanced optoelectronic devices.Herein,we report the preparation of borophene-ZnO heterostructures and their applications of broadband photonic nonvolatile memory.The memory shows a good switching ratio(5×10^(3))and long-term stability(3,600 s),which are superior to those of the pristine borophene or ZnO quantum dots(QDs).It is found that the memory shows a broad light response from ultraviolet(365 nm)to near infrared(850 nm).Besides,the SET voltage will decrease when the device is exposed to light,which can be attributed to the separation of holes and electrons in accelerating the formation of vacancy conductive filament.This work not only provides a promising material for next-generation photoelectric information,but also paves the way for borophene-based memory towards data storage devices.

浅谈一种新型非消耗的光学原理氧传感器

氧气的定量测量在生产、生活和科研等领域具有重要的意义。主要介绍一种基于荧光猝灭原理的光学氧传感器,浅谈这种光学氧传感器的原理、结构设计和部件组成情况。经过若干次的测试和改进,这种传感器己经被越来越多的用户所接受。也介绍了目前所推出光学氧传感器的性能、简单的应用和特点等。通过现场测试,测试效果非常理想。这种传感器目前在一些氧含量、氧分压的测试场氧气合非常具有优势。

Temperature dependence of photoluminescence from self-organized Ge quantum dots with large size and low density

Photoluminescence(PL) from self-organized Ge quantum dots(QDs) with large size and low density has been investigated over a temperature range from 10 to 300 K using continuous-wave(CW) optical excitation.The integrated PL intensity of QDs observed is negligible at about 10 K and rapidly increases with raising temperature up to 100 K.Through analyzing the PL experimental data of the QDs and wetting layer(WL),we provide direct evidence that there exists a potential barrier,arising from the greater compressive strain surrounding large QDs,which could trap carriers in WL at low temperatures and could be overcome via increasing temperature.