氟化钡晶体电注入着色临界温度及光谱特性

利用用自行研制的电注入实验装置,对氟化钡晶体进行电注入并使之有效着色. 由基本理论得到氟化钡晶体电注入临界温度,着色氟化钡晶体产生大量F和FA色心. 研究结果表明,经电注入氟化钡晶体,F色心首先在阴极附近产生,而且室温下F色心很不稳定.     

金刚石集群NV色心的光谱特征及浓度定量分析

金刚石NV-色心具有优越的光致发光特性,可实现高灵敏度物理量探测。其中,NV-色心的浓度是影响其宏观领域物理量探测灵敏度的重要因素之一。分析了金刚石在NV-色心制备过程中产生的发光缺陷,研究了不同的电子注入剂量与NV-色心浓度的关系。首先,对金刚石进行电子辐照并高温真空退火,制备了NV-色心;然后,利用拉曼光谱仪测试了金刚石在电子辐照前、电子辐照后及退火后三个阶段中的荧光光谱,分析了金刚石在NV-色心制备过程中的光谱特性;最后,对生成的NV-色心的浓度进行了估算,并探究了不同电子注入剂量对NV-色心浓度的影响规律。结果表明,金刚石经电子注入后生成了524.7,541.1,578和648.1 nm发光中心。其中,HPHT合成金刚石经电子注入后普遍存在524.7 nm中心。电子注入后的金刚石经高温(≥800 ℃)真空(≥10-7 Pa)退火后,空位自由移动,不稳定的缺陷消失,当空位靠近氮原子时被束缚而形成氮空位色心。对于氮含量100 ppm的金刚石,当电子注入产生的空位含量小于120 ppm(2.1×1019 cm-3)时,NV-色心浓度与电子注入生成空位的含量的关系符合Boltzmann分布。该研究为利用氮含量100 ppm的金刚石实现定量NV-色心浓度的制备提供了参考依据,为NV-色心在宏观物理量精密测量的应用奠定了基础。     

钨酸铅晶体的本征色心和辐照诱导色心

根据钨酸铅晶体(PbWO4,简称PWO)的缺陷化学和晶体结构特点,用光吸收谱、广延X射线吸收精细结构(EXAFS)和精密X射线衍射(XRD)方法对高温退火后PWO晶体进行微结构研究,获得了其退火前后缺陷变化的情况,据此提出生成态(asgrown)晶体中350nm本征色心吸收带起源于V-F空穴心,并指出PWO中紫外区色心吸收带的强度取决于晶体中铅空位和氧空位浓度之差:[VPb]-[VO];然后,结合晶体在紫外光(UV)辐照过程中色心的转化规律和偏振吸收谱的实验结果,提高420nm辐照诱导色心吸收带起源于V0F双空穴心.并对所提出的PWO晶体色心模型的合理性进行了讨论. 关键词： 钨酸铅 本征色心 辐照诱导色心 色心模型     

蓝宝石中子辐照色心的研究

研究了中子辐照对蓝宝石(α-Al2O3)单晶体缺陷形成及光学性能的影响,对采用提拉法与温度梯度法生长的蓝宝石晶体进行中子辐照,通过对比辐照前后的吸收及荧光光谱变化,发现辐照使得蓝宝石晶体内形成F、F^ 和F2^ 色心缺陷,但不同方法生长的晶体样品中色心浓度差异明显。其中提拉法样品的F心浓度要高于温度梯度法样品,而温度梯度法样品中F^ 色心浓度要高于提拉法样品。分析表明,这与两种方法生长的晶体中杂质含量差异有关。通过研究辐照后晶体的热致发光谱发现提拉法与温度梯度法生长的蓝宝石晶体分别在145℃与150℃有明显的热致发光出现,采用初始上升法计算出两种方法生长的晶体的热致发光陷阱深度分别为1．15eV及1．05eV。     

溴化钾质量对红外光谱测试结果的影响

溴化钾(KBr)在中红外区段没有吸收峰,所以常作为红外光谱测试样品的载体。如果溴化钾试剂中混有杂质,则杂质产生的吸收峰会对样品测试的红外光谱形成干扰和影响。对国内外多家厂商的溴化钾试剂分别进行了红外光谱测试,就溴化钾试剂质量对红外光谱测试的影响进行了分析和论述。分析表明,红外光谱实验所选用的溴化钾纯度至少应当在99%以上。     

LiF色心晶体—红宝石激光器被动Q开关

用着色LiF晶体中的色心做红宝石激光器的被动Q开关,得到了能量为50mJ,脉冲宽度为30ns(FWHM)的巨脉冲输出,并和隐花菁(cryptocyanine)等染料调Q作了比较.     

色心晶体及激光研究进展

色心激光是当前及今后固体可调谐激光领域的主要研究对象之一。该文综合评述了碱卤化物色心晶体及激光的研究发展概况，系统地探讨了色心的结构、光谱性质和色心晶体的制备，客观地分析了Ｆ型色心、Ｆ２＾＋型色心的发展、现状及主要激光性能。     

Yb∶YAG晶体的荧光特性研究

测量了不同掺杂浓度Yb∶YAG晶体氧化和还原气氛退火前后的色心吸收光谱、荧光光谱和荧光寿命 研究了色心对Yb∶YAG晶体的荧光强度和荧光寿命的影响 结果表明 ,只有当Yb的掺杂浓度大于 10at.%时 ,色心吸收的加强对发光强度和荧光寿命有明显猝灭作用     

Yb∶YAG晶体的荧光特性研究

测量了不同掺杂浓度Yb∶YAG晶体氧化和还原气氛退火前后的色心吸收光谱、荧光光谱和荧光寿命.研究了色心对Yb∶YAG晶体的荧光强度和荧光寿命的影响.结果表明,只有当Yb的掺杂浓度大于10 at.%时,色心吸收的加强对发光强度和荧光寿命有明显猝灭作用.     

Yb:YAG晶体的光谱性能

系统地研究了不同掺杂浓度的Ｙｂ：ＹＡＧ晶体的光谱特性,通过吸收光谱的测量计算了晶体的吸收截面,用对易法计算了晶体的发射截面。在Ｙｂ：ＹＡＧ晶体毛坯中发现Ｙｂ＾２＋和色心,其浓度随Ｙｂ：ＹＡＧ晶体中Ｙｂ＾３＋的增加而增加。经１４００℃氧气氛退火后消失。首次用光子激发和Ｘ射线激发研究了Ｙｂ：ＹＡＧ晶体的荧光特性。     

Formation of H<Subscript><Emphasis Type="Italic">a</Emphasis></Subscript><Superscript>-</Superscript> hydrogen centers upon additive coloration of alkaline-earth fluoride crystals

The mechanism of coloration of alkaline-earth fluoride crystals CaF₂, SrF₂, and BaF₂ in calcium vapors in an autoclave with a cold zone is studied. It was found that the pressure in the autoclave upon constant evacuation by a vacuum pump within the temperature range of 500–800°C increases due to evaporation of metal calcium. In addition to the optical-absorption bands of color centers in the additively colored undoped crystals or to the bands of divalent ions in the crystals doped with rare-earth Sm, Yb, and Tm elements, there appear intense bands in the vacuum ultraviolet region at 7.7, 7.0, and 6.025 eV in CaF₂, SrF₂, and BaF₂, respectively. These bands belong to the H_a ^- hydrogen centers. The formation of hydrogen centers is also confirmed by the appearance of the EPR signal of interstitial hydrogen atoms after X-ray irradiation of the additively colored crystals. Grinding of the outer edges of the colored crystals leads to a decrease in the hydrogen absorption-band intensity with depth to complete disappearance. The rate of hydrogen penetration inside the crystal is lower than the corresponding rate of color centers (anion vacancies) by a factor of tens. The visible color density of the outer regions of the hydrogen-containing crystals is several times lower than that of the inner region due to the competition between the color centers and hydrogen centers.     

A high-stability medium based on CaF<Subscript>2</Subscript>:Na crystals with colloidal color centers: I. Photothermochemical conversion of colloidal color centers in CaF<Subscript>2</Subscript>:Na crystals

Photothermochemical conversion of simple color centers (which include from one to four anionic vacancies) and highly aggregated ones in additively colored crystals of calcium fluoride doped by sodium is studied. The annealing of crystals with a low sodium content in a reducing atmosphere (additive coloration) leads to the predominant formation of simple color centers, which convert into highly aggregated centers under the joint action of heating and irradiation in absorption bands of simple centers. The irradiation of highly aggregated centers into their absorption bands and simultaneous heating causes these centers to convert into simple centers. The additive coloration of crystals with a relatively high sodium content leads to the predominant formation of highly aggregated centers. The heating of these crystals along with the irradiation in absorption bands of highly aggregated centers causes these centers to convert into simple centers. The formation of different color centers in the course of additive coloration of crystals with different impurity content and different results of photothermochemical conversion of centers in these crystals are connected with the dual action of impurities. Anion vacancies, which compensate the charge of the impurity alkali metal, facilitate the aggregation of color centers. At the same time, the alkali impurity stabilizes simple color centers.     

Electrolytic coloration and spectral properties of hydroxyl-doped potassium chloride single crystals

Hydroxyl-doped potassium chloride single crystals are colored electrolytically at various temperatures and voltages using a pointed cathode and a flat anode. Characteristic OH⁻ spectral band is observed in the absorption spectrum of uncolored single crystal. Characteristic O⁻, OH⁻, U, V₂, V₃, O²⁻-V_a⁺, F, R₂ and M spectral bands are observed simultaneously in absorption spectra of colored single crystals. Current-time curve for electrolytic coloration of hydroxyl-doped potassium chloride single crystal and its relationship with electrolytic coloration process are given. Production and conversion of color centers are explained.     

Energy transfer among color centers in LiF crystals

In colored LiF crystals there are many absorption and emission bands which cover a wide region of the spectrum from 200 up to 1 300 nm without breaking the continuity. In the frame of these favourable conditions we have performed some experiments of energy transfer among various color centers. The results indicate the existence of efficient exchanges of radiative energy among several bands by using only one exciting wavelength. In particular, the emissions of the F₃ ^- and F₂ ^- color centers centered at 900 and 1 100 nm, respectively, have been observed by pumping at 672 nm completely outside their absorption bands. Received 25 June 2001 and Received in final form 16 July 2001     

V color centers in electrolytically colored hydroxyl-doped sodium chloride crystals

Hydroxyl-doped sodium chloride crystals were successfully colored electrolytically by using pointed anode and flat cathode at various temperatures and under various electric field strengths. V₂ and V₃ color centers were produced in the colored crystals. Current-time curves for the electrolytic colorations were given, and activation energy for the V₂ and V₃ color center migration was determined. Production of the V₂ and V₃ color centers and formation of current zones for the electrolytic colorations of the hydroxyl-doped sodium chloride crystals are explained.     

Electrolytic coloration and spectral properties of OH- and Cu-codoped NaCl crystals

OH⁻- and Cu⁺-codoped NaCl crystals are colored electrolytically by using a pointed anode and a flat cathode at various temperatures and under various voltages. Absorption and fluorescence spectral properties of colored crystals are investigated. Absorption, excitation and fluorescence spectra reveal existence of V₂, V₂^m, V₃, OH⁻, U, U_A, O²⁻–V_a⁺, O₂⁺, Cu⁺, Cu⁰, Cu⁻ and OH⁻-perturbed Cu⁺ color centers in colored crystals. Formations of color centers are explained.     

Luminescent patterns based on color centers generated in lithium fluoride by extreme ultraviolet radiation and soft X-rays

Primary and aggregate color centers in lithium fluoride (LiF) crystals and polycrystalline LiF films were produced by an innovative irradiation technique using extreme ultraviolet radiation and soft X-rays generated by a laser-plasma source. This irradiation facility allowed the efficient formation of active color centers on luminescent patterns with submicron spatial resolution on large areas and short exposure times. The method looks promising for the realization of low-dimensionality photonic devices. The optical characterization of the colored structures was performed by means of absorption and photoluminescence measurements on LiF samples colored under different irradiation conditions.     

Additive coloring of CaF<Subscript>2</Subscript> optical ceramic

The specificity of additive coloring of CaF₂ optical ceramic (formation of color centers in it and photothermochemical transformation of these centers in colored ceramic samples) has been considered. Under the same coloring conditions, this process occurs more slowly in ceramics rather than in crystals; at the same time, the limiting concentration of color centers that can be introduced into ceramics is much higher. The photothermochemical transformations of color centers in crystals and ceramics, which occur under illumination at different wavelengths and upon heating, have been studied. The specific features of introduction of color centers into ceramic and their transformation under illumination and heating are likely to be related to the mass twinning of ceramic grains.     

Electrolytic coloration of air-grown sodium fluoride crystals

Air-grown sodium fluoride crystals were colored electrolytically by using a pointed cathode at various temperatures and electric field strengths, which should mainly benefit appropriate coloration temperatures and electric field strengths. , F, M, N₁, N₂ color centers and O²⁻-F⁺ complexes were produced in the colored crystals. Current-time curves for the electrolytic colorations were given, and activation energy for the V color center migration was determined. The formation of the color centers was explained.     

The absorption spectrum of radiation-colored SrCl2-Ce crystals

We investigate the spectra of the x-ray radiation-induced absorption of SrCl₂−Ce crystals over the spectral range 345–830 nm and their temperature transformations in the interval from 77 to 450 K. We found that radiative color centers are characterized by a complex spectrum of induced absorption that contains wide bands of photochromic PC (750, 519, 378 nm) and PC⁺ (620, 446, 340 nm) centers and quasi-linear bands of Ce²⁺ centers. The most significant thermal transformations of radiative color centers occur in the vicinity of the thermostimulated luminescence peak of 394 K, at which the holes of the PC⁺ centers recombine with the electrons of the Ce²⁺ centers. Ivan Franko L’vov State University, 8, Kirilla i Mefodiya St., L’vov 290005, Ukraine. Translated from Zhurnal Prikladnoi Spektroskopii, Vol. 64, No. 4, pp. 545–547, July–August, 1997.