ZnS FLIR窗片
ZnS FLIR窗片ZnS FLIR(前视红外)用于红外窗口和热波段(8至14μm)透镜,作为热成像系统(特别是那些遭受恶劣环境)的坚韧的前光学器件。 ZnS FLIR等级比ZnS多光谱等级具有更高的强度。硫化锌通过从锌蒸汽和H 2 S气体合成而产生,经过压片形成片状。 硫化锌在结构上是微晶的,控制晶粒尺寸以产生最大强度。 前瞻性的红外(FLIR)级,其在可见光中是淡黄色和半透明的,在没有进一步处理的情况下使用沉积。 它比多光谱级别更强。 单晶ZnS是可用的,但不常见。在其常用光谱范围内, 散射很低。在用做高功率激光器件时, 需要严格控制材料的体吸收和内部结构缺陷, 并采用最小破坏程度的抛光技术和最高光学质量的镀膜工艺。ZnS在300℃下显著氧化,在约500℃下显示塑性变形,并解离约700℃。 为了安全起见,在正常大气中不应在250°C以上使用硫化锌窗户。详细参数:透射范围: 1.0~13μm折射率: 2.192 at 10.6μm反射损耗: 24.6% at 10.6μm(2个表面)吸收系数: 0.02cm -1 at 3.8μm吸收峰: 30.5μmdn / dT: + 43×10 -6 /℃,3.39μmdn /dμ= 0: n / a密度: 4.08g / cc熔点: 1827°C(见下面注释)热导率: 16.7Wm-1K-1 at 29.7K热膨胀: 6.6×10-6 /℃ at 273K硬度: Knoop 240 with 50g indenter比热容: 469JKg-1K-1介电常数: n / a杨氏模量(E): 74.5GPa剪切模量(G): n / a体积模量(K): n / a弹性系数: Noy available表观弹性极限: 103.4 MPa(15,000 psi)泊松比: 0.29溶解度: 65×10-6g / 100g water分子量: 97.43类别/结构: 多晶立方,ZnS,F43m折射率:No = Ordinary Rayμm No μm Noμm No0.42 2.5160.46 2.4580.50 2.4190.54 2.3910.58 2.3710.62 2.355 0.66 2.3420.70 2.3320.74 2.3230.78 2.3160.82 2.310.86 2.3050.90 2.3010.94 2.2970.98 2.2941.00 2.2921.40 2.2751.80 2.2672.20 2.2632.60 2.263.00 2.2573.40 2.2553.80 2.2534.20 2.2514.60 2.2485.00 2.2465.40 2.244 5.80 2.2416.20 2.2386.60 2.2357.00 2.2327.40 2.2287.80 2.2258.20 2.2218.60 2.2179.00 2.2129.40 2.2089.80 2.20310.2 2.19810.6 2.19211.0 2.18611.4 2.1811.8 2.17312.2 2.16712.6 2.15913.0 2.15213.4 2.14313.8 2.13514.2 2.12614.6 2.11615.0 2.10615.4 2.09515.8 2.08416.2 2.07216.6 2.05917.0 2.04517.4 2.0317.8 2.01518.2 1.998ZnS FLIR圆形窗片订购型号规格(D×L)应用光谱GradeZNSFP9.5-29.5×2.0mmIR FLIR GradeZNSFP19-1W19.0×1.0mm 楔形IRFLIR GradeZNSFP25-225.0×2.0mmIRFLIR GradeZNSFP25-425.0×4.0mmIRFLIR GradeZNSFP25.4-525.5×5.0mm IRFLIR GradeZnS FLIR矩形窗片规格(L×W×H)应用光谱Grade25.0×25.0×5.0mmIRFLIR Grade关于晶体切割:During Chemical Vapour Deposition the small crystallite grains align with the direction of growth, and arenormal to the thickness of the sheet produced. For windows of normal thickness and aspect ratios the alignment of the grain therefore is rarely a problem as they are cut from the grown sheet such that within an optical window the grains align perpendicular to the surfaces. This is optimum orientation for lowest internal absorption and scatter.With prisms, the cutting direction requires more consideration. It is recommended that the thickness of the strip material corresponds to the apex height of the prism. This ensures optimum crystallite orientation for most usualprism applications.For typical 45° prisms the most obvious use of material is shown in (A) but itshould be noted that this is not the optimum orientation.The best choice is (B) and it also permits a higher limit on prism size or conversely allows thinner stock to be used. There is waste at the ends of the strip but this is small and so it may not be quite as economic as (A).Cutting in direction (C) where the entire light beam runs at 90° to the grainstructure should be avoided completely if at all possible. Note that maximum available thickness of ZnSe and ZnS (FLIR) is approximately 60mm. Maximum available thickness of ZnS Cleartran is approximately 30mm