FP-leaf叶夹式植物光谱与叶绿素荧光丈量包
FP-leaf叶夹式植物光谱与叶绿素荧光丈量包用于丈量叶片水平的植物叶绿素荧光、叶片反射光谱及光谱指数等���,蕴含手持式叶绿素荧光丈量仪和植物反射光谱丈量仪������。适于野表大量样品的急剧检测���,宽泛利用于植物胁迫响应、除草剂检测���,生态毒理生物检测、植物反射光谱丈量、色素组成变动、氮素含量变动、产量估测、生态学、分子生物学等������。
测得的数据以图形或数据表的大局实时显示在仪器的显示屏上������。这些数据都能够贮存在仪器的内存里并传输到电脑里������。丈量仪由可充电锂电池供电���,不必要使用电脑即可独立进行丈量������。丈量仪建设全彩色触屏显示器、内置光源、内置GPS和用于固定样品的无损叶夹������。
利用领域
合用于光合作用钻研和讲授���,植物及分子生物学钻研���,农业、林业���,生物技术领域等������。钻研内容涉及光合活性、胁迫响应、农药药效测试、突变筛选、色素含量评估等������。
·植物光合个性钻研
·光合突变体筛选与表型钻研
·生物和非生物胁迫的检测
·植物抗胁迫能力或者易感性钻研
·农业和林业育种、病害检测、长势与产量评估
·除草剂检测
·色素组成变动
·氮素含量变动
·产量估测
·讲授
职能特点
§结构紧凑、便携性强���,光源、检测器、节造单元集成于仅手机大幼的仪器内
§职能壮大���,具备了大型叶绿素荧光仪和反射光谱仪的所有职能���,能够丈量所有叶绿素荧光参数和自动推算常用的植物反射光谱指数���,同时提供荧光动力学曲线图和高精度反射光谱图
§叶绿素荧光检测内置了所有通用尝试法式���,蕴含3套荧光淬灭分析法式、3套光响应曲线法式、OJIP急剧荧光动力学曲线等
§叶绿素荧光检测具备高功夫分辨率���,可达10万次每秒���,自动绘出OJIP曲线并给出26个OJIP–test参数
§专业软件职能壮大:叶绿素荧光分析软件可下载、展示叶绿素荧光参数图表���,也能够通过软件直接节造仪器进行丈量������;植物光谱分析软件能够自动推算内置植被指数、推算用户自界说植被指数、实时显示数据图和数据表
§叶绿素荧光检测具备无人值守自动监测职能
§具备GPS������?���,输出带功夫戳和地理地位的叶绿素荧光参数图表和反射光谱数据
技术参数
1. 丈量参数及法式
1.1叶绿素荧光丈量蕴含F0、Ft、Fm、Fm’、QY、QY_Ln、QY_Dn、NPQ、Qp、Rfd、PAR(限PAR型号)、Area、Mo、Sm、PI、ABS/RC等50多个叶绿素荧光参数
1.2叶绿素荧光OJIP–test蕴含F0、Fj、Fi、Fm、Fv、Vj、Vi、Fm/F0、Fv/F0、Fv/Fm、Mo、Area、Fix Area、Sm、Ss、N、Phi_Po、Psi_o、Phi_Eo、Phi–Do、Phi_Pav、PI_Abs、ABS/RC、TRo/RC、ETo/RC、DIo/RC等
1.3叶绿素荧光丈量法式:Ft、QY、OJIP、NPQ1、NPQ2、NPQ3、LC1、LC2、LC3、PAR(限PAR型号)、Multi无人值守自动监测
1.4植被反射指数:NDVI、SR、绿度指数、MCARI、TCARI、TVI、ZMI、SRPI、NPQI、PRI、NPCI、Carter指数、SIPI、GM1、SR、MCARI1、OSAVI、MCARI、Ctr2、GM2(视具体型号而定)
2. 手持式叶绿素荧光丈量单元:
2.1叶夹类型:固定叶夹式、分离叶夹式、探头式等
2.2PAR传感器:80?入射角余弦校对���,读数单元?mol(photons)/m?.s���,可显示读数���,检测领域400-700 nm
2.3 
丈量光:每丈量脉冲最高0.09?mol(photons)/m?.s���,10-100%可调
2.4光化学光:10-1000?mol(photons)/m?.s可调
2.5鼓和光:最高3000?mol(photons)/m?.s���,11-100%可调
2.6光源:尺度配置蓝光455nm���,可凭据需要建设分歧波长的LED光源
2.7尺寸大������。撼阈���,手机大幼���,134×65×33mm(不蕴含探头)���,沉量仅188g
2.8数据存储:容量16Mb���,可存储149000数据点
2.9显示与操作:图形化显示���,双键操作���,待机5分钟自动关关
2.10供电:2000mA可充电锂电池���,USB充电���,可陆续工作48幼时���,低电报警
2.11工作前提:0–55℃���,0–95%相对湿度(无凝固水)
2.12存贮前提:-10–60℃���,0–95%相对湿度(无凝固水)
2.13通讯方式:蓝牙+USB双通讯模式���,蓝牙在20m距离最大传输速度3Mbps
2.14GPS������?椋耗谥���,最高精度1.5m
2.15软件:FluorPen1.1专用软件���,用于数据下载、分析和图表显示���,输出Excel数据文件及荧光动力学曲线图
3. 手持式植物反射光谱单元
3.1光谱检测领域:
PolyPen RP 410 UVIS光谱响应领域为380-790nm
PolyPen RP 410 NIR光谱响应领域为640-1050nm
3.2光源:氙气白炽灯380-1050nm
3.3光谱响应半宽度:8nm
3.4光谱杂散光:-30dB
3.5光学孔径:7mm
3.6扫描速度:约100ms
3.7触控屏:240×320像素���,65535色
3.8内存:16MB(可存储4000组以上丈量数据)
3.9系统数据:16位数模转换
3.10动态领域:高增益 1:4300������;低增益 1:13000
3.11内置GPS������?椋鹤畲缶龋1.5m
3.12通讯方式:USB
3.13软件职能:自动推算内置植被指数、推算用户自界说植被指数、实时显示数据图和数据表、数据导出为Excel、GPS地图、固件升级���,Windows XP及以上系统合用
3.14光谱反射尺度配件(选配):提供最高的漫反射值(99%)������。光谱平面涵盖UV-VIS-NIR光谱���,保障+/-1%的光学平面������。用于光源和检测器的校准������。
3.15尺寸:15×7.5×4cm
3.16沉量:300g
3.17表壳:防水溅表壳
3.18电池:2600mAh可充电锂电池���,通过USB接口衔接电脑充电
3.19续航功夫:可陆续丈量48幼时
3.20工作前提:温度0~55℃���,相对湿度0-95%(无冷凝水)
3.21存放前提:温度-10~60℃���,相对湿度0-95%(无冷凝水)
利用案例 1:
欧盟委员会结合钻研中心通过无人机遥测技术钻研叶缘焦枯病菌在橄榄树中的习染������。同时通过FluorPen叶绿素荧光仪和RP400光谱仪直接检测叶片的叶绿素荧光和反射光谱植被指数���,用于对照建改无人机遥测数据������。钻研了局颁发在《Nature Plants》(Zarco-Tejada���,2018)������。
利用案例 2:
水稻灌浆期的夜间高温会显著影响水稻的产量������。捷克科学院全球变动钻研中心与国际水稻钻研所合作钻研夜间高温对成熟水稻穗光学个性的变动追踪������。钻研者使用FluorPen手持式叶绿素荧光仪丈量了光合系统有效光化学效能ΦII(也称为有效量子产额QY或ΦPSII)和稳态荧光Fs������。同时使用PolyPen手持式植物反射光谱丈量仪的前期型号WinePen丈量了反射光谱曲线���,并推算了PRI、mSR705、mND705、R470/R570、R520/R675等9项植被指数������。这些植被指数与水稻叶片/穗的光合能力、稳态荧光、叶绿素浓度等缜密有关(Gil-Ortiz R et al. 2020)������。
图1. 分歧种类水稻的有效量子产额QY功夫趋向
图2. 反射植被指数与叶绿素荧光参数的线性回归系数
参考文件
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