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AquaPen AP110手持式藻类荧光测量仪是一款用于快速、精确测量水体藻类与蓝藻叶绿素荧光参数的手持式荧光仪、/span>AquaPen有两种探头型号、/span>AP110-C配备比色杯试管测量室,将要测量的水体、悬浊液或培养溶液采集到比色杯中进行测量,配夆/span>455nm蓝色咋/span>620nmLED红色光源,既可以测量叶绿素荧光,又可以测野/span>680nm咋/span>720nm光密度、/span>AP110-P配备了浸入式光学探头,可直接插到要测量的水体、悬浊液或培养溶液中进行测量,也可测量大型藻类、/span>
AquaPen 具备极高的敏感度,可检??.5g Chl/L的叶绿素荧光,可以检测浮游植物浓度极低的自然水体,可用于野外和实验室测量、/span>
AquaPen采用调试式荧光测量技术,可设置多种参数,方便测量多种植物叶绿素荧光。外观小巧,方便携带,设计新颖,操作简单,经济耐用,精度高稳定性好、/span>
应用领域
藻类、蓝藻光合特性研穵/span>
水体藻类含量检浊/span>
光合突变体筛选与表型研究
生物和非生物胁迫的检浊/span>
藻类抗胁迫能力或者易感性研穵/span>
经济藻类育种、病害检测、长势与产量评估
教学
功能特点9/span>
结构紧凑、便携性强+/span>LED光源、检测器、控制单元集成于仅手机大小的仪器内,重量仄/span>180g
功能强大,是叶绿素荧光技术的高端结晶产品,具备了大型荧光仪的所有功能,可以测量所有叶绿素荧光参数
内置了所有通用叶绿素荧光分析实验程序,包括两套荧光淬灭分析程序?/span>3套光响应曲线程序?/span>OJIP–test筈/span>
高时间分辨率,可辽/span>10万次每秒,自动绘凹/span>OJIP曲线并给凹/span>26?/span>OJIP–test参数
AquaPen两种探头型号:比色杯试管测量室,既可以测量叶绿素荧光,又可以测量680nm咋/span>720nm光密度;浸入式光学探头,可直接插到要测量的水体、悬浊液或培养溶液中进行测量,也可测量大型藻籺/span>
FluorPen专业软件功能强大,可下载、展示叶绿素荧光参数图表,也可以通过软件直接控制仪器进行测量
具备无人值守自动监测功能
内置蓝牙不/span>USB双通讯模块+/span>GPS模块,输出带时间戳和地理位置的叶绿素荧光参数图表
配备多种叶夹型号:固定叶夹式(适用于大批量样品快速测量)、分离叶夹式(适用于暗适应测量)、开放叶夹式(适用于温室、培养箱进行监测)、用户定制式筈/span>
可选配野外自动监测式荧光仪,防水防尘设讠/span>
测量程序与功胼/span>
Ft:瞬时叶绿素荧光,暗适应完成后Ft=F0
QY:量子产额,表示光系绞/span>II的效率,等于Fv/Fm(暗适应状?/span>)戕/span>PSII(光适应状?/span>)、/span>
OJIP:快速荧光动力学曲线,用于研究植物暗适应后的快速荧光动态变匕/span>
NPQ:荧光淬灭动力学曲线,用于研究植物从暗适应到光适应状态的荧光淬灭变化过程、/span>
LC:光响应曲线,用于研究植物对不同光强的荧光淬灭反应、/span>
OD:光密度,反映藻类密度(陏/span>AP110-C)、/span>
技术参?/span>
测量参数包括F0、Ft、Fm、Fm’、QY、QY_Ln、QY_Dn、NPQ、Qp、Rfd、Area、Mo、Sm、PI、ABS/RC?0多个叶绿素荧光参数,OD680和OD720(限AP110-C)及3种给光程序的光响应曲线?种荧光淬灭曲线、OJIP曲线筈/span>
OJIP–test时间分辨率为10s(每科/span>10万次),给出OJIP曲线咋/span>26个参数,包括F0?/span>Fj?/span>Fi?/span>Fm?/span>Fv?/span>Vj?/span>Vi?/span>Fm/F0?/span>Fv/F0?/span>Fv/Fm?/span>Mo?/span>Area?/span>Fix Area?/span>Sm?/span>Ss?/span>N?/span>Phi_Po?/span>Psi_o?/span>Phi_Eo?/span>Phi–Do?/span>Phi_Pav?/span>PI_Abs?/span>ABS/RC?/span>TRo/RC?/span>ETo/RC?/span>DIo/RC筈/span>
测量程序9/span>Ft?/span>QY?/span>OJIP?/span>NPQ1?/span>NPQ2?/span>LC1?/span>LC2?/span>LC3?/span>OD(限AP110-C)?/span>Multi无人值守自动监测
测量光:每测量脉?-0.09mol(photons)/m2.s?-100%可调
光化学光9/span>0‒span>1000mol(photons)/m2.s+/span>0-100%可调
饱和光:0‒/span>3000mol(photons)/m2.s+/span>0-100%可调
探头型号9/span>AP110-C试管式?/span>AP110-P探头弎/span>
光源:AP110-C?20nm红光?55nm蓝光测量叶绿素荧光,680nm?20nm红外光测量OD;AP110-P?55nm蓝光
试管容积(限AP110-C(/span>?ml
叶绿素荧光检测限9/span>0.5g Chl/L
检测器9/span>PIN光电二极管,667?50nm滤波?/span>
尺寸大小:超便携,手机大小,1656555mm,重量仅290g
存贮:容野/span>16Mb,可存储149000数据炸/span>
显示与操作:图形化显示,双键操作,待朹/span>8分钟自动关闭
供电:可充电锂电池,USB充电,连续工佛/span>48小时,低电报?/span>
工作条件9/span>0‒/span>55℃,0‒/span>95%相对湿度(无凝结水)
存贮条件9/span>-10‒/span>60℃,0‒/span>95%相对湿度(无凝结水(/span>
通讯方式:蓝牘/span>+USB双通讯模式
GPS模块:内?/span>
软件9/span>FluorPen1.1专用软件,用于数据下载、分析和图表显示,输凹/span>Excel数据文件及荧光动力学曲线图,适用亍/span>Windows 7及更高操作系绞/span>
操作软件与实验结枛/span>
产地:欧洲
参考文?/span>
1. X Chenet al.2018.The secretion of organics by livingMicrocystisunder the dark/anoxic condition and its enhancing effect on nitrate removal.Chemosphere196:280-287
2. C M'Rabetet al.2018.Impact of two plastic-derived chemicals the Bisphenol A and the di-2-ethylhexyl phthalate exposure on the marine toxic dinoflagellateAlexandrium pacificum.Marine Pollution Bulletin126:241-249
3. P Steinrckenet al.2018.Comparing EPA production and fatty acid profiles of threePhaeodactylum tricornutumstrains under western Norwegian climate conditions.Algal Research30:11-22
4. T Kieselbachet al.2018.Proteomic analysis of the phycobiliprotein antenna of the cryptophyte algaGuillardia thetacultured under different light intensities.Photosynthesis Research135(1-3):149-163
5. E Bermejoet al.2018.Production of lutein and polyunsaturated fatty acids by the acidophilic eukaryotic microalgaCoccomyxa onubensisunder abiotic stress by salt or ultraviolet light.Journal of Bioscience and BioengineeringAvailable online 20 January 2018In Press
6. W Nohet al.2018.Harvesting and contamination control of microalgaeChlorella ellipsoideausing the bio-polymeric flocculant -poly-l-lysine.Bioresource Technology249:206-211
7. S Arisakaet al.2018.Genetic manipulation to overexpress rpaA altered photosynthetic electron transport inSynechocystissp. PCC 6803.Journal of Bioscience and BioengineeringAvailable online 5 March 2018In Press
8. J Tanget al.2018.Sustainable pollutant removal by periphytic biofilm via microbial composition shifts induced by uneven distribution of CeO2nanoparticles.Bioresource Technology248:75-81
10. SB Ouadaet al.2018.Effect and removal of bisphenol A by two extremophilic microalgal strains (Chlorophyta).Journal of Applied Phycology 6: 1-12
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