斯派克旗舰级SPECTRO ARCOS型ICP光谱仪定义元素分析新高度
SPECTROGREEN革命性新突破 垂直同步双观测技术(DSOI)
DSOI技术提供数倍于传统垂直观测系统的信号强度
TI技术带来的高灵敏度,能够实现对痕量元素进行测量,即使在充满挑战性的环境基体也能确保准确度,避免基体干扰。
响应极其敏锐的LDMOS发生器无需额外的外部水冷装置
新设计的软件系统简洁直观易于使用
就是如此简单!原子吸收光谱法和顺序型ICP的真正替代技术
用于多元素分析的高性能XRF光谱仪
SPECTROCUBE ED-XRF 分析仪
小焦点ED-XRF光谱仪,为贵金属测试而优化
为野外和临线应用提供快速可靠的实验室级分析
基于SDD的 手持式ED-XRF光谱仪系列
市场领先的移动式金属分析仪
对不能承担金属错误损失的您来说是一个简单选择
基于SDD的手持式ED-XRF
高端金属分析真正意义上的革命
完美无瑕的金属分析!
特有的iCAL 2.0单标样标准化专有技术 – 补偿温度波动造成的漂移,平均每天节省30分钟标准化时间
与前代产品相比,检出限提高了30%-40%(例如:铁、铝和铜基)
与之前的型号相比,在待机期间减少了高达64%的氩气消耗
适用于所有原材料和成品的日常分析和精确定量,以及冶炼铸造过程控制(包括氮元素分析) – 覆盖10个标准基体,68类德国原厂工作曲线和59种元素
以最低价格水平提供最高性能和可靠性
最新
Analytical Challenges and Solutions for Mining and Geochemistry
最受欢迎
升级到新一代ICP-OES技术的四个理由
ICP-OES灵活的精细化学品分析解决方案
Effluent Phosphate Recovery & Recycling: The Latest Analytical Solutions
XRF光谱仪的简单、易用而功能强大的定性软件
ED-XRF新技术 新功能“蔚为大观”
选择新一代 ICP-OES执行常规分析任务的十大理由
面向未来的研究:学术界元素分析的新性能和范围
升级到新一代ED-XRF分析仪的五个原因
比较ICP-OES分析仪的等离子视图:轴向,径向,双重,多重视图和新的双重侧面接口
以全新的视角看待等离子体:DSOI技术的优势
哪种ICP-OES光学技术可提供最优越性能:Echelle还是ORCA?
为何火焰原子吸收光谱法(FASS)用户改用ICP-OES
X射线荧光分析聚合物
贵金属分析
用于环境测试的ICP-OES分析的新方法
使用ICP-OES进行高效农学分析
锂离子电池供应链元素分析的近期进展
利用XRF进行元素合规性筛选
能量色散X射线荧光光谱仪分析药品中的元素杂质
利用XRF进行高精度元素分析时,使用高级光谱处理功能降低基体效应
The XRF Principle: The Fundamentals of Energy Dispersive X-ray Fluorescence Technology
空气悬浮微粒的元素分析
九种元素分析对手持XRF分析仪是一种挑战—但OES能轻松解决
用于材料可靠性鉴定(PMI)的光谱分析法
铝回收:通过分析增加价值
利用SPECTRO xSORT手持XRF 光谱仪对废金属进行分类
移动式光谱仪:进出厂检验现场解决方案
用于航空航天和汽车的小零件的高精密度分析
铸铁中碳含量分析
PMT与CMOS:金属分析仪检测器技术的范式转变
Analysis of Tin and its Alloys
Analysis of Wastewater by ICP-OES With Dual Side-on Plasma Observation With a Focus on the USA
Analysis of Wastewater by ICP-OES With Dual Side-on Plasma Observation With a Focus on the European Union
Analysis of Silver and its Alloys
Analysis of Calcium Fluorides
Analysis of Cobalt and its Alloys
Analysis of Titanium and its Alloys
ED-XRF Performance When Using Nitrogen/Air Instead of Helium Purge
Analysis of Lead and its Alloys
Analysis of Magnesium and its Alloys
Measurements With Reduced Argon Flow Conditions
Analysis of Copper-Cobalt Ores by ICP-OES With Dual Side-On Plasma Observation
Analysis of Manganese Ore by ICP-OES With Dual Side-On Plasma Observation
Analysis of Cement According to ASTM C-114
Analysis of Nickel and its Alloys
Analysis of Zinc and its Alloys
Dynamic Measurement Correction – An Efficient Option for ICP Sample Sequences
Cast Iron Analysis Using Spark OES
Analysis of Pd, Pt, and Rh Content in Used Automobile Catalysts by ICP-OES With Dual Side-On Plasma Observation
Analysis of Plastics According to the RoHS Directive
Analysis of Ferro-Alloys Prepared as Fused Beads
Analysis of Graphite and Carbon-Based Components Using ETV-ICP-OES
The Analysis of Iron and Steel (SPECTROMAXx LMX10)
Analysis of Aluminum and its Alloys (SPECTROMAXx LMX10)
Analysis of Copper and its Alloys (SPECTROMAXx LMX10)
Analysis of Animal Feed by ICP-OES With Dual Side-On Plasma Observation
Analysis of Palm Oil
Analysis of High Alumina, Alumino-Silicate, and Other Silicate Refractories Prepared as Fused Beads (SPECTROCUBE)
Limits of Detection in Edible Oil With Dual Side-On Plasma Observation
Analyzing Small Parts, Wires and Thin Sheet Metal Using a Stationary Metal Analyzer
Analytical Solutions for Aluminum Recycling
Analysis in Line-Rich Tungsten Matrix Using High-Resolution ICP-OES
Analysis of Nickel Laterite Ore Prepared as Pressed Pellets (SPECTROCUBE)
Analysis of Nickel Laterite Ore Prepared as Pressed Pellets (SPECTRO XEPOS)
铁矿石和铁烧结矿中次要成分的分析
Analysis of Trace Elements in Diesel Fuels by ICP-OES Using Dual Side-On Plasma Observation
Analysis of 200 g/L NaCl Solutions by ICP-OES With Dual Side-On Plasma Observation
Analysis of Chlorine in NiSO4
Analysis of Aqueous Solutions and Water by ICP-OES With Axial Plasma Observation
Analysis of Aqueous Solutions and Water by ICP-OES with Single-Side-On and Dual-Side-On Plasma Observation
Analysis of High Purity Graphite Using ED-XRF
Analysis of Slag Prepared as Fused Beads with SPECTRO XEPOS
Analysis of Slag Prepared as Fused Beads with SPECTROCUBE
Analysis of Plating Thickness of Decorative Coatings
Analysis of Rhodium Plated White Gold
Quality Monitoring During Manufacturing of PCBs
Limits of Detection in Aqueous Solutions Using the SPECTROGREEN ICP-OES with Twin Interface (TI) in Radial and in Axial Mode
Analysis of Glucose Matrix Samples Using ICP-OES
Analysis of Lactose Matrix Samples Using ICP-OES
Analysis of Fertilizer and Fertilizer Precursor Materials Using Side-On and Dual Side-On Plasma Observation
使用ICP-OES分析大豆粉
Analysis Of Waste Water By ICP-OES With Twin Interface Plasma Observation
使用带有轴向等离子体观测的SPECTRO ARCOS满足药品中元素杂质的新ICH和USP法规。
使用ICP-OES分析奶粉
通过直接吸入和径向ICP-OES分析葡萄酒
使用径向等离子观测ICP-OES分析油品
使用轴向等离子观测ICP-OES分析饮用水
使用径向等离子观测ICP-OES分析水溶液
High Precision Determination of Major Precious Metal Components Using ICP-OES and the Bracketing Technique
Analysis of Impurities in High-Purity Precious Metals With Axial Plasma Observation
Limits of Detection in High-Purity Aluminum Using Axial Plasma Observation
Limits of Detection in High-Purity Nickel Using Axial Plasma Observation
电感耦合等离子体发射光谱仪轴向观测技术分析高纯钴样品
Analysis of Plant Materials Using ETV-ICP-OES With Axial Plasma Observation
Analysis of Lithium Composite Oxide Cathode Materials by ICP-OES With Radial Plasma Observation
ICP-OES结合径向和轴向等离子观测对沉积物进行生态水文学研究的多元素分析
ICP-OES的单径和双侧界面等离子体观察法分析200 g / L NaCl溶液
使用ICP-OES进行单径向和双面界面等离子体观察的油品分析
ICP-OES在单径向和双侧入式界面等离子体观察下的水溶液分析
ICP-OES结合等离子体等离子体分析法分析废水
ICP-OES结合等离子体等离子体分析土壤
生物柴油分析(FAME)
ICP-OES结合双侧等离子体观察分析冷却液
电感耦合等离子体发射光谱仪垂直同步双向观测技术分析玩具中的迁移元素
ICP-OES结合等离子体等离子体观察,分析遵循CLP ILM 05.3协议的环境样品
ICP-OES双重侧面离子对等离子体观察法分析盐酸中的金属杂质
遵循ISO 22241-2的ICP-OES和双向侧面等离子体观察技术对AdBlue®(Urea AUS 32)进行多元素分析
垂直同步双向观测 ICP-OES分析乙醇燃料
电感耦合等离子体发射光谱仪双向观测技术分析土壤和淤泥
电感耦合等离子体 发射光谱仪双向观测技术优化水溶液分析速度
Multi-Element Analysis of Seafood by ICP-OES with Twin Interface Plasma Observation
ICP-OES Analysis of Trace Elements in Water Using Axial Plasma Observation and a Combined Pneumatic-Hydride Generating Sample Introduction
Elemental Analysis of Edible Oils and Fats by ICP-OES
Analysis of Food Supplements by ICP-OES with Axial Plasma Observation
Analysis of Nickel Ore by ICP-OES with Dual-Side-On Plasma Observation
Analysis of Higher TDS Waters by ICP-OES
使用ICP-OES分析水溶液
使用ICP-OES分析油品
使用ICP-OES分析生物柴油
使用ICP-OES分析土壤和淤泥
使用ICP-OES对油品中磨损金属进行低成本高效的分析
Analysis of High Alumina, Alumino-Silicate, and Other Silicate Refractories Prepared as Fused Beads Using ED-XRF (SPECTRO XEPOS)
Analysis of Raw Material Prepared as Fused Bead in the Cement Industry
Analysis of Sulfur in Petroleum and Petroleum Products According to ASTM D4294
使用ED-XRF进行空气微粒元素分析
使用ED-XRF进行地质材料压片的痕量元素分析
生物地球化学:使用ED-XRF分析沉积物中的微量元素
石化产品中二十七种元素的分析
使用ED-XRF分析高炉炉渣
使用能量色散X射线荧光光谱法进行高精度分析
在化妆品生产过程中使用ED-XRF进行过程控制
使用ED-XRF对化妆品中重金属进行筛查和量化
可可中的微量元素
使用ED-XRF分析食品
脂肪酸甲酯(FAME)中硫和痕量元素含量分析
含萤石矿物的分析-ED-XRF筛选氟含量
ED-XRF分析玻璃中的氟
生物地球化学–泥炭样品中微量和微量元素的分析
使用配备XRF Analyzer Pro软件的SPECTRO XRF分析仪确认符合21 CFR Part 11规定
使用SPECTRO XEPOS分析植物材料中的有毒和营养成分
分析肥料中的植物养分,微量元素和重金属
Analysis of Crude Oil Using ED-XRF
Analysis of Trace Elements and Fluorine in Pressed Pellets of Geological Materials
使用ED-XRF光谱仪(SPECTROCUBE)进行贵金属测试
根据RoHS指令进行塑料分析
使用SPECTROCUBE联合应用分析各种石化产品中的24种元素
根据ISO 13032和ASTM D 7220-12分析汽车燃料中的超低硫含量
SPECTROCUBE 分析高炉炉渣
SPECTROCUBE ED-XRF 光谱仪快速准确地测定 应用报告:三元催化剂中的Rh、Pd和Pt含量
使用ED-XRF光谱法进行贵金属测试
使用ED-XRF光谱法临线分析微量营养素
使用ED-XRF光谱法依据ASTM D4294对燃料中的硫进行临线分析
使用ED-XRF光谱法对动物饲料中的铅进行近线分析
先进ED-XRF光谱法加速井下特性鉴定
使用便携式ED-XRF光谱仪在野外进行土壤和下水道淤泥分析
使用ED-XRF光谱法近线分析检测食品中的金属
使用ED-XRF光谱法进行钢板、铝板涂层重量临线分析
Portable ED-XRF for Chemical Characterization in Additive Manufacturing
碳水平:分析、检查和分拣钢合金时的关键因素
为改善废料回收而分析铝合金中的轻元素
改善针对钢构件PMI的XRF分析以预防腐蚀
分析固体金属样本
二手汽车催化转化器中Rh,Pd和Pt的分析
铝及其合金的分析
钢铁分析
铜及其合金的分析
镍及其合金的分析
锌及其合金的分析
The Analysis of Tin and its Alloys
铅及其合金的分析
The Analysis of Cobalt and its Alloys
纯镁及镁合金的分析
The Analysis of Titanium and its Alloys
The Analysis of High-Purity Zinc
The Analysis of High-Purity Aluminium
The Analysis of High-Purity Lead
The Analysis of High-Purity Copper
高纯金的分析
The Analysis of High-Purity Silver
Detection and Analysis of Inclusions Using Single Spark Evaluation Technology
The Analysis of Cast Iron
钢铁铸铁分析
分析电子制造中的浸锡污染
Why You Should Give SPECTRO's Instrument Online Demonstrations a Try
A Spectrum of Innovations for Demanding Elemental Analysis
SPECTRO ARCOS — Evolving Elemental Analysis to the Next Level
SPECTRO ARCOS MultiView
Curing the Bench Space Blues with SPECTROGREEN
Pass/Fail Sorting — The Quick Identification of the Good and the Bad
From Waste Water Treatment to Phosphate Recovery – Elemental Analysis Using ICP-OES and ED-XRF
Mobile Metal Analyzers: Displaying Results on an External Device And Remote Control
The Analysis of Cast Iron Using Stationary and Mobile Metal Analyzers
Determination of Elemental Composition of Biomass Including Solid Recovered Biofuels by ED-XRF
Palm Oil: Elemental Analysis and Provenance Testing
Improving the Precision and Accuracy of ICP-OES Analyses
Thickness and Composition Analysis of Coatings, Layers and Decorative Platings on Metals Using XRF Technology
Cement Industry Quality Assurance and Production Monitoring With ED-XRF
Mobile and Handheld Metal Analyzers: On-The-Spot Solutions for Incoming and Outgoing Inspection
Analysis of Fuels and Biofuels Using ICP-OES and ED-XRF
Analysis of Ni Laterite Ores Using ED-XRF
Analyzing Small Parts Using Mobile and Stationary Metal Analyzers
Analyzing Samples With Complex Spectra Using Modern ED-XRF
Elemental Analysis of Fine Chemicals Using the New SPECTRO ARCOS ICP-OES
Mobile Metal Analysis – How Can Measurement Results Be Documented According to Requirements
Analysis of Slag, Ferro-Alloys and Refractory Materials Using ED-XRF
Lithium Ion Battery Material Analysis With ICP-OES and ED-XRF
10 Benefits for Routine Labs From Improved ICP-OES Technology
Elemental analysis of liquid petroleum products with ICP-OES and ED-XRF instruments
Which ICP-OES/ICP-AES optical technology offers superior performance: Echelle or ORCA?
Considerations for High Performance Agronomy Analysis using ICP-OES
Which ICP-OES/ICP-AES Plasma Interface is Best for Your Research: Axial-View, Radial View, Dual-View, or new MultiView?
ICP-OES Technology Advancements Addresses the Axial/Radial Dilemma on Plasma Viewing While Offering Improvements in Overall Performance
Dual Side On Interface (DSOI): Better Than Dual-View ICP
The Search for the Single ICP-OES for Environmental Testing
ICP-OES/ICP-AES or Flame AAS – Which Spectrometer Technology is Best for You?
Advances in XRF and ICP-OES for Plant Tissue and Soil Analysis
ICP-OES: Is There an Alternative to the Classical Dual-View Technique?
ICP Analyzer Pro Software Demonstration
Analysis of Precious Metals with ICP-OES
Analysis of Trace Elements in Brine Solutions Using Radial ICP-OES
ICP-OES: What Does Multiview Technology Mean?
ICP-OES Smart Background Correction for Complex Matrices
ICP-OES Plasma Observation Technologies and Their Application
Alternative Uses: Biofuels Analysis with XRF & ICP-OES
Elemental Analysis of Foods, Cosmetics, and Pharmaceuticals
Fertilizer Analysis: From Raw Materials to Final Product QC with XRF & ICP-OES
Plant Tissue Analysis: Elemental Composition from Screening to Traces with XRF and ETV-ICP-OES
Soil Analysis: Heavy Metal Screening with Portable XRF & Micronutrients with ICP-OES
The Harvest: Elemental Analysis for Organic Material Screening & Food Analysis with XRF & ICP-OES
Analysis of Fuels and Additives Using ICP-OES and ED-XRF
High Precision Analysis of Precious Metal Alloys in the Refinery, in Jewelry Manufacturing and Hallmarking
Elemental Analysis of Powdered Metals and Additively Manufactured Parts
Analysis of Food Using ICP-OES
Valuation of Precious Metal Alloys, Incoming Inspection at Refinery
Analysis of Recycling Samples for Their Precious Metal Content
Benefits of Adaptive Excitation in ED-XRF
How to Analyze Gemstones Using ED-XRF Equipment
Precious Metals Testing With ED-XRF Spectrometry
SPECTROCUBE Portable EDXRF Analyzer — the Specialist for the Elemental Analysis of Petroleum Products, Liquid Fuels and Lubricants
SPECTROCUBE — Portable ED-XRF Elemental Analysis Optimized for Your Application
SPECTROCUBE — Future-Proof XRF Solutions for Elemental Compliance-Screening
Precious Metals Testing With Portable EDXRF Spectrometry
Raw Materials Screening with SPECTRO XRF Ident Software
Decorative Coatings: Analysis of Plating Bath Solutions and Coating Thickness Using XRF
Using ED-XRF for Screening of Pharmaceutical Products for Elemental Impurities According to ICH Q3D
Nondestructive Quantitative Analysis of low Amounts of Powder and Liquid Samples Using XRF
The New SPECTROGREEN – the Perfect fit for Your ICP-OES Elemental Analysis Tasks
Data Analysis in the Rearview Mirror - SPECTRO ICP Analyzer Pro Software
Five Reasons for Upgrading to a Next-Generation ED-XRF Analyzer
Analysis of Metals & Minerals in Food with ED-XRF
Future-Proof Academic Research with SPECTRO XEPOS ED-XRF
High Throughput Analyses with ED-XRF
SPECTRO’s TurboQuant for Waste Analysis with ED-XRF
ED-XRF Can Do What Now?
Using X-ray Fluorescence Spectrometry for Compliance Screening & Quality Control of Multilayer Structures in the Electronics Industry
Analysis of Metals Using a Portable Spectrometer
SPECTRO XEPOS ED-XRF Technology: A Quantum Leap
The Rise of ED-XRF: Key Technology Advancements and Implications for Your Analyses
High Precision Elemental Analysis Using an ED-XRF Spectrometer
Elemental Analysis of Liquid Petroleum Products with a Focus on ED-XRF
Improved Laboratory Profitability Via Next-Gen ED-XRF Instrumentation
Advances In ED-XRF and ICP-OES Technology Improve Chemical and Petrochemical Analysis
Future-Proof Solutions for Elemental Compliance Screening Using XRF
Introducing New SPECTROSCOUT ED-XRF Analyzer
Moving your Lab to the Line with a Portable ED-XRF Spectrometer
Metalmorphosis
Cast Iron Analysis Using Advanced OES Technology
Elemental Analysis of Precious Metals Using SPECTROLAB S
Automation Solutions for Spark OES
SPECTRO Metal Database – Your All-In-One Tool For Detailed Information on Metals and Its Alloys
Four Reasons Why You Should Upgrade to Next-Generation ICP-OES Technology
High-Performance Agronomy Analysis Using ICP-OES
See What Your Lube Oil Analysis Is Missing: 27 Elements, Only 1 Method
Everything You Want in Your Next Precious Metals Spectrometer
Picking the Perfect Analysis for Your Precious Metals Application
Four Things Your Next Environmental ICP-OES Should Be
SPECTROMAXx with iCAL 2.0: Five Reasons to Make the Most Intelligent Spectrometer Choice
S.M.T. Analyzes Large Metal Samples On-Site Using SPECTROTEST
SPECTROMAXx: Helping CASS Process End-Of-Life Metals For Greener Recycling
SPECTROPORT: 加利福尼亚州运输部使用分析仪对道路上的钢结构进行可靠的金属分析
茂名威特信赖 SPECTROTEST,现场的金属材料精确定量分析
SPECTROLAB S 火花直读光谱仪:为奥钢联的钢铁分析应用 提供革命性提升
BYD optimizes Metal Testing Efficiency With SPECTROTEST and SPECTROPORT
SPECTRO ARCOS为Eurofin提供高通量农艺分析
SPECTRO XEPOS: 欧莱雅化妆品分析 取得了良好结果
SPECTRO XEPOS使润滑油分析达到Q8Oils的极限
SPECTRO ARCOS MV: Advanced Analysis for Agronomy and More at the University of Padua
石油化工应用的理想分析仪
Manual SPECTRO ARCOS
Manual SPECTROGREEN
Manual SPECTRO GENESIS
Manual SPECTRO XEPOS
Manual SPECTROCUBE C
Manual SPECTROCUBE D
Manual SPECTRO MIDEX Precious Metals
Manual SPECTRO MIDEX
Manual SPECTROSCOUT
Manual SPECTRO xSORT
Manual SPECTROTEST
Manual SPECTROPORT
Manual SPECTROLAB S
Manual SPECTROMAXx
Manual SPECTROCHECK
尽管温度波动大,仍可实现突破性的稳定性
重要升级 成为工业领先的解决方案
Verification of duplex steels by its nitrogen content
On-the-spot sorting, identification, verification, and analysis of metal alloys
Upgrade to SPECTROTEST for Even Faster Readiness on the Spot
Boron Steels – When High Wear Resistance is Required
Standardization can be smart - that‘s what iCAL 2.0 is
SPECTRO ARCOS 宣传册
SPECTROGREEN 宣传册
SPECTRO GENESIS 宣传册
SPECTROCUBE Overview 宣传册
SPECTRO XRF Layers Brochure
SPECTROLAB S 宣传册
SPECTROMAXx 落地式直读光谱仪
SPECTROMAXx台式直读光谱仪
产品概述-一系列创新