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Home Products Kinetics and Spectroscopy Cryogenic Stopped Flow Product Overview Cryogenic Stopped Flow ​ Uses cryogenics to slow down rapid kinetics processes. ​ Cryo stopped-flow covers temperature ranges below -15°C where traditional stopped-flow experiments are limited. Cryo stopped-flow instruments are now well-established systems in inorganic and bio-inorganic chemistry laboratories where they have proved to be efficient tools used to identify reaction intermediates and define reaction mechanisms. Request a quote Conventional stopped-flow systems are usually limited to -15°C/-20°C because of the materials used in valves and driving syringes. However, some chemical reactions are still too fast to be observed at these sub-zero temperatures. One solution to elucidate the reaction mechanism is to slow down the reaction. By reducing the reaction temperature to -90°C the reaction becomes about 10,000 times slower when compared to ambient temperature, meaning that some events become observable. Cryo stopped-flow covers temperature ranges below -15°C where traditional stopped-flow experiments are limited. Cryo stopped-flow instruments are now well-established systems in inorganic and bio-inorganic chemistry laboratories where they have proved to be efficient tools used to identify reaction intermediates and define reaction mechanisms. Cryogenic option down to -90°C. The cryogenic option extends the range of Bio-Logic stopped-flow to -90°C. It is available for single and double mixing applications. The mixers, the cuvette and the transfer lines are immersed in a cryo-solvent. Two cooling methods are available for the cryo bath: using liquid N2 circulation or using a commercial cryostat. Temperature dependence studies can be carried out from -90°C to +20°C without any reconfiguration. The mixing chamber is connected to the detection system using fiber optics and spectra can be recorded every 400 µs using our fast diode array detectors to fully benefit from the 2ms dead time. Stopped-flow accessories

Contact us Home Contact Us Request a quote Enter contact details First name* Email* Last name* Phone number* Organisation* Address* City/Suburb* Address (2) State or Territory* State or Territory arrow&v Message* Request a Quote Thanks for submitting! ProDigitek 98-100 Station Rd, Seven Hills NSW 2147, Australia +61 2 9674 4222

Home Products Nuclear Physics Equipment CAEN SyS Scintillator Detectors Product Overview Inorganic Scintillator Detectors High Resolution Gamma Ray Spectroscopy. ​ Built-in or Remote Preamplifier types are available depending on application • Option to choose a preamplifier type with a resistive or optoelectronic feedback high energy rate up to 15000 MeV/sec. • Ability to increase energy rate to 20000 Mev/s radiation detection in any spatial orientation made possible by modifications to the portable cryostat during manufacturing. • Energy range from 3 keV to 1500 keV • Input window materials: Aluminium, Beryllium or Carbon-fiber • Excellent peak symmetry and high resolution • HV supply protection if detector is warm • High count rate indicator • Variable cryostat design modifications • Can be transported and stored without cooling Request a quote Application: Each scintillation crystal has its own specific application. For high resolution Gamma ray spectroscopy, NaI(Tl), or CsI(Na) (high light output) are normally used. CeBr3 has exceptional light emission and fast light deexcitation time. For high energy physics applications, the use of bismuth germanate Bi4Ge3O12 (BGO) crystals (high density and Z) improves the Gamma ray energy confinement. (BGO) crystals (high density and Z) improves the Gamma ray energy confinement. ​ NaI(Tl): General scintillation counting health physics environmental monitoring high temperature use ​ CsI(Tl): Particle and high energy physics general radiation detection photodiode readout phoswiches ​ BGO: Particle physics geophysical research PET anti-Compton spectrometers ​ CeBr3: High resolution spectroscopy fast timing particle and high energy physics ultra-low background ​ Standard Set: The Inorganic scintillator assemblies are composed by the following components: the crystal (e.g. NaI(Tl), CsI(Na)) A 14-pin 10 stages PMT ​ This can be matched with MCA PMT base GAMMA Stream , bPAD and bMCA . The assembly can be also provided with a voltage divider, to be matched with TOPAZ-Pico MCA. Scintillator Detector Product Presentation

Home Products Nuclear Physics Equipment CAEN SyS GAMON-S Product Overview GAMON-S Gamma radiation spectroscopy system for real-time radiation monitor. Gamma radiation spectroscopy system based on scintillation detector and Geiger-Mueller counter (integrated neutron detector on request) Onboard web interface for easy configuration of isotope based alarms Spectral analysis and statistical data treatment according to ISO-11929 Robust spectrum stabilization algorithms Big onboard data storage for long autonomous data taking Designed for operating outdoor in extreme weather conditions from -40 to +60 °C Robust case, designed to guarantee IP68, including the power and the communication connectors Design for easy wall and pole mounting Wired and Wireless communication interfaces: USB 2.0, Ethernet, WiFi and 3G/4G LTE Implementing long range, low power wireless platform LoRa™ Configurable list of communication interfaces for selecting primary and backup interfaces Quick and easy to install and commission thanks to onboard web graphical interface Data exchange according to ANSI N42.42 (XML based) Request a quote Overview The GAMON-S is a gamma radiation spectroscopy system designed for outdoor and indoor online radiation monitoring, for early environmental warning and emergency response. It can operate in harsh weather conditions and is protected from rain and moisture. The GAMON-S can be deployed in a wide range of scenario, as in permanent ring monitoring as well as in moving monitoring stations thanks to GPS coordinate logging. The GAMON-S spectrometer runs automatic isotope identification and isotope related dose rate evaluation. The real-time data processing and the defined isotope based alarm allow GAMON-S to detect the presence of artificial nuclides in a short time window and more effectively compared to traditional dose rate meters. The spectroscopy detector is configured to collect gamma interactions in the energy range from 30 keV to 3 MeV. Alternative energy ranges can be configured on request. The full spectrometer is designed to guarantee IP68, including the power and the communication interface connectors. The spectrometer web interface allows the user to easily configure the data acquisition and the isotopic analysis. Security level of the web interface can be configured by the user to avoid unauthorized setting changes. An additional web interface enable the access to multiple GAMON-S spectrometers at once and to visualize the on a map. GAMON-S Data Sheet

Active Technologies Home Products Active Technologies Arbitrary Waveform Generators Waveform Generator Range Arbitrary Waveform Generators 2, 4 AND 8 CHANNEL ARBITRARY WAVEFORM GENERATORS Active Technologies Arbitrary Waveform Generators meet the demand of today’s engineers offering a wide variety of signal types: analog digital mixed-signal multi-channel applications can be covered by Active Technologies instruments. As a result the AWG (Arbitrary Waveform Generator) and AFG (Arbitrary Function Generator) family helps you to generate with confidence waveforms of almost any imaginable shape: complex signals like digital modulations RF stimuli for functional and performance tests radar simulation optical communication electronic warfare Quantum Computing can be created through an easy to use interface. The modular structure of AWGs allows to build systems with 2, 4, 8, 16 or 32 channels and sample rate from 250 Ms/s to 6.16 Gs/s combined with 14 and 16 bit resolution. Moreover the combination with Digital output Channels (up to 32 digital channel per instrument) make each instrument a real MSG (Mixed Signal Generator ) solution. ​ Arbitrary Waveform Generators – Key Features Analog, Digital and Mixed Signal Generation RF & Wireless, Aerospace & Defense, Quantum Computing, Radar & Lidar, Advanced Research, Educational, Real-World signals generation High Speed capabilities combined with High Voltage and High Resolution solutions Extremely Easy To Use User Interface SELECT A MODEL BELOW FOR FURTHER INFORMATION Arb Rider AWG–5000 Arb Rider AWG-4000 Arb Rider AWG-2000 AWG-1102 / 1104 What is a signal generator used for? The signal generators are used to test electronic devices and systems. They are the reference instrumentation family for applications that require the reproduction of real life signals such as Quantum Computing, RF and Wireless applications, IQ modulation, radar and lidar testing, semiconductor test, advance research in electronic, chemistry and physics, aerospace and defense applications. What are the types of signal generators? They are: AFG Arbitrary Function Generators, AWG Arbitrary Waveform Generators , DPG Digital Pattern Generators, SPG Serial Data Pattern Generators, Pulse Generators and Pulse Pattern Generators . Arb Rider AWG-2000 Arb Rider AWG-4022 Arb Rider AWG-4010 FOR EDIT What is an arbitrary waveform generator used for? The AWG’s ability is to create virtually any type of waveform with high precision and accuracy. AWG is the reference instrumentation family for applications that require the reproduction of real life signals such as Quantum Computing, RF and Wireless applications, IQ modulation, radar and lidar testing, semiconductor test, advance research in electronic, chemistry and physics, aerospace and defense applications. What is the difference between arbitrary waveform and function generator? The Arbitrary Waveform Generator is a sophisticated playback system that creates waveforms based on stored digitala data. The AWG’s ability is to create virtually any type of waveform with high precision and accuracy. The Arbitrary Function Generator is based on DDS (Direct Digital Synthesis) and produce the most common test signals used in laboratories and design departments. The AFG Function Generator delivers excellent frequency agility and modulation. What are the parameters of arbitrary waveform generator? The main parameters are: sample rate, memory depth or record length, timing or horizontal resolution, vertical resolution,analog bandwidth, output stage, number of channels, digital channels. What is an arbitrary function generator? The Arbitrary Function Generator is based on DDS (Direct Digital Synthesis) technique and it produces the most common test signals used in laboratories and design departments. The AFG Function Generator delivers excellent frequency agility and modulation. What is a waveform generator used for? AWG and AFG are are the reference instrumentation for applications that require the reproduction of real life signals such as Quantum Computing, RF and Wireless applications, IQ modulation, radar and lidar testing, semiconductor test, advance research in electronic, chemistry and physics, aerospace and defense applications. Do I need a waveform generator? The Arbitrary Waveform Generator can address a wide range of applications from Quantum Computing to education. How do you make waveforms? The waveforms can be created by using the AT Waveform Editor tool that it is a software able to create any kind of analog and digital waveforms. The waveforms can also be created using a third party software and imported in txt or zip format. What does a waveform generator do? The Arbitrary Waveform Generator is a sophisticated playback system that creates waveforms based on stored digitala data. The AWG’s ability is to create virtually any type of waveform with high precision and accuracy. The Arbitrary Function Generator is based on DDS (Direct Digital Synthesis) and produce the most common test signals used in laboratories and design departments. The AFG Function Generator delivers excellent frequency agility and modulation. What are the types of signal generators? They are: AFG Arbitrary Function Generators, AWG Arbitrary Waveform Generators , DPG Digital Pattern Generators, SPG Serial Data Pattern Generators, Pulse Generators and Pulse Pattern Generators . Which waveform is produced by generator? The Arbitrary Waveform Generator cab create virtually any type of waveform and replicate real-world signals.

Home Products Electrochemistry Boosters FlexP0012 Request a quote Essential Range FlexP0012 Powerful EIS with FlexP. A booster designed specifically for electrolyzer/fuel cell characterizations with a continuous maximum current of +/-200 A for a single unit extendable up to +/-800 A by connecting four units in parallel Specifically designed for electrolyzer/fuel cell characterizations, the FlexP0012 boasts a continuous maximum current of +/-200 A for a single unit extendable up to +/-800 A by connecting four units in parallel. ​ The booster is also highly suitable for Redox Flow Batteries (RFB) or large single cells. The FlexP0012 is not only a DC instrument, it is also able to perform EIS measurement up to 10 kHz. The instrument’s configuration can be easily upgraded to reflect user needs without being sent back to the factory. This is made possible by the plug and play capability of its booster modules. The EC-Lab® interface will automatically detect any new configuration ensuring that the transition to the new upgrade occurs seamlessly ​ A case study describing the use of the FlexP0012 is described in the application note AN#63 . Proton Exchange Membrane Water Electrolyzer (PEMWE). FlexP0012 Specifications ​ Up to 12 V Up to 200 A Up to 800 A with 4 units connected EIS: up to 10 kHz Individual Element measurement within a pack FlexP0012 Brochure Electrochemisty Instrument Catalog

Home Products Kinetics and Spectroscopy JTS-150 Product Overview JTS-150 Pump probe and photocatalysis spectrometer. ​ Absorbance/fluorescence kinetics spectrometer Up to 9 detection wavelengths per experiment Data collection at 100ns rate Use leaf or liquid samples Collection sequences from milliseconds to hours long Photosynthesis applications built-in ​ The most flexible system available for probing photokinetic systems; one specifically built for photosynthesis applications. Harness the power of fast kinetics studies using multiple wavelengths with intensity control into a single experiment. Use a single experiment setup and collect data using up to nine wavelengths in real time on a microsecond time scale. Request a quote Complete, Simultaneous Photosynthetic Characterization. The JTS-150 brings the power of fast kinetics studies using multiple wavelengths with intensity control into a single experiment. With the JTS-150 and Smart-Lamp you can use a single experiment setup and collect data using up to nine wavelengths in real time on a microsecond time scale. Perfect time correlation from a single sample allows you to view multi-center reactions in parallel or in sequence. The JTS-150 makes it possible to monitor every photosynthetic reaction in a sample with one setup. In continuous mode data can be collected at a sub-microsecond rate for viewing faster reactions. Absorbance and Fluorescence pump-probe spectrometer. The JTS-150 measures absorbance or fluorescence using combinations of detection LEDs and optical emitters. Pulsed LED measurements (Joliot-type) can be acquired at 10 microseconds between samples (100 kHz). Continuous measurements (not pulsed LEDs) can be acquired at 100 nanoseconds between samples (10 MHz). ​ The JTS-150 has all applications and controls built in and is controlled from a web browser connected via local Ethernet allowing the instrument to be controlled from a PC, Mac or even a Linux based system either directly connected or remotely via the network connection. This software architecture allows a sequencing interface that simplifies sequence design and data collection/analysis for researchers without years of experience and a full opto-electronic suite. Smart-lamp for multi wavelength experiments. With the newly designed Smart-Lamp, you can measure any combination of the following in a single experiment: P700 at 705nm, Plastocyanin at 574nm and 735nm, Electrochromic shift at 520nm corrected at 546nm, Cytochrome b6f at 554nm and 563nm with baseline corrections at 546nm and 574nm, and Fluorescence with or without the flashprobe at 470nm to measure Primary Fluorescence parameters (Fo, Fm, Fv, Fp, Fv’, Fq’, Fm’, F’, Fm) and Calculated Fluorescence parameters (qE , qI, qL, qP, NPQ, max PSII photochemistry, PSII operating efficiency, PSII max efficiency, PSII efficiency factor or QA), OJIP, Fluorescence induction kinetics. The smartLED array enables the observation of interactions between any of the photosynthetic parameters measured by the JTS-10/100 without the need for complicated experimental setups, in a single run, typically without any need for averaging. JTS-150 brochure

Home Products Kinetics and Spectroscopy Freeze quench Product Overview Freeze quench Accessory to enable the conversion of stopped flow/chemical flow to a freeze quench in minute. ​ Freeze quench can be used to study full and intermediate kinetics by trapping reaction intermediates, whose presence has been determined by stopped-flow experiments. Request a quote When chemical quenching is not suitable for a rapid kinetics study, fast freezing the reaction to quench it may be the best option. Freeze quench experiments are divided into three phases: mixing, ageing and freezing. The frozen reaction products are collected and analyzed by EPR/NMR, Mossbauer or XAFS in their solid state. Freeze quench can be used to study full and intermediate kinetics by trapping reaction intermediates, whose presence has been determined by stopped-flow experiments. Freeze quench techniques are also extensively used to study metallic reaction centers in metalloproteins and metalloenzymes. ​ Freeze quench experiments are made possible thanks to the coupling of one premium SFM stopped-flow with the freeze quench accessory. Freezing is carried out by ejection into a -130°C isopentane bath cooled down by liquid N2 circulation. To limit the number of steps required during the packing process and to avoid the risk of warming up the frozen solution, aged solution is ejected directly into a cooled Teflon funnel. The sample holder is attached to the bottom of the funnel cone so the sample can be packed easily with the packing rod (included). Holders are available to collect samples for spectroscopic analysis by EPR/NMR, Mossbauer, and XAFS. 9 ms ageing total time can be achieved in freeze quench mode. The Freeze quench set-up can be converted to a stopped-flow or chemical quench in minutes. SFM Series brochure

Home Products Electrochemistry Boosters HCV-3048 Premium Range HCV-3048 The unmatched combination of Speed & Speed. A booster pack designed specifically for battery pack characterizations. Continuous maximum current of +/-30 A extendable by +/-120 The HCV-3048 booster is designed for battery pack characterizations. ​ The continuous maximum current of +/-30 A for a single unit can be extended up to +/-120 A by connecting four units in parallel. ​ Thanks to the wide bandwidth of HCV-3048, EIS measurements can be performed up to 500 kHz. The instrument configuration can be easily modified, in-situ, to meet the end user’s specific requirements. The instrument does not need to be sent back to the factory to be upgraded thanks to the plug and play capability of the booster modules. ​ The EC-Lab® interface will automatically detect any new configuration ensuring that the transition to the new upgrade occurs seamlessly. Request a quote HCV-3048 Specifications ±30 A / 0-48 V Up to ±120 A with 4 unit in parallel EIS measurement up to 500 kHz HCV-3048 Brochure Electrochemisty Instrument Catalog

Home Products Nuclear Physics Equipment CAEN SyS Topaz-Pico Product Overview TOPAZ-Pico Stand Alone Digital MCA. ​ ​ Fully digital Multi-Channel Analyser (MCA), suitable for medium-energy resolution detectors OEM kits available Full Pulse-Height Analysis (PHA) and Multi-Channel Scaling (MCS) modes of data acquisition Up to 4096 channels for PHA and MCS acquisition Advanced electronic noise reduction algorithms USB 2.0 for data communication and device control Miniature design combining low power consumption with low noise Basic spectrum acquisition and device control software included Optional TTL counter input available Compact MCA: 107x72x19mm In Aluminium Case < 150 Grams Programming libraries available for Windows & Linux Operating System (upon request) Request a quote The TOPAZ-Pico is a compact, stand-alone, digital Multichannel Analyzer (MCA) capable of performing Pulse Height Analysis (PHA) of a signal produced by a standard scintillation detector such as NaI(Tl), LaBr3, CeBr3, etc. ​ TOPAZ-Pico is a compact, stand-alone digital Multi-Channel Analyser (MCA), which is able to perform Pulse Height Analysis (PHA) of the signal produced by a standard scintillation detector such as NaI(Tl), LaBr3 (Ce), LaCl3(Ce), etc. ​ The device is therefore useful for obtaining the energy spectrum from the photon radiation detected by the scintillator, and can be easily interfaced to a typical PC or notebook via a standard USB port for further data transfer and analysis. ​ The MCA is provided with a basic software package that allows to control the device, and to acquire and visualise the energy spectrum. The software incorporates an advanced and easy-to-use “discovery” function that can be used to detect automatically all the BrightSpec MCAs (bMCAs-USB, bMCA-Ethernet and TOPAZ-Pico) in the neighbourhood of the PC that are available for connection. ​ A set of programming libraries is also offered, which makes the incorporation of the TOPAZ-Pico into existing radiation systems or setups very easy. The programming libraries are available for both MS Windows and Linux operating systems. ​ The device is available either in a rugged, pocket-size aluminium box with input and output connectors or as separate Printed-Circuit Board (PCB) for OEM distribution. TOPAZ-Pico Product Presentation

Home Products Nuclear Physics Equipment CAEN SyS GAMON-D Product Overview GAMON-D Gamma dose rate monitoring system for real-time radiation monitor. Wide measurement range from 10 nSv/h to 10 Sv/h with subtraction of intrinsic background Automatic transition between Geiger Muller tubes with advanced data processing Robust case designed to guarantee IP68 Designed for operating outdoor in extreme weather conditions from -40 to +60 °C Wired and Wireless communication interfaces: USB 2.0, Ethernet, WiFi and 3G/4G LTE Implementing long range, low power wireless platform LoRa™ Request a quote Overview The GAMON-D is a versatile gamma dose rate monitoring system designed for early environmental warning and emergency response. GAMON D integrates a low power consumption CPU, to guarantee autonomous operations, including the activation of backup communication interfaces for data transfer in any environmental condition. GAMON-D is intended for a wide range of applications thanks to its high detection efficiency and its extended measurement range. ​ Operative Scenario The GAMON-D gamma dose rate monitoring system is designed to be used in the following scenario: ​ Ring monitor systems around nuclear facilities as nuclear power plants, nuclear fuel processing and spent fuel storage facilities Nationwide environmental monitoring networks Area monitor system in nuclear research laboratories Mobile stations for operator radioprotection ​ GAMON D gamma dose rate monitoring system is available with the following options: ​ Standard dose range: from 100 nSv/h to 1 Sv/h Extended dose range: from 10 nSv/h to 10 Sv/h GAMON-D Data Sheet

Home Products Electrochemistry Materials Research MTZ-35 Impedance Analyzers MTZ-35 An advanced, comprehensive solution for the electrical characterization of materials. ​ An impedance analyzer with the features and specifications necessary for working on a the broad range of applications in the field of materials research. Request a quote An advanced, comprehensive solution for the electrical characterization of materials. ​ ​ A modern materials science lab faces challenging measurements every day, and impedance spectroscopy is a primary tool in materials research enabling the characterization of the electrical properties of materials. ​ With a wide frequency range (10 µHz – 35 MHz) and high-levels of accuracy (0.1% amplitude, 0.05% phase) the BioLogic MTZ-35 impedance analyzer has been designed to tackle even the most difficult measurements required by materials science. ​ The MTZ-35 is the key instrument in integrated solutions for the electrical characterization of materials. These solutions, dedicated to wide-ranging applications and temperature ranges, consist of the MTZ-35 impedance analyzer, a temperature control unit, a sample holder and MT-lab software. The MT-Lab interface allows the control of many temperature control systems (HTF-1100 furnace, ITS, etc.) over a wide temperature range (from -40 to 1100°C). It also allows impedance measurement and the modeling of EIS data with equivalent circuits. Many sample holders (CESH, HTSH-1100, HTCC) covering various materials types (polymers, ceramics, composites, ionic liquids, gels, etc) are compatible with the MTZ-35. MTZ-35 Specifications Generator Frequency Range: 10 μHz to 35 MHz Voltage range DC: ±100 μV to ±10 V Voltage range AC: 100 μV to 10 V Measurement Ranges Inductance 10 nH to 10 kH Capacitance 1 pF to 1000 μF Resistance 1 mΩ to 500 MΩ Basic Accuracy 0.1% MTZ-35 Brochure Material Testing Catalog