[Cornell University], [Fri. Sept. 13 - Sun. Sept. 15, 2024]

CIQTEK, a leading provider of advanced scientific instrumentation, showcased its cutting-edge Benchtop Electron Paramagnetic Resonance (EPR) Spectroscopy, the EPR200M, at the recent workshop held at the National Resource for Advanced Electron Spin Resonance Spectroscopy (ACERT). The workshop, organized by Cornell University in collaboration with CIQTEK, brought together researchers, industry experts, and practitioners to explore the latest advancements in EPR technology.

During the live demonstration session, attended by over 20 interested attendees, CIQTEK's team presented the features and capabilities of the EPR200M system.

One of the highlights of the demonstration was the on-site sample measurement performed for a visiting delegation from France. The EPR200M showcased its versatility by delivering accurate and reliable results, impressing the attendees with its analytical capabilities, allowing researchers to obtain valuable insights into the electronic structure, magnetic properties, and dynamics of materials across a wide range of disciplines, including chemistry, materials science, biophysics, and more.

The ACERT workshop facilitated valuable discussions and knowledge exchange among participants, fostering collaborations and advancements in EPR technology research. CIQTEK's participation and successful demonstration further solidified its position as a trusted provider of innovative scientific solutions.

Electron paramagnetic resonance (EPR), also known as electron spin resonance (ESR), is a sophisticated spectroscopic technique used to probe paramagnetic materials' electronic and magnetic properties. In this blog, we will explore the concepts, fundamentals, and applications of EPR. 

What is Electron Paramagnetic Resonance:

Electron paramagnetic resonance focuses on the behavior of unpaired electrons in materials with magnetic moments. The central premise of electron paramagnetic resonance is that when these paramagnetic materials are subjected to a magnetic field, their electrons occupy different energy levels due to their spin properties. Irradiating a sample with microwave radiation at a resonant frequency induces transitions between these energy levels, providing valuable information about the electronic structure, dynamics, and interactions of the material.

Electron Paramagnetic Resonance Principle:

EPR spectroscopy relies on quantum mechanical principles and the interaction of electron spins with external magnetic fields. Unpaired electrons have a spin quantum number, which determines their intrinsic angular momentum. When placed in a magnetic field, these electron spins are aligned either parallel or anti-parallel to the magnetic field, resulting in different energy levels. Resonance occurs when the energy difference between these energy levels matches the energy of the incident microwave radiation. By adjusting the strength of the magnetic field or the frequency of the microwaves, resonance conditions can be achieved and studied.

What is EPR Spectroscopy:

EPR spectroscopy accurately characterizes electron spins and their interactions in paramagnetic systems. Very detailed spectra can be obtained by measuring the absorption or emission of microwave radiation. These spectra provide information on a variety of key parameters, including the g factor (anisotropy factor), linewidth (related to electron-electron interactions), relaxation time (describes the spin-lattice and spin-spin relaxation processes), and hyperfine coupling (the interaction of the electron spins with nearby nuclei). Through careful analysis of these parameters, researchers can derive valuable insights into the electronic structure, chemical environment, and dynamic behavior of the materials under study.

CIQTEK EPR Spectroscopy:

With state-of-the-art innovations, the CIQTEK EPR Spectrometer performs high-sensitivity and high-resolution measurements, offering unprecedented accuracy and a wide range of experimental possibilities. The system integrates state-of-the-art magnet design, microwave technology, and data analysis algorithms to enable researchers to explore complex phenomena with extraordinary precision. Whether in materials science, chemistry, or biological research, the CIQTEK EPR spectrometer opens new avenues for studying paramagnetic materials and their applications.

Check CIQTEK Website: https://www.ciqtekglobal.com/

Electron paramagnetic resonance and EPR spectroscopy enable scientists to study the electronic and magnetic properties of paramagnetic materials with great precision.

To determine if your roller shutter motor is dead, you can try the following steps:

Check the power source: Ensure that the motor is properly connected to a power source and that there is a steady supply of electricity. If the power source is not working, the motor will not be able to operate.

Test the remote control: If the remote control tubular motor is controlled by a remote control, check the batteries and try using a different remote control to make sure it's not the cause of the problem.

Check the motor fuse: If the motor fuse has blown, the motor will not be able to receive power and will not operate. Check the manual to determine the location of the fuse and replace it if necessary.

Check the wiring: Check the wiring that connects the motor to the control system and the power source to ensure that it's properly connected and not damaged.

Listen for any noise: If the motor is not working, listen for any noise that may indicate that it is receiving power but not functioning properly.

If the motor still does not work after checking these items, it may be dead and need to be replaced. In some cases, the motor may be repairable, but it's recommended to consult a professional for a proper diagnosis and repair.

The electric roller blind tubular motor is a motor that can drive the roller blind fabric up and down. Its technical characteristics mainly include the following aspects:

1. Motor structure: The electric roller blind tubular motor adopts a cylindrical structure, and is equipped with components such as a motor, a reducer and a control circuit inside, which can realize precise control and roller blind operation.

2. Drive mode: The electric roller blind tubular motor is usually powered by DC power supply, which can realize forward and reverse rotation and speed adjustment through the control circuit, and can also support wireless remote control and APP remote control.

3. Low noise: The electric roller blind tubular motor adopts a precise reducer structure inside, which can effectively reduce noise and make the up and down of the roller blind fabric more stable and quiet.

4. Low power consumption: The electric roller blind tubular motor adopts high-efficiency motor and control circuit, which can achieve low power consumption, and can also achieve energy saving and environmental protection through functions such as sleep mode.

5. Safety: The electric roller blind tubular motor adopts a variety of safety protection measures, such as overload protection, temperature protection and prevention of curtain jamming, etc., which can ensure the safety and stability during use.

In general, the electric roller blind tubular motor has the characteristics of low noise, low power consumption, safety, reliability, and easy control, and is a relatively advanced curtain lifting device.

We’re thrilled to unveil our new demo lab at Loughborough University’s LMCC by SciMed, featuring the cutting-edge CIQTEK SEM3200 Scanning Electron Microscope.

The CIQTEK SEM3200 is a high-performance tungsten filament scanning electron microscope, designed for those who demand excellence in imaging. It delivers exceptional image quality with high-resolution visuals and an expansive depth of field, ensuring rich detail and dimension in every image.

SEM3200 also offers a low vacuum mode, allowing for the direct observation of non-conductive samples without the need for coating. Its extended scalability makes it compatible with various detectors and tools, including SE, BSE, EDS, and EBSD.

For scientists, the SEM3200 provides numerous benefits:

· High-resolution imaging: Achieve stunning clarity and detail.

· Versatility: Flexible sample positioning with a five-axis eucentric stage.

· Scalability: Seamlessly integrate additional detectors and analytical tools to extend functionality.

· User-friendly interface: Simplifies complex imaging tasks, enhancing productivity and research outcomes.

These features empower researchers to push the boundaries of their work, from material science to biological studies.

Abstract:

Titanium dioxide, widely known as titanium white, is an important white inorganic pigment extensively used in various industries such as coatings, plastics, rubber, papermaking, inks, and fibers. Studies have shown that the physical and chemical properties of titanium dioxide, such as photocatalytic performance, hiding power, and dispersibility, are closely related to its specific surface area and pore structure.

Using static gas adsorption techniques for precise characterization of parameters like specific surface area and pore size distribution of titanium dioxide can be employed to evaluate its quality and optimize its performance in specific applications, thereby further enhancing its effectiveness in various fields.

About Titanium Dioxide:

Titanium dioxide is a vital white inorganic pigment primarily composed of titanium dioxide. Parameters such as color, particle size, specific surface area, dispersibility, and weather resistance determine the performance of titanium dioxide in different applications, with specific surface area being one of the key parameters. Specific surface area and pore size characterization help understand the dispersibility of titanium dioxide, thereby optimizing its performance in applications such as coatings and plastics. Titanium dioxide with a high specific surface area typically exhibits stronger hiding power and tinting strength.

In addition, research has indicated that when titanium dioxide is used as catalyst support, a larger pore size can enhance the dispersion of active components and improve the overall catalytic activity, while a smaller pore size increases the density of active sites, aiding in improving reaction efficiency. Hence, by regulating the pore structure of titanium dioxide, its performance as a catalyst support can be improved.

In summary, the characterization of specific surface area and pore size distribution not only aids in evaluating and optimizing the performance of titanium dioxide in various applications but also serves as an important means of quality control in the production process. Precise characterization of titanium dioxide enables a better understanding and utilization of its unique properties to meet the requirements in different application fields.

Application Examples of Gas Adsorption Techniques in Titanium Dioxide Characterization:

1. Characterization of Specific Surface Area and Pore Size Distribution of Titanium Dioxide for DeNOx Catalysts

Selective catalytic reduction (SCR) is one of the commonly applied and researched flue gas denitrification technologies. Catalysts play a crucial role in SCR technology, as their performance directly affects the efficiency of nitrogen oxide removal. Titanium dioxide serves as the carrier material for DeNOx catalysts, primarily providing mechanical support and erosion resistance to active components and catalytic additives, along with increasing the reaction surface area and providing suitable pore structures.

Here is an example of the characterization of titanium dioxide used as a carrier material for DeNOx catalysts using the CIQTEK V-3220&3210 series BET Surface Area & Porosimetry Analyzer. As shown in Figure 1 (Left), the specific surface area of the titanium dioxide used in the DeNOx catalyst is 96.18 m2/g, indicating a larger surface area that provides more active sites as a carrier material, thus enhancing the efficiency of the DeNOx catalytic reactions. The N2 adsorption-desorption isotherm (Figure 1, right) reveals the predominant presence of a type IV isotherm.

Utilizing the BJH model for mesopore size distribution analysis (Figure 2, Left), a concentrated mesopore distribution at 9.50 nm is observed. The SF pore size distribution plot (Figure 2, Right) shows the most probable micropore width of the sample to be 0.44 nm. Studying the effect of specific surface area and pore size distribution on DeNOx catalysts allows the optimization of catalyst design and DeNOx processes, improving nitrogen oxides' removal efficiency.

Figure 1. Specific surface area test results (Left) and

N2 adsorption-desorption isotherm (Right) of titanium dioxide used for DeNOx catalysts.

Figure 2. BJH pore size distribution plot (Left) and

SF pore size distribution plot (Right) of titanium dioxide used for DeNOx catalysts.

2. Characterization of Specific Surface Area and Pore Size Distribution of General Titanium Dioxide

By adjusting and controlling the specific surface area and pore size distribution of titanium dioxide for different applications, the performance and effectiveness of titanium dioxide can be assessed and improved. For example, in the coatings and plastics industries, specific surface area and pore size analysis help optimize the dispersibility and light scattering ability of titanium dioxide, ensuring uniformity and durability of coatings and improving the mechanical properties and weather resistance of plastic products. Furthermore, it provides an important means of quality control in the production process to ensure product consistency.

The CIQTEK V-3220&3210 series BET Surface Area & Porosimetry Analyzer is utilized for the characterization of specific surface area and pore size distribution of titanium dioxide. As shown in Figure 3 (Left), the specific surface area of the titanium dioxide sample is determined to be 18.91 m2/g using the multi-point BET equation. Further analysis of the N2 adsorption-desorption isotherm (Figure 3, Right) reveals a type II isotherm.

By performing NLDFT total pore size distribution analysis (Figure 4), the total pore volume of the titanium dioxide is determined to be 0.066 cm3/g, with micropores accounting for 9.66% and mesopores accounting for 69.72%. In-depth studies on the specific surface area, pore size distribution, pore volume, and their influencing factors provide valuable references for applications and performance optimization of titanium dioxide, thereby meeting the demands for high-performance titanium dioxide in different industries.

Figure 3. Specific surface area test results (Left) and N2 adsorption-desorption isotherm (Right) of a titanium dioxide sample.

Figure 4. NLDFT pore size distribution plot of a titanium dioxide sample

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Ion Gauge Nude for AMAT PVD System

Condition: Brand New

Warranty: 365 days after shipment

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