<h3>Lunch &amp; learn tips &amp; tricks series 2026 – part 1</h3>In modern analytical laboratories, efficiency, consistency, and data confidence are essential. Whether you are operating an ICP-OES or ICP-MS system, the way you use your software can significantly influence productivity and analytical performance. In the first session of our Lunch &amp; Learn Tips &amp; Tricks Series, we focused on one of the most common themes raised by users: how to navigate <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/products/1489">Qtegra </a>software more effectively and optimize everyday workflows.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/Thermo_Fisher_Scientific_Mastering_Qtegra_Software_Practical_Strategies_to_Improve_Your_Daily_Lab_Workflow_3d35454782.jpg" alt="Thermo Fisher Scientific: Mastering Qtegra Software: Practical Strategies to Improve Your Daily Lab Workflow" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_Thermo_Fisher_Scientific_Mastering_Qtegra_Software_Practical_Strategies_to_Improve_Your_Daily_Lab_Workflow_3d35454782.jpg 245w," sizes="100vw" width="1024" height="512">This session explored three key areas in detail: understanding the structure of Qtegra and the Configurator, using the Dashboard as your operational control center, and building smarter, more efficient LabBooks. Below is a structured recap of the key insights shared during Part 1.<h3>Understanding the structure of Qtegra</h3>One of the most valuable features of Qtegra software is its consistency across multiple instrument platforms. Whether you are working with the <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/products?category=227&amp;instrumentationItems=84&amp;manufacturerItems=3&amp;search=icap+pro">iCAP PRO ICP-OES</a>, the <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/products?category=232&amp;instrumentationItems=83&amp;manufacturerItems=3">iCAP MX ICP-MS</a>, the iCAP 7000 OES, or Qnova ICP-MS systems, the interface and workflow logic remain familiar. This consistency reduces the learning curve when transitioning between instruments and supports standardised training across laboratories.Qtegra consists of two primary components: the Qtegra application itself and the Configurator.<ul><li>The Qtegra application is where you directly interact with your instrument. It is used to create LabBooks, control the instrument, execute analyses, and review results.</li><li>The Configurator, in contrast, defines how your system behaves at a deeper level. It controls system-level settings that underpin daily operation. Within the Configurator, users can manage features such as Fast Uptake setup, drain sensor configuration, wavelength libraries for ICP-OES systems, the Reaction Database for ICP-MS systems, and user access permissions.</li></ul>Understanding the distinction between these two components helps users troubleshoot more effectively and ensures that system configuration aligns with laboratory requirements.<h3>Using the dashboard as your central hub</h3>When Qtegra is opened, the first screen presented is the Dashboard. The Dashboard functions as the central hub for instrument monitoring and control. From this location, users can view instrument status, monitor live operating parameters, access tuning tools, review performance checks, and identify error or interlock notifications.<ul><li>For ICP-OES users, the Dashboard provides access to tune sets, source settings, AutoPeak alignment, autotuning functions, and live views such as Plasma TV. These tools allow users to confirm that the plasma and optical system are performing as expected before analysis begins.</li><li>For ICP-MS users, the Instrument tab within the Dashboard provides access to autotune routines, performance report summaries, gas flow settings, nebuliser adjustments, operating mode selection such as Standard, KED, or CCT modes, IntelliLens control, and real-time data streams.</li></ul>The Dashboard should be used as a structured checkpoint before running any analysis. Confirming that all parameters are within acceptable ranges reduces the likelihood of interruptions and supports consistent performance throughout the run.<h3>The get ready workflow: structured instrument preparation</h3><ul><li>The Get Ready function, which is launched directly from the Dashboard, provides a guided preparation workflow. This feature is designed to ensure that the instrument is fully configured and operating correctly for the selected method before analysis begins.</li><li>Within Get Ready, users can access scheduling tools that automate warmups, standby routines, shutdowns, and maintenance checks. These tools are particularly beneficial for laboratories operating multiple shifts or managing variable workloads.</li></ul>For ICP-MS systems, the Get Ready workflow includes automated performance checks, autotune routines, and controlled warm-up conditions. These routines verify that the instrument is operating within its expected performance range.By following the structured steps within Get Ready, laboratories can reduce the risk of missed preparation tasks and maintain day-to-day analytical consistency.<h3>Building smarter LabBooks</h3>The LabBook forms the foundation of every analytical sequence in Qtegra. A carefully constructed LabBook improves efficiency, reduces setup errors, and simplifies data review.Users can create a LabBook from scratch or begin with a template. Templates are particularly useful for laboratories that integrate with LIMS systems or import sample lists via CSV files, as they promote standardisation and consistency.<h4>Defining analytes</h4><ul><li>For ICP-OES methods, users must select appropriate wavelengths and evaluate potential spectral interferences.&nbsp;</li><li>For ICP-MS methods, users select the required masses, consider isobaric and polyatomic interferences, and use the Reaction Database to support reaction mode selection.</li></ul>Careful analyte selection at this stage helps prevent complications later in the analytical workflow.<h4>Configuring acquisition parameters</h4>Acquisition parameters define how the instrument collects data.<ul><li>For ICP-OES systems, this includes selecting viewing modes, choosing wavelength ranges such as iFR or eUV, and defining integration times.</li><li>For ICP-MS systems, this includes selecting operating modes such as Standard, KED, or CCT, configuring Reaction Finder options, enabling Intelligent Matrix Handling, and defining digital trigger settings.</li></ul>Thoughtful parameter configuration ensures that data quality objectives are met without unnecessary reanalysis.<h4>Using intelligent uptake and rinse</h4>The Intelligent Uptake and Rinse feature detects when the sample or rinse solution reaches the nebuliser. This ensures consistent timing across samples and improves overall throughput. In high-throughput environments, this feature contributes to both efficiency and reproducibility.<h4>Calibration and quantification strategy</h4>Calibration design is central to reliable quantification. Qtegra allows users to manage global standards, configure dilution tools, select calibration fit types, assign internal standards, and establish quality control samples.For ICP-OES systems, users can define standard ranges and switch points. For SemiQuant workflows, Relative Sensitivity Factors can be applied.Establishing these parameters during LabBook creation ensures that data validation is straightforward once analysis is complete.<h4>Autosampler and sample list setup</h4>For laboratories using the <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/products/1715">iSC-65 autosampler</a>, features such as StepAhead, custom rack definitions, colour-coded sample views, and visual integrity checks support efficient sequence management.When constructing the sample list, users should clearly define sample types, establish a logical sequence order, and configure column layouts appropriately. Setting flags and limits during initial setup simplifies the data review process and supports quality assurance.<h3>Why workflow optimisation matters</h3>Optimising Qtegra usage does not require learning new software features. Instead, it involves using existing tools more strategically. By treating the Dashboard as a pre-run checkpoint, using Get Ready consistently, and constructing LabBooks with long-term efficiency in mind, laboratories can reduce downtime, improve reproducibility, and strengthen confidence in analytical results.<h3>Looking ahead to part 2</h3><blockquote>In Part 2 of the Qtegra Tips &amp; Tricks series, we will focus on post-analysis best practices. Topics will include interpreting signal intensities, reviewing calibration performance, evaluating recoveries and readbacks, applying flags effectively, exporting data, and implementing practical workflow improvements discussed in Part 1.</blockquote>By building a structured approach to both preparation and data review, laboratories can transform routine analysis into a streamlined, reliable, and repeatable process.We look forward to continuing the discussion in Part 2.<h5>Acknowledgement</h5>I would like to thank Matthew Gregory Field Applications Scientist, North EMEA, Trace Elemental Analysis and David Fishwick Field Applications Scientist, North EMEA, Trace Elemental Analysis for the support on this blog and the webinars<h4>Sign up for our webinars live and on demand.</h4>English<ul><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/webinar/5795">Lunch and Learn Tips and Tricks Series: Qtegra Part 1</a></li><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/webinar/5976">Lunch and Learn Tips and Tricks Series: Qtegra Part 2</a></li><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/webinar/5977">Lunch and Learn Tips and Tricks Series: Trace Elemental Analysis (ICP-OES &amp; ICP-MS)</a></li><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/webinar/5978">Trace Elemental Analysis: Ask the Expert</a></li></ul>Deutsch<ul><li>19. März 2026 <a target="_blank" rel="noopener noreferrer" href="https://event.on24.com/wcc/r/5179134/393E071E3B501943730958BA6203F477">Interne Standards in der ICP-OES: Ein Praxisguide für zuverlässige Qualitätssicherung im Labor</a></li><li>18. Juni 2026 <a target="_blank" rel="noopener noreferrer" href="https://event.on24.com/wcc/r/5179292/AE4C576B6A54D1AC182F7F77573D380F">Fehler reduzieren, Durchsatz steigern: Autoverdünnung mit PrepFast am ICP-MS</a></li><li>17. September 2026 <a target="_blank" rel="noopener noreferrer" href="https://event.on24.com/wcc/r/5179423/B5019C560431BADCA2A76E54E4EFE56F">ICP-OES smarter nutzen: Probendurchsatz erhöhen, Ressourcen sparen</a></li><li>17. Dezember 2026 <a target="_blank" rel="noopener noreferrer" href="https://event.on24.com/wcc/r/5179530/94EEDD1F56138F5EEE2AF24E29E6C12A">Qtegra ISDS Software Unlocked – Live im Expertengespräch</a></li></ul>Visit us on&nbsp;<a target="_blank" rel="noopener noreferrer" href="https://www.linkedin.com/showcase/72003132/admin/dashboard/">LinkedIn:</a>&nbsp;#Qtegra, #ICPMS, #ICPOES, #TraceElementalAnalysis<blockquote><h5>Petra Gerhards</h5>Petra Gerhards, Dipl-Ing, is Regional Marketing Manager of GC and GC-MS for EMEA at Thermo Fisher Scientific. She has more than 29 years of experience in the fields of GC-MS, SPE and LC-MS. Since joining the regional team she has contributed to workflow solutions combining vials and closures with SPE solutions, GC-MS and LC-MS. She works with KOL's on data for regional specific marketing campaigns, organizes in-house seminars and works on customer specific solutions. Her main expertise is in the field of doping and drugs-of-abuse analysis.</blockquote>

Mastering Qtegra Software: Practical Strategies to Improve Your Daily Lab Workflow

Since the beginning of this year, a project to develop a light-based electron microscope, LightEM, has been underway at CEITEC Brno University of Technology (BUT). The principal investigator is Andrea Konečná from CEITEC BUT and the Faculty of Mechanical Engineering BUT, who has secured support for the project through the prestigious ERC CZ program. Over the next five years, her research team aims to develop and test a light-based electron microscope. This technology would allow scientists to adaptively modulate the electron beam during experiments or observe processes over time – capabilities that are not possible with conventional electron microscopes.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_4_2062655721.jpeg" alt="CEITEC/Václav Koníček: Microscope of the Future: Combining Light and Electrons Wins Prestigious Grant: Andrea Konečná's group" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_4_2062655721.jpeg 235w," sizes="100vw" width="1600" height="1067">Over the coming five years, Andrea's team will work on improving existing electron microscopes. Her project, Light-Based Electron Microscope (LightEM), focuses on the interaction between electrons and light and could help overcome some of the limitations of classical electron microscopy. “We are trying to improve the electron beam. What we want to do is, figuratively speaking, shoot an intense laser beam into the microscope and influence electrons using light. Simply put, we aim to create adjustable ‘glasses’ for the electron microscope using light and change how optics is traditionally done in electron microscopy,” explained Andrea.According to her, this approach should bring higher resolution, new imaging techniques, and the ability to study dynamic processes. “With light, the resolution should be even better. Moreover, we could image sensitive samples, which is usually problematic. We could also observe processes over time –&nbsp;stimulate a sample with light, for example by heating it, and then dynamically monitor what is happening,” she added.<h3>The microscope will offer better resolution and new imaging techniques</h3>Andrea points out that standard electron microscopes use magnetic lenses to image and focus electrons onto a sample, but these lenses have imperfections that limit resolution. The best electron microscopes in the world therefore use many lenses – similar to professional camera lenses – to compensate for these defects and achieve atomic resolution. A light-based electron microscope could change this.“We would like to demonstrate that such complex lens systems –&nbsp;whose production, alignment, and operation are very expensive and demanding –&nbsp;could be replaced by a specially modulated laser beam. Compared to conventional lenses, a laser beam can be used not only for magnification, reduction, or aberration correction, but also offers great flexibility and the possibility to create new ‘exotic’ types of electron beams. Electrons don’t have to be focused only into a point; we can create a beam shaped like a ‘donut.’ In addition, the beams could be modulated quickly and adaptively,” said Andrea.According to her, such a modified microscope could be used in many fields. “Thanks to the possibility of light-based modulation of the electron beam during experiments, we could more efficiently image sensitive samples, which is crucial for biology. Or we could detect defects in materials and semiconductor components more quickly,” she added.This is highly unique research with no equivalent in scope, either in the Czech Republic or abroad. According to Andrea, only a few studies on the topic have been published so far. “At the time I was writing the grant, only a few theoretical and experimental papers had demonstrated the basic concept –&nbsp;that electrons can be focused or otherwise modulated using a laser beam. But they did not go as far as we would like, namely to create a prototype microscope where part of the standard electron optics is replaced by a laser beam,” she said.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_3_1ec4c49bf5.jpeg" alt="CEITEC/Václav Koníček: Microscope of the Future: Combining Light and Electrons Wins Prestigious Grant: Andrea Konečná's research" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_3_1ec4c49bf5.jpeg 235w," sizes="100vw" width="1600" height="1067"><h3>Unique research supported by the Ministry of Education</h3>The project’s strong potential is confirmed by the fact that Andrea Konečná received an ERC CZ grant from the Czech Ministry of Education, Youth and Sports. The program aims to support researchers who applied for a European ERC grant, succeeded in evaluation, but were not funded due to limited resources.“There is enormous competition within the European ERC program. I submitted this project twice and both times advanced to the second round, where I presented it and discussed it with the panel. Each time I received an A rating, but unfortunately without funding. The Ministry looks at these European evaluations and ultimately supported my project. To be honest, it is mainly about prestige, because otherwise the conditions are the same. The project still runs for five years, and the Ministry supported it in full, so we receive the same funding we would have received from the European Union,” Andrea noted.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_2_3114b2e414.jpeg" alt="CEITEC/Václav Koníček: Microscope of the Future: Combining Light and Electrons Wins Prestigious Grant: Andrea Konečná's research" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_2_3114b2e414.jpeg 235w," sizes="100vw" width="1600" height="1067"><h3>Two prestigious grants – and motherhood alongside</h3>A few years ago, Andrea Konečná also received the prestigious JUNIOR STAR grant from the Czech Science Foundation, which supports outstanding early-career researchers. She is currently the principal investigator of two major projects, while also balancing motherhood since last year.“Maybe it’s still too early to evaluate, because my daughter is still small and I was on maternity leave for some time. But honestly, it is demanding. At the same time, the flexibility of our work makes it easier than in other professions. Moreover, the JUNIOR STAR project is already in its fourth year, and several excellent PhD and master’s students have joined during that time, so many smaller projects were able to continue even during my maternity leave. I’m also happy that several of these colleagues will now join the ERC CZ project,” she concluded.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_1_8369f441d5.jpeg" alt="CEITEC/Václav Koníček: Microscope of the Future: Combining Light and Electrons Wins Prestigious Grant: Andrea Konečná" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_CEITEC_VUT_Vaclav_Konicek_Mikroskop_budoucnosti_Spojeni_svetla_a_elektronu_ziskalo_prestizni_grant_1_8369f441d5.jpeg 235w," sizes="100vw" width="1600" height="1067"><h3>A major success for CEITEC Brno University of Technology</h3>“I greatly appreciate the success of Andrea Konečná, who managed to succeed in a highly competitive environment. It is the result of long-term high-quality scientific work and significant personal dedication. At the same time, I am pleased that at BUT, we are systematically creating conditions to support excellent research. One of the key tools is the Research Excellence Support Fund, through which we motivate and support researchers in preparing applications for prestigious grants such as ERC, EXPRO, JUNIOR STAR, or MSCA. These are precisely the types of projects that push the boundaries of knowledge and strengthen the international standing of our university,” said Martin Weiter, Vice-Rector of BUT for Research and Knowledge Transfer.

Microscope of the Future: Combining Light and Electrons Wins Prestigious Grant

Our Library never stops expanding. What are the most recent contributions to LabRulezICPMS Library in the week of 30th March 2026? Check out new documents from the field of spectroscopy/spectrometry and related techniques!<blockquote>👉 <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/library">SEARCH THE LARGEST REPOSITORY OF DOCUMENTS ABOUT SPECTROSCOPY/SPECTROMETRY RELATED TECHNIQUES</a></blockquote><blockquote>👉 Need info about different analytical techniques? Peek into <a target="_blank" rel="noopener noreferrer" href="https://lcms.labrulez.com/library">LabRulezLCMS</a> or <a target="_blank" rel="noopener noreferrer" href="https://gcms.labrulez.com/library">LabRulezGCMS</a> libraries.</blockquote>This week we bring you application notes by Metrohm, Shimadzu, Thermo Fisher Scientific and Waters Corporation!<h3>1. Metrohm: Quantification of methanol in contaminated spirits</h3>Protecting consumers from contaminated beverages<ul><li>Application note</li><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/labrulez-bucket-strapi-h3hsga3/an_rs_056_download_3b37cb883a.pdf">Full PDF for download</a></li></ul>An alarming global trend highlights the serious harm that can result from ingesting illegal, improperly distilled alcohol. Home-distilled spirits prepared using industrial solvents (i.e., wood alcohol) and presented as legitimate alcoholic beverages often contain methanol. Methanol causes blindness and can lead to death when ingested. This has led to fatal consequences around the world [1–3].&nbsp;The breaking point for the Czech Republic came in September 2012. The sale of hard liquor was temporarily banned after 20 people died from the consumption of spirits with dangerous levels of methanol [2]. After an exhaustive study using various screening tools, the Czech Republic adopted Raman spectroscopy as the method of choice for identifying and quantifying methanol in contaminated spirits. This Application Note demonstrates how Raman spectroscopy can be employed as an efficient and rapid screening method for samples of rum contaminated with methanol.<h4>EXPERIMENT&nbsp;</h4>This example study measures commercially available coconut rum that is spiked with methanol in concentrations between 0.33% and 5.36%. The <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/library?mainauthorItems=220&amp;search=iRaman">iRaman NxG 785H</a> with a fiber-optic probe is used to collect Raman spectra of the mixtures (Figure 3). Table 1 lists the relevant equipment and instrument settings used for this application study. The peak at around 1000 cm-1 (highlighted by the inlay of Figure 3) visibly increases with increasing concentration of methanol, becoming significant at approximately 1%.<h4>CONCLUSION</h4>These results validate that Raman spectroscopy can be used for rapid, quantitative screening of dangerous adulterants in alcoholic beverages. This technique can be expanded to investigate adulteration in other media such as food, petroleum, and pharmaceutical drugs [4].<h3>2. Shimadzu: Evaluation of Organic Impurities in Lithium Carbonate by TOC Analysis</h3><ul><li>Application note</li><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/labrulez-bucket-strapi-h3hsga3/an_01_01098_en_ec9b3e73fc.pdf">Full PDF for download</a></li></ul><h4>User Benefits</h4><ul><li>TOC analysis enables effective control of organic impurities in lithium carbonate.</li><li>Using the combustion tube kit for high-salt samples can extend the lifespan of the combustion tube and catalyst, reducing maintenance frequency.</li><li>With the <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/library?mainauthorItems=1&amp;search=ASI-L+autosampler">ASI-L autosampler</a>, multiple samples can be measured automatically, improving throughput and efficiency</li></ul>Lithium carbonate (Li2CO3) is an important material used in a wide range of applications in the lithium-ion battery industry. For example, it is used as a lithium source for cathode active material synthesis and electrolyte salt production, as a raw material for oxide-based solid electrolytes, and as a form of lithium commonly recovered in recycling processes.&nbsp;Because impurities in lithium carbonate can affect downstream processes and final products, appropriate control is essential. In particular, organic impurities require especially careful attention because they may originate from so many sources, such as solvents and processing aids used during purification, residual organics from manufacturing steps, or contamination introduced during handling and storage.&nbsp;Total organic carbon (TOC) analysis offers an effective way to manage such organic impurities in raw materials. This article presents an example of using a <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/library?mainauthorItems=1&amp;search=TOC-L">Shimadzu TOC-L</a> total organic carbon analyzer (Fig. 1) to evaluate the TOC content of lithium carbonate.<h4>TOC Analysis&nbsp;</h4><h5>TOC Analysis Methods&nbsp;</h5>Two commonly used methods are available for TOC analysis:&nbsp;(1) TC - IC method: Total carbon (TC) and inorganic carbon (IC) are measured separately, and then TOC is calculated as the difference (TOC = TC – IC).(2) NPOC method: TOC is measured as non-purgeable organic carbon (NPOC). After acidifying the sample to pH &lt; 3, IC is subsequently removed by sparging and the remaining carbon is measured as TC, which is regarded as TOC. The acidification and sparging steps are performed automatically by the instrument.&nbsp;For lithium carbonate solutions, the amount of carbonatederived IC is typically very high. As a result, the TC–IC method tends to yield calculated TOC values with a larger relative error. Therefore, the NPOC method isrecommended.&nbsp;In lithium carbonate solutions prepared as described above, IC is expected to be present mainly as bicarbonate (HCO3 –) and carbonic acid (H2CO3). If IC is not fully removed during NPOC pretreatment, the TOC result may be overestimated. Therefore, thorough IC removal is critical for samples with high IC content. For actual samples, sparging parameters, such as sparge gas flow rate and sparge time settings, can be adjusted.&nbsp;<h5>Combustion Tube for High-Salt Samples&nbsp;</h5>The prepared lithium carbonate solution contains a large amount of salts. When a large number of salt-containing samples are analyzed, salts may accumulate inside the combustion tube, which can lead to catalyst clogging, reduced sensitivity, and poorer repeatability.For this analysis, the optional combustion tube for high-salt samples was used, shown in Fig. 2. The high-salt combustion tube has a larger diameter than the standard combustion tube and contains larger catalyst particles to help mitigate saltrelated clogging. Thus, the frequency of combustion tube replacement can be significantly reduced.<h4>Conclusion&nbsp;</h4>In this article, TOC analysis was performed for a 10 g/L lithium carbonate solution using a Shimadzu TOC-L total organic carbon analyzer. By measuring TOC in the prepared solution, the TOC content in the lithium carbonate solid was calculated. The results showed good recovery rates in the spike-recovery test and consistent performance was also confirmed during long-term continuous analysis. These findings demonstrate that the TOC-L is a reliable solution for measuring TOC in lithium carbonate and for effective management of organic impurities.&nbsp;When applying the NPOC method to lithium salt-containing solutions, careful selection of the acid is essential because salts formed during acidification can affect both data quality and instrument condition. For this example, sulfuric acid is recommended.In addition, using the optional combustion tube kit for high-salt samples can extend the lifespan of the combustion tube and catalyst, thereby reducing maintenance frequency. This option is especially helpful for samples with high salt concentrations.&nbsp;In addition to lithium carbonate, the TOC-L can also be applied to TOC analysis of lithium hydroxide solutions, determination of water-extractable TOC in recycled black mass, and analytical needs in lithium refining processes based on direct lithium extraction (DLE). With its broad applicability across various upstream materials, recycling streams, and refining processes, the TOC-L supports both quality control and process optimization operations throughout the lithium-ion battery value chain.<h3>3. Thermo Fisher Scientific: Evaluating Silicon using Raman Microscopy</h3><ul><li>Application note</li><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/labrulez-bucket-strapi-h3hsga3/vib_silicon_analysis_with_raman_microscope_app_note_mcs_an1232_en_11_2024_1887815_web_50639c9148.pdf">Full PDF for download</a></li></ul>Raman spectroscopy is a form of vibrational spectroscopy that probes chemical bonds and molecular structure and is sensitive to small changes in chemical and structural environments. The Raman spectrum of a material is a molecular “fingerprint” that can be used for identification of unknown materials and for characterizing and qualifying expected materials. Since intermolecular effects and lattice vibrations are also detected, it can be used to evaluate crystallinity. Mechanical phenomena such as strain can also be detected from peak shifts in Raman spectra. Raman imaging allows visualization of the distribution of components or changes in physical state across the sample.<h4>Silicon in aluminum&nbsp;</h4>Silicon is used in alloys with aluminum to increase the strength of lightweight aluminum-based parts. Addition of silicon to aluminum also alters the viscosity of melted aluminum, improving the castability. These alloys typically contain 3% to 25% silicon. While silicon and aluminum can form a eutectic mixture, it is common to have finely dispersed silicon particles throughout the material.¹ The size and distribution of silicon particles can affect the strength of the aluminum.&nbsp;One common example of an aluminum product, aluminum foil, is made up of almost pure aluminum (approximately 98.5%) but it does contain small amounts of silicon and iron.² Raman imaging of a piece of aluminum foil reveals small particles of silicon (Figure 1). A <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/products/2237">Thermo Scientific™ DXR3xi Raman Imaging Microscope </a>was used with a 532 nm laser and a 100X&nbsp;metallurgical objective to collect the Raman imaging data. An area of 408 μm x 208 μm was imaged using an image pixel size of 1 μm. The Raman image, based on the 520 cm-1 peak of silicon, shows the spatial distribution of the particles and image analysis provides size and shape information. In this case, 81&nbsp;silicon particles were identified with a size (area) range of 6-151 μm². This analytical approach may be extrapolated to other types of Si/Al alloy parts.<h4>Conclusion&nbsp;</h4>The importance of silicon as a technologically significant material cannot be overstated. It has properties that make it useful in numerous different types of products. Raman micro-spectroscopy has proven itself an important tool for the assessment of molecular structure and physical states of silicon. Raman images provide a way to observe the spatial distribution of silicon and silicon-containing components, structural variations such as crystallinity, and physical effects such as strain. This note showed a few representative examples to illustrate some of the advantages offered by Raman microscopic analysis of silicon. The coverage is not intended to be comprehensive as there are numerous other areas where the Raman analysis of silicon is currently employed and other opportunities where it could be used. The Thermo Scientific DXR3 Raman Microscope and the Thermo Scientific DXR3xi Raman Imaging Microscope have both been shown to be excellent choices for the Raman analysis of silicon samples.<h3>4. Waters Corporation: High-Throughput Detection of Degraded Polysorbate in Biological Formulations with FMM</h3><ul><li>Application note</li><li><a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/labrulez-bucket-strapi-h3hsga3/720009114_en_99c7483d1a.pdf">Full PDF for download</a></li></ul>The FDA requires that all biologic formulations be free of visible particles and has defined allowable levels of subvisible particles (SVPs) larger than 10 µm to ensure the potency, efficiency, and safety of these drug.1 While most protein drug particle analysis focuses on particles formed due to formulation instability, SVPs formed through the degradation of formulation excipients must also be considered.&nbsp;Polysorbates 20 (PS20) and 80 (PS80), best known as Tween-20 and -80, are excipients used in &gt;70% of marketed parenteral biological drugs to improve product stability and shelf life.2 However, when these formulations are stored for long periods of time (&gt;6 months) at low temperatures (4 °C), visible and subvisible particles are formed due to the enzymatic hydrolysis of the polysorbates by host cell proteins (HCPs) such as esterases and lipases.3,4 PS20 in particular has been found to be extremely prone to degrading into fatty acid particles.5 Lauric, myristic and palmitic acids are the most common fatty acid degradation products, and there is a direct correlation between low fatty acid solubility and particle formation in common formulation buffers.3–7 However, high-throughput, sensitive, and specific analysis of polysorbate particles has been difficult due to their complex chemistry and their low concentrations (&lt;&lt;0.5%) in high protein concentration (&gt;100–200 mg/mL) formulation environments, making it a perennial needle in a haystack problem.In this application note, we introduce the Aura™ polysorbate degradation assay, a specific and quantitative assay that detects free fatty acid particles (FFAs) formed during polysorbate degradation on Aura PTx System. The assay analyzes 96 samples using anywhere from 5 µL–10 mL of sample in a few hours. <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/products/2190">Aura™ Systems</a> use backgrounded membrane imaging (BMI) and fluorescence membrane microscopy (FMM) to count, size and ID particles from 1 µm to 5 mm. Fluorescent labels utilized by FMM are selected based on thier ability to interact with particles of a certain nature, allowing for the generation of key information related to identity of the particles.<h4>Results and Discussion&nbsp;</h4><h5>Morphological Appearance of Different Fatty Acid Particles&nbsp;</h5>Aura systems image every particle, enables subvisible particle size distributions analysis, and makes morphological differentiation possible using built-in image analysis filters. When we analyze different free fatty acid solutions with Aura PTx System, we find that each forms particles with different morphological characteristics. Lauric acid particles are large and irregular clusters, myristic acid particles are small and oval shaped, and palmitic acid particles form fibril-like particles and small circular clusters (Figure 2a-c). These unique morphological characteristics suggest the presence of free fatty acid particles that can then be confirmed with FMM using labeled fluorescence.<h4>Conclusion&nbsp;</h4>Aura PTx System and <a target="_blank" rel="noopener noreferrer" href="https://icpms.labrulez.com/products/2190">Aura+ System</a> can easily detect the major degradation components of PS20 in proteincontaining samples at any stage of the drug manufacturing process. The method only requires 5 µL of sample, is specific and sensitive, and can analyze 96 samples in just a few hours, far outperforming other techniques. Aura PTx System and Aura+ System can also identify and differentiate the key degraded particulates from polysorbate formulation by their distinguishable shape, appearance, and specific labeling with BODIPY FL C16. The Aura polysorbate assay can detect FFAs at concentrations relative to lauric acid above 9.38 µM (&gt;2183 counts/mL) and quantitate above 18.75 µM (&gt;2976 counts/mL).

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LECO LM Series Microindentation Hardness Testing Systems

The LECO LM Series offers flexible microindentation hardness testing from 1 gf to 2000 gf, with compact designs, multiple turret options, and analog or digital models for labs and production sites.

The LECO LM Series Microindentation Hardness Testing Systems are designed to meet the needs of both production environments and research laboratories. With a broad range of configurations—from economical analog models to advanced digital systems—the LM Series offers flexible solutions that can be tailored to your application requirements and budget.These systems support precise microindentation testing across a wide load range and are suitable for detailed hardness evaluation of thin layers, coatings, and small or delicate specimens. Their compact footprint, flexible turret configurations, and wide selection of objectives make the LM Series a versatile and reliable choice for modern hardness testing workflows.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/LECO_LM_Stanoveni_mikrotvrdosti_12e8c38050.jpg" alt="LECO: LM Series Microindentation Hardness Testing Systems" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_LECO_LM_Stanoveni_mikrotvrdosti_12e8c38050.jpg 235w," sizes="100vw" width="416" height="276"><h4>Key Features</h4><ul><li>Load range from 1 gf to 2000 gf for broad application coverage</li><li>Manual or automatic turret options</li><li>Wide selection of objectives from 2.5X to 100X</li><li>Turret configuration supporting up to four objectives and two indenters</li><li>Compact design to save valuable laboratory space</li></ul><h4>Applications</h4><ul><li>Coating and surface layer hardness testing (e.g., nitrided layers)</li><li>Hardness profiling across material layers</li><li>Thin specimen analysis</li><li>Weld and heat-affected zone evaluation</li></ul><h4>Available Models</h4><ul><li>LM110 Series – Economical solution for low-volume laboratories</li><li>LM310 Series – Digital measurement with automatic hardness calculations</li><li>LM810 Series – Digital measurement, hardness calculations, conversions, and statistical analysis</li><li>LM248AT Dual Indenter – Digital measurements with conversions and statistical hardness data using dual indenters</li></ul>

LECO LCB3100 Brinell Load Cell Hardness Tester

LCB3100 is a Brinell load cell hardness tester with touch-pad control, automatic load application, and selectable loads, delivering accurate, repeatable hardness testing without mechanical weights.

The LECO LCB3100 is a modern Brinell hardness tester that uses advanced load cell technology to deliver accurate, repeatable, and user-friendly hardness measurements. Designed to simplify operation and reduce the risk of operator error, the LCB3100 eliminates traditional mechanical weights and adjustment knobs in favor of an intuitive electronic control system.Hardness testing is performed through a simple touch-pad operation panel, where the user selects the desired test load and dwell time. The instrument then automatically applies, holds, and removes the load using direct load-cell feedback, ensuring precise force control and consistent results. Its rugged construction and enclosed load cell make the LCB3100 well suited for routine laboratory use as well as demanding industrial environments.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/LECO_LCB_3100_Tvrdomer_Brinell_se_snimacem_zatizeni_9cb81e86c5.jpg" alt="LECO: LCB3100 Brinell Load Cell Hardness Tester" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_LECO_LCB_3100_Tvrdomer_Brinell_se_snimacem_zatizeni_9cb81e86c5.jpg 196w," sizes="100vw" width="1723" height="1371"><h4>Key Features</h4><ul><li>Twelve selectable Brinell load options for flexible testing</li><li>Direct load method with real-time load-cell feedback</li><li>Automatic load application, holding, and removal</li><li>Selectable dwell times to meet different testing standards</li><li>Heavy-duty cast housing with enclosed load cell for long-term stability</li><li>User-friendly touch-pad operation panel that simplifies setup and minimizes errors</li></ul>

LECO AMH55 Software for Automated Hardness Testing

AMH55 software enables automated, semi-automated, and manual hardness testing with advanced image recognition, flexible reporting, and Cornerstone® control for accurate microindentation and Vickers analysis.

LECO’s AMH55 software is designed to maximize productivity and measurement confidence in microindentation and Macro/Vickers hardness testing. By introducing LECO’s Cornerstone® software platform to hardness testing systems, AMH55 delivers advanced automation, intuitive operation, and flexible reporting for a wide range of applications and surface conditions.AMH55 supports fully automatic, semi-automatic, and lite configurations, enabling laboratories to tailor their hardness testing workflow to specific needs while maintaining high accuracy and repeatability. Advanced image-recognition technology ensures reliable evaluation even on challenging sample surfaces, making AMH55 a powerful solution for modern hardness testing environments.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/LECO_AMH_55_Software_pro_automaticke_testovani_tvrdosti_2_9317816b67.jpg" alt="LECO: AMH55 Software for Automated Hardness Testing" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_LECO_AMH_55_Software_pro_automaticke_testovani_tvrdosti_2_9317816b67.jpg 172w," sizes="100vw" width="838" height="761"><h4>Key Features</h4><ul><li>Advanced image-recognition technology for analysis beyond simple threshold-based methods</li><li>Reliable measurement on scratched, etched, uneven, or variably illuminated surfaces</li><li>Cornerstone® software with optional touch-screen interface for full control of methods, calibrations, analysis parameters, and reporting</li><li>Flexible configurations to support automatic, semi-automatic, or manual workflows</li><li>Customizable data reporting to match laboratory and application requirements</li></ul><h4>Configuration Options</h4><h5>AMH55 Automatic</h5><ul><li>Fully automatic alignment and parfocal tools</li><li>Automatic pixel calibration and shading correction</li><li>Optional Advanced Analysis Module for color-contoured hardness mapping</li><li>Fully customizable reporting</li><li>Motorized X, Y, and Z axis movement</li></ul><h5>AMH55 Semi-Automatic</h5><ul><li>Automatic indent location and analysis</li><li>Automatic alignment and pixel calibration</li><li>Customizable reporting</li><li>Motorized X and Y axes</li><li>Manual focus</li></ul><h5>AMH55 Lite</h5><ul><li>Automatic indent detection and analysis within a single field of view</li><li>Automatic pixel calibration</li><li>Customizable reporting</li><li>Manual X, Y, and Z axes</li><li>Optional digital stage micrometers for position tracking</li><li>Upgradeable to AMH55 Semi-Automatic or Automatic</li></ul><h4>Compatible Models</h4><ul><li>AMH55 with LM110 Series microindentation systems</li><li>AMH55 with LM248 Series microindentation systems</li><li>AMH55 with LV110/LV810 Series Macro Vickers hardness testers</li></ul>

LECO LV Series Macro-Vickers Hardness Testing System

LECO LV Series Macro-Vickers hardness testers provide affordable, flexible hardness testing for large samples, offering wide load ranges, multiple objectives, and upgrade options for demanding applications.

The LECO LV Series Macro-Vickers hardness testing systems provide an affordable and versatile solution for hardness testing of larger and heavier samples commonly encountered in welding, metallurgical, and industrial applications. Designed for reliability and flexibility, the LV Series supports both routine and more demanding hardness measurements across a wide load range.Available in analog and digital configurations, the LV Series can be tailored to laboratory needs, with upgrade paths toward more automated operation. This modular approach allows laboratories to start with a basic configuration and expand capabilities as testing requirements evolve.<img src="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/LECO_LV_Stanoveni_makrotvrdosti_2_c6b6bb0ddb.jpg" alt="LECO: LV Series Macro-Vickers Hardness Testing System" srcset="https://storage.googleapis.com/labrulez-bucket-strapi-h3hsga3/thumbnail_LECO_LV_Stanoveni_makrotvrdosti_2_c6b6bb0ddb.jpg 220w," sizes="100vw" width="1795" height="1269"><h4>Key Features</h4><ul><li>Turret accommodating up to three objectives for flexible inspection and measurement</li><li>Improved, finer-pitched focusing mechanism compared to previous generations</li><li>Wide load range with eight load steps from 0.3 kgf up to 50 kgf</li><li>Broad selection of objectives ranging from 2.5× to 100×</li><li>Optional light-load Brinell testing on the LV810 (custom load set required)</li></ul><h4>Available Models</h4><h5>LV110 Series</h5><ul><li>Economical solution for low-volume laboratories</li><li>Supports a combination of micro and macro loads</li></ul><h5>LV810 Series</h5><ul><li>Supports a combination of micro and macro loads</li><li>Optional light-load Brinell testing capability</li></ul>

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