Application Notes

This application note details the RA802’s ability to deformulate the make-up of a transdermal nicotine patch.

This note highlights the robust and consistent data acquisition of the Thermo Scientific™ iCAP™ RQ ICP-MS for the unattended analysis of drinking water samples.

In this technical note, the concept of dead time in TCSPC fluorescence lifetime measurements is introduced, and how it can be avoided using Reverse Mode is explained.

Using Analytik Jena’s patented iCRC technology for interference removal, we measured 82 drinking water samples per h with 21 elements (+4 internal standards).

Raman spectroscopy as a technique used for mineral and soil analysis for the mining and petroleum industries or for gemstones and the jewelry industry.

This note highlights the benefits of triple quadrupole ICP-MS for increasing sample turnover and boosting data confidence.

This application note describes using complementary s-SNOM and AFM-IR techniques to characterize 2D materials, such as graphene, nanoantennae, and semiconductor materials.

This application note describes a fast and simple means of obtaining elemental composition of unknown sample materials using the Rigaku NEX DE VS elemental spectrometer.

Standardized methods exist for stable isotope analysis of food and beverage samples and are aimed at protecting product origin, authenticity, and label claims.

Inprentus offers custom-designed blazed diffraction grating masters with rights for replication. A variety of substrate materials and thin film overcoatings are available.

For analysis of non-particulate solids, the diffuse reflection sampling technique may offer an easy, non-destructive method for mid-infrared measurements. Spectral results of a polypropylene face mask collected via diffuse reflection and attenuated total reflection (ATR) were compared.

Tri-Range Applications of the Spectrum 3 Infrared Spectrometer

In this application note, we investigate the phase transitions occurring in polyethylene and nylon-6 using the Edinburgh Instruments RMS1000 Raman Microscope and a temperature stage.

Confocal Raman microscopy is a powerful tool for analyzing the chemical composition of samples on the submicrometer scale. In the food industry, various ingredients, additives, and bio-polymers (such as emulsifiers, stabilizers, carbohydrates, or thickeners) are commonly used to optimize the texture or the flavor of food. The distribution and microstructure of the ingredients strongly influence the properties of the final product. Therefore, research and development, as well as quality control, require powerful analytical tools for studying the distribution of compounds in food. Raman imaging has proven to be an effective and versatile technique for food analysis (1,2).

The TacticID-1064 ST has dedicated software and hardware designed to measure materials through both transparent and opaque containers. These through-barrier measurements remove the need for active sampling of potentially dangerous compounds such as fentanyl, leading to safer operations and reduced wait time for clear results. The 1064 nm laser is also an advantage for analyzing fluorescent or impure material. A Raman system with a 785 or 830 nm laser may generate fluorescence from these samples, which can overwhelm the Raman signal and make identification impossible. In this application note, we explore some of the capabilities of the TacticID-1064 ST.

Supported by the PSI method, Raman spectroscopy has the capability to analyze the surface structure of nanomaterials, such as graphene, transition metal dichalcogenides (TMD), semiconductors, nanomaterials, and so on.

Key Issues: Sampling flexibility of Raman enables in-process analysis of solids, turbid media, liquids, and gases Large volumetric Raman provide representative sampling of heterogenous solids

FT-NIR spectroscopy is a useful tool to identify textile samples, with distinct spectral features observed at wavelengths >1350 nm. This approach can be applied to authentication of natural and synthetic consumer textile products.

The analysis of gemstones is demonstrated, using low-power 50W EDXRF with indirect excitation.

Diamond ATR has become one of the most commonly used FT-IR spectroscopy methods. However, the strong diamond lattice bands in the 2300–1900 cm-1 region make it difficult to measure the functional groups from nitriles, isocyanates, isothiocyanates, diimides, azides, and ketenes that would normally appear in that region. This applications note compares the sensitivity of a single-reflection ATR to multiple-reflection ATR for the nitrile functional group infrared transition.

In 1970, marijuana was designated a Schedule I drug under the Controlled Substances Act, making it nearly impossible for laboratories to perform cannabis research. However, medicinal use of cannabis is now legal in Canada and 36 U.S. states, with more joining every year. With the passage of the Farm Bill in 2018, it is now federally legal to grow and process hemp in all 50 states. All of this interest in medical cannabis and CBD has highlighted the need for good analysis methodology in this relatively young market. Cannabis analysis is still developing standardized protocols, requirements, and acceptable testing practices. Typical testing requirements for cannabis and its products include heavy metal analysis, pesticide residue, and the potency of active ingredients such as tetrahydrocannabinol (THC). The terpene content of cannabis is also important. Terpenes have been shown to have beneficial uses for treatment of conditions ranging from cancer and inflammation to anxiety and sleeplessness. It is believed that the combination of terpenes and cannabinoids in cannabis produce a synergistic effect with regard to medical benefits, further elevating its popularity worldwide.

Demand for hand sanitizer products has skyrocketed. We describe a fast and easy analysis method for on-site quality control in the production of hand sanitizers.

We tackle one of the most common questions to arise when picking a Raman spectroscopy laser, “Should I choose a single, or multi-spatial mode laser for my application?”

Learn why the spectral properties, pulse width, and simpler design of picosecond lasers provide many advantages over femtosecond lasers for Raman spectroscopy.

Explore the uses of LIBS in the medical/biomedical application space by taking a look at some of the common applications as well as both laser and system requirements.