Equipment Leasing Solutions
Raman Spectrometers

How Raman Spectrometers Work & How We Save You Time & Money

Excedr’s leasing program is designed for labs. Request a lease estimate today and see how leasing can save you time and money.

All equipment brands and models are available.
Raman spectroscopy diagram

Raman spectrometers employ Raman spectroscopy, a nondestructive chemical analysis technique that provides detailed information about a sample’s chemical composition, molecular interactions, crystallinity, and phase and polymorphy.

Spectroscopy diagram

Specifically, the Raman effect is a light scattering technique based on the principle that molecules scatter incident light from a highly intense light source, typically a laser source. The scattered, incidental light is usually the same wavelength as the laser light and does not provide essential data about the sample. That’s because when light hits something, most of the photons that are scattered are the same energy as the light it was hit with. This scattered light is also referred to as Rayleigh Scatter.

However, a minimal amount of light is scattered at a different wavelength than the Rayleigh Scatter and is indicative of an analyte’s chemical structure. This shorter wavelength scattered light is called Raman Scatter, or Raman effect. It is named after Sir C.V. Raman.

In other words, Raman spectroscopy is a type of molecular spectroscopy that relies on inelastic scattering (Raman Scatter) of light to detect vibrational, rotational, and other low-frequency modes in a sample.

It is used in chemistry to identify molecules by providing a structural fingerprint, represented by a Raman spectrum. This spectrum is characterized by several peaks that describe the intensity and wavelength position of the scattered light from a sample and are unique to specific molecules and materials. Each peak relates to a particular molecular bond vibration, including both individual bonds and groups of bonds.

Raman spectral libraries are often used to identify a sample based on its Raman spectrum. The libraries contain thousands of samples’ Raman spectra, collected from various positions of each sample.

Because Raman looks at the scattering of light rather than its absorption, the sample preparation is much less complex, and there are no aqueous absorption bands to throw off the data. When a monochromatic laser interacts with a sample, the light will scatter. Furthermore, these devices offer both low/medium resolution and high-resolution capabilities.

Raman Spectrometer Techniques, Methods, & Costs

A hand creating a star-shaped symbol using all of its fingers

These devices’ instrumentation varies depending on the experimental capabilities you wish to have. We’ll review the basics. Furthermore, Raman spectrometers rely on different techniques to observe change, which will also be explained in further detail below. We’ll cover some of the most common ones, as several different types of Raman spectroscopy are being used today.

Spectrometer Instrumentation

Raman spectrometers are made of three main components:

  • Laser
  • Sampling interface
  • Spectrometer

The laser’s excitation wavelength can vary depending on the sample being analyzed using Raman spectroscopy. The various wavelengths include some typical examples: ultraviolet, visible, and near-infrared (NIR). The one you choose will depend on your goals and the experimental capabilities you wish to have.

In many spectrometers today, the sampling interface is a type of fiber-optic probe. It can be augmented to fit a range of optical microscopes, liquid flow cells, gas flow cells, and various sampling chambers.

The spectrometer provides high resolution and low power consumption without much noise and includes the detector. The detector type depends on the laser source being used. When visible light is used, a standard charge-coupled device (CCD) detector is utilized; however, various CCDs exist that are optimized for specific wavelengths. In the case of UV excitation, a particular CCD detector is used, along with objective lenses and diffraction gratings.

Surface-Enhanced Raman Spectroscopy (SERS)

A highly accurate and powerful technique, surface-enhanced Raman spectroscopy (SERS) improves normal Raman scattering by huge orders of magnitude and can be used to detect single molecules.

This technique applies Raman intensity and improves Raman scattering through an electromagnetic amplification mechanism. The enhancement occurs on the surface of a rough metal substance or via nanostructures consisting of magnetic-plasmonic silica nanotubes.

Due to its ability to identify chemical species and analyze the makeup of a mixture on the nanoscale, this technique is used extensively in chemistry, pharmaceuticals, and materials science.

Coherent Anti-Stokes Raman

Coherent anti-Stokes Raman Spectroscopy (CARS), also known as coherent anti-stokes Raman scattering, is similar to conventional Raman spectroscopy. It is also used to measure the vibrational signatures of molecules.

However, it differs from the other technique because it employs multiple photons to address the vibrations. Doing so produces a coherent signal or identical wave sources. This makes CARS much stronger than processes like spontaneous Raman emission.

Fourier Transform (FT) Raman

Fourier Transform (FT) Raman spectroscopy relies on a specific type of configuration, which is designed to collect wavelength-stable and fluorescence-free measurements. A conventional FT Raman spectrometer comprises an excitation laser source, a sampling interface, and an interferometer.

The use of an interferometer makes FT Raman distinct from dispersive techniques, such as Dispersive Raman, which uses a diffraction grating spectrometer to disperse the light scattered from a sample. While the diffraction grating will detect the scatter via a CCD detector, producing a Raman spectrum directly, the FT Raman spectrometer’s interferometer will introduce a path between the light source and the signal beams, creating an interference pattern. This pattern is used to reconstruct the Raman spectrum.

Resonance Raman

By using a specific wavelength to cause scattering, resonance Raman spectroscopy can increase the intensity of Raman scattering. This is done by choosing a wavelength that either overlaps or is extremely close to the electronic transition of the sample that is being observed.

Due to resonance Raman spectroscopy’s increased intensity, it can detect samples with extremely low concentrations in a substance. One major disadvantage of this technique is that the fluorescence of an object may throw off the data collected and should be accounted for. This makes it an instrumental technique in analyzing environmental pollutants that have concentrations in the parts per billion range.

Transmission Raman

By shining light through a sample in the direction of the excitation laser, transmission Raman spectroscopy allows for bulk analysis of powders, tablets, and opaque substances.

By shooting the light through the object and analyzing the light that comes out the other side, it allows for analysis of the entire volume of the material.

Their ability to perform fast, quantitative analysis of substances makes them useful in pharmaceutical and medical analysis, as well as material sciences.

Raman Optical Activity

Also known as spontaneous vibrational Raman optical activity scattering, this vibrational spectroscopy technique looks at the difference in intensity of Raman scattered from the right and left circularly polarized light.

Similar to vibrational circular dichroism, Raman optical activity directly looks at chirality, or molecular vibrations. Due to its ability to observe chirality, this spectroscopic technique is very useful in chemistry and biology.

High-Throughput Screening Raman Spectrometer Leases to Fit Every Need

An animation of lines spreading out from the center to form a sunset-like shape

Founder-Friendly Leases

Our lease agreements are founder-friendly and flexible, helping you preserve working capital, strengthen the cash flow of your business, and keep business credit lines open for expansions, staffing, and other crucial operational expenses and business development opportunities.

2-5 Year Lease Lengths

Leases range from 2 to 5 years. Length will depend on several factors, including how long you want to use the equipment, equipment type, and your company’s financial position. These are standard factors leasing companies consider and help us tailor a lease agreement to fit your needs.

Your Choice of Manufacturer

We don’t carry an inventory. This means you’re not limited to a specific set of manufacturers. Instead, you can pick the equipment that aligns with your business goals and preferences. We’ll work with the manufacturer of your choice to get the equipment in your facility as quickly as possible.

Maintenance & Repair Coverage

Bundle preventive maintenance and repair coverage with your lease agreement. You can spread those payments over time. Easily maintain your equipment, minimize the chances something will break down, repair instrumentation quickly, and simplify your payment processes.

End-of-Lease Options

At the end of your lease, you have multiple options. You can either renew the lease at a significantly lower price, purchase the machine outright based on the fair market value of the original pricing, or call it a day and we’ll come the pick up the equipment for you free of charge.

No Loan-Like Terms

Our leases do not include loan-like terms, which can be restrictive or harmful in certain situations. We do not require debt covenants, IP pledges, collateral,  or equity participation. Our goal is to maximize your flexibility. When you lease with us, you’re collaborating with a true business partner.

In-House Underwriting Process

Our underwriting is done in-house. You can expect quicker turnaround, allowing you respond to your equipment needs as they arise. We require less documentation than traditional lenders and financiers and can get the equipment you need in operation more quickly.