From Science Fiction to Reality: Laser Light Diffraction Unveiled
The Invention of Laser Light
Laser light, an acronym for “Light Amplification by Stimulated Emission of Radiation,” is a groundbreaking technology that has revolutionized various fields, from telecommunications to medicine. The invention of laser light has paved the way for numerous scientific and technological advancements. In this section, we will explore the introduction to laser technology and key innovations that led to its development.
Introduction to Laser Technology
The concept of laser technology originated from the theoretical work of Albert Einstein in the early 20th century. However, it wasn’t until the 1960s that practical demonstrations of laser light became a reality. The invention of the laser is credited to Theodore Maiman, who constructed the first operational laser using a ruby crystal as the gain medium in 1960.
Laser light is characterized by its unique properties, including high intensity, coherence, and monochromaticity. Unlike ordinary light sources, such as incandescent bulbs or fluorescent lamps, laser light consists of photons that are all in phase and traveling in the same direction. This coherence allows laser light to be focused into a narrow beam with minimal divergence. Additionally, laser light is monochromatic, meaning it consists of a single wavelength or color (laser light wavelength).
Key Innovations in Laser Development
The development of laser technology involved several key innovations that enabled the practical realization of laser light. One such innovation was the introduction of different types of lasers, each utilizing a specific gain medium and pumping mechanism. Examples of these types include gas lasers, solid-state lasers, and semiconductor lasers.
Another pivotal innovation was the achievement of population inversion, a condition in which the number of excited atoms or molecules exceeds the number of atoms or molecules in the ground state. This condition is crucial for the amplification of light through stimulated emission. Various techniques, such as optical pumping and electrical discharge, were employed to achieve population inversion and generate laser light (laser light amplification).
Over the years, advancements in laser technology have led to the development of lasers with different output powers, pulse durations, and wavelengths. These innovations have expanded the applications of lasers across a wide range of fields, including telecommunications, manufacturing, medicine, and scientific research. Laser technology continues to evolve, with ongoing research and development pushing the boundaries of what is possible with laser light.
Understanding the invention and development of laser light provides a foundation for comprehending the principles of laser diffraction. In the next section, we will delve into laser diffraction, a technique that utilizes laser light to measure the size of particles by analyzing the variation in the intensity of scattered light as a function of the scattering angle.
Understanding Laser Diffraction
Laser diffraction is a powerful technique used to determine particle size by analyzing the relationship between light scattering (angle and intensity) and particle size using the Mie scattering theory. The principle of laser diffraction is based on the phenomenon of diffraction at the edges of a light beam and the refraction of light as it travels through particles (AZoM). By studying these interactions, laser diffraction provides accurate data on particle size.
The Principle of Laser Diffraction
The principle of laser diffraction revolves around the diffraction of laser light as it encounters particles. As a laser beam passes through a particle, the light is scattered in different directions due to the interaction with the particle’s surface. This scattering pattern contains valuable information about the size of the particles present.
According to Fraunhofer diffraction theory, the intensity of light scattered by a particle is directly proportional to the particle size. The angle of the laser beam and particle size have an inversely proportional relationship. This relationship allows for the calculation of particle size based on the analysis of the scattered light patterns.
Mie Scattering Theory Explained
The Mie scattering theory is an alternative to Fraunhofer diffraction theory that is often used in laser diffraction analysis. Unlike Fraunhofer theory, which assumes particles are much larger than the wavelength of the incident light, Mie theory considers particles of various sizes and refractive indices. It requires precise knowledge of the complex refractive index of the particle’s material.
Mie theory allows for more accurate analysis of particles that are not significantly larger than the wavelength of the light source. It can provide valuable information about the size distribution and shape of particles, making it particularly useful for analyzing complex samples and particles with unique optical properties (Wikipedia).
Modern laser diffraction analyzers, such as the LA-960 from HORIBA, utilize the Mie scattering theory as the default method for accurate particle size determination. These analyzers also allow users to input the refractive index of particles, enabling precise measurements for a wide range of sample materials (AZoM).
In summary, laser diffraction operates on the principles of diffraction and light scattering. By utilizing the Mie scattering theory, laser diffraction analyzers can accurately determine particle size based on the scattering patterns of laser light. This technique provides valuable data for a wide range of applications in various industries.
Applications of Laser Diffraction
Laser diffraction, a widely used particle sizing technique, finds numerous applications in various industries. Its ability to analyze particle size distributions ranging from hundreds of nanometers up to several millimeters makes it invaluable in understanding and optimizing processes. Let’s explore the industrial applications of laser diffraction and the importance it holds in different sectors.
Industrial Applications of Laser Diffraction
Laser diffraction plays a crucial role in several industries, including:
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Pharmaceuticals: In the pharmaceutical industry, laser diffraction is used for quality control and formulation development. It aids in determining the particle size of active pharmaceutical ingredients (APIs), excipients, and drug delivery systems. This information is vital for ensuring consistent drug performance, optimizing dissolution rates, and formulating effective dosage forms.
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Chemicals: Laser diffraction is utilized in the chemical industry for analyzing powders, catalysts, pigments, and other chemical substances. It enables manufacturers to understand the particle size distribution and its impact on product performance, such as flowability, reactivity, and dispersibility. This knowledge assists in optimizing production processes and ensuring consistent product quality.
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Food: The food industry heavily relies on laser diffraction for quality control and process optimization. It helps in determining the particle size of ingredients, such as flours, spices, and additives. Understanding particle size distribution is crucial for achieving desired product characteristics, such as texture, mouthfeel, and stability. Laser diffraction aids in developing formulations, improving shelf life, and optimizing production efficiency.
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Mining: In the mining industry, laser diffraction is used for particle size analysis of minerals, ores, and raw materials. It assists in optimizing processes like grinding, milling, and beneficiation. By understanding the particle size distribution, mining companies can improve mineral recovery rates, optimize energy consumption, and enhance the efficiency of downstream processing.
Importance of Laser Diffraction in Various Industries
Laser diffraction offers several advantages that make it indispensable across industries:
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Wide Measuring Range: Laser diffraction has a wide range, from submicron to millimeter sizes, making it versatile for analyzing different types of materials. It can handle fine powders, suspensions, emulsions, pastes, and creams, accommodating various physical forms of materials.
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Quick Results: Laser diffraction provides fast results, with an average test taking under 60 seconds to complete. This rapid analysis allows for efficient process monitoring and enables timely decision-making.
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High Repeatability: Laser diffraction enables sampling a large number of particles in each measurement, ensuring high repeatability. This reliability is crucial for quality control and optimizing processes.
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Database and Optical Property Estimation: Many laser diffraction instruments come with built-in databases that include optical properties of common dispersants. In cases where optical properties are unknown, users can measure or estimate them using an iterative approach based on the fit between modeled and actual data. This flexibility enhances the accuracy and applicability of laser diffraction measurements.
By leveraging laser diffraction, industries gain valuable insights into particle size distributions, enabling them to improve product quality, optimize processes, and ensure consistent performance. The versatility, speed, and reliability of laser diffraction make it an essential tool in various sectors, aiding in advancements and innovations across industries.
Challenges and Pitfalls in Laser Diffraction
Laser diffraction is a powerful technique for particle size analysis, but it is not without its challenges and potential pitfalls. Understanding these common challenges and the factors that can affect accuracy is crucial for obtaining reliable results in particle size analysis.
Common Challenges in Laser Diffraction
Several common challenges can arise during laser diffraction experiments. These challenges include:
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Incorrect Sample Dispersion: Proper sample dispersion is essential for accurate particle size analysis. Inadequate dispersion can lead to particle agglomeration or poor representation of the sample’s true particle size distribution.
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Multiple Scattering Effects: Multiple scattering occurs when particles interact with each other, leading to deviations from the idealized scattering patterns. These effects can complicate data interpretation and require careful consideration when analyzing results.
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Inappropriate Optical Model Assumptions: Laser diffraction analysis relies on certain assumptions about the optical properties of particles, such as their shape and refractive index. Deviations from these assumptions can introduce errors in the results.
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Instrument Settings: Proper instrument settings are crucial for accurate laser diffraction measurements. Errors in settings such as laser intensity, aperture size, or detector angle can lead to inaccuracies in the analyzed particle size distribution.
Factors Affecting Laser Diffraction Accuracy
Several factors can affect the accuracy of laser diffraction measurements. These factors include:
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Sample Preparation: Proper sample preparation is critical for obtaining reliable results. Factors such as sample homogeneity, dispersion technique, and the concentration of particles in the sample can impact accuracy.
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Particle Shape and Refractive Index: Laser diffraction assumes that particles are spherical and have a known refractive index. Irregular particle shapes or variations in refractive index can introduce errors in the size distribution analysis.
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Measurement Range: Laser diffraction instruments have a measurement range within which accurate results can be obtained. If the particle size distribution falls outside this range, the accuracy of the analysis may be compromised.
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Calibration: Regular calibration of the laser diffraction instrument is essential for maintaining accuracy. Calibration ensures that the instrument provides consistent and reliable results over time.
It is important to note that laser diffraction instruments can measure particles in both liquid suspension and as dry powders. However, the analysis of sprays and aerosols may require specific setups to account for their unique characteristics (Wikipedia).
To overcome these challenges and ensure accurate results, it is crucial to have a thorough understanding of the principles of laser diffraction, proper sample preparation techniques, and the capabilities of the instrument being used. By addressing these challenges and considering the factors that can affect accuracy, researchers can obtain reliable and meaningful particle size analysis results using laser diffraction.
Choosing the Right Laser Diffraction Instrument
When selecting a laser diffraction instrument, there are several factors to consider to ensure accurate and reliable particle size analysis. Understanding these factors will help you choose the right laser diffraction analyzer for your specific needs.
Factors to Consider when Selecting a Laser Diffraction Analyzer
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Sample Properties: Consider the properties of the sample you will be analyzing. Is it a dry powder or a suspension? Are the particles uniform in shape and size, or is there a wide range of particle sizes? Understanding the sample properties will help determine the appropriate laser diffraction instrument.
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Particle Size Range: Determine the particle size range you need to measure. Some laser diffraction analyzers are optimized for a specific size range, while others can handle a broader range of particle sizes. Consider the minimum and maximum particle sizes you expect to encounter in your samples.
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Measurement Accuracy: Assess the required measurement accuracy for your application. Higher accuracy is often achieved with instruments that offer a wider range of detectors and multiple scattering angles. These features allow for more comprehensive data collection and analysis.
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Refractive Index: The refractive index of the sample material plays a crucial role in laser diffraction analysis. Some instruments allow users to input the desired refractive index, while others provide built-in databases of common dispersants’ optical properties. Ensure that the instrument you choose can handle the refractive index requirements of your samples.
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Analysis Method: Laser diffraction analyzers offer the option to use either the Fraunhofer theory or the Mie scattering theory for data analysis. The choice between these methods depends on the optical properties and size range of the particles being analyzed. The Fraunhofer theory is suitable for samples with unknown optical properties or mixtures, while the Mie theory is more appropriate for particles that are not significantly larger than the wavelength of the light source.
Analysis Method | Suitable for | Particle Size Range |
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Fraunhofer Theory | Unknown optical properties or mixtures | Large particles |
Mie Scattering Theory | Known optical properties, non-large particles | Small to medium-sized particles |
Table data sourced from Wikipedia
- Instrument Features: Consider additional features that may enhance your particle size analysis. Some instruments offer advanced technologies such as Polarisation Intensity Differential Scattering (PIDS) for enhanced sizing accuracy. Evaluate whether these features align with your specific requirements.
Comparison of Fraunhofer and Mie Theory in Laser Diffraction
The choice between Fraunhofer theory and Mie scattering theory depends on the optical properties and particle size range being analyzed. The Fraunhofer theory is a simplified approach that does not require knowledge of the sample’s optical properties. It is particularly effective for large particles (Malvern Panalytical). On the other hand, the Mie scattering theory provides a more comprehensive analysis by considering the complex refractive index of the particle’s material (Wikipedia).
Commercial laser diffraction analyzers often offer the flexibility to choose between Fraunhofer and Mie theory for data analysis. Fraunhofer theory is suitable for samples with unknown optical properties or mixtures, while Mie theory is more appropriate for particles that are not significantly larger than the wavelength of the light source (Wikipedia).
It is important to note that the Mie theory requires precise knowledge of the complex refractive index of the particle’s material. The lower detection limit of laser diffraction using Mie theory is generally believed to be around 10 nm (Wikipedia). Alternatively, the Fraunhofer approximation can be used as a simplified approach when the optical properties of the sample are not known. However, caution is advised when analyzing samples with particles below 50µm or where particles are relatively transparent (Malvern Panalytical).
By considering these factors and understanding the differences between Fraunhofer and Mie theory, you can make an informed decision when choosing a laser diffraction instrument for your particle size analysis needs.
Enhancing Laser Diffraction Analysis
To further enhance the capabilities of laser diffraction analysis, researchers and scientists have developed advanced techniques and methods. Two notable advancements in laser diffraction analysis are Polarisation Intensity Differential Scattering (PIDS) and other advancements in laser diffraction techniques.
Polarisation Intensity Differential Scattering (PIDS) for Enhanced Particle Sizing
Polarisation Intensity Differential Scattering (PIDS) is a technique that utilizes the property of sub-micron particles to scatter polarized light differentially based on polarization and wavelength. This method enables the measurement of particles as small as 10nm (0.01µm) by analyzing the intensity of polarized light at multiple wavelengths. PIDS provides quantifiable size distribution measurements, making it a valuable tool for particle size analysis in both powder and liquid samples (Meritics).
Compared to conventional laser diffraction techniques, PIDS offers superior resolution and a wider dynamic range, making it particularly suitable for quality control applications. By utilizing the differential scattering properties of particles, PIDS allows for rapid assessment of particle size distributions, providing valuable insights for various industries (Meritics).
Advancements in Laser Diffraction Techniques
In addition to PIDS, other advancements in laser diffraction techniques have been developed to overcome certain limitations and improve measurement accuracy. For example, some laser diffraction instruments now come with built-in databases that include the optical properties of common dispersants. This allows users to obtain more accurate and reliable particle size distribution measurements, even when the optical properties of the dispersants are unknown. In cases where the optical properties are unavailable, an iterative approach can be used to estimate them based on the fit between modeled and actual data (Malvern Panalytical).
It’s important to note that laser diffraction analysis has its limitations, particularly when measuring particles below 1µm. Distinguishing light from different particle sizes becomes challenging, and below 0.4µm, it becomes virtually impossible. To address this challenge, some instruments employ multiple wavelengths of light. However, the effectiveness of this approach is limited. Curve fitting routines are sometimes used to estimate data below the measuring limits.
Furthermore, when selecting a laser diffraction instrument, it is crucial to consider the measuring range, resolution, and the appropriate theory to use. Fraunhofer’s approximation of Mie theory is commonly employed for measuring particles up to 30µm. It relies on good resolution of the angular pattern of the diffracted light and a large number of detectors (>100) to provide reliable and accurate particle size distribution measurements (Meritics).
By leveraging advancements like PIDS and other techniques, researchers and scientists continue to push the boundaries of laser diffraction analysis, enabling more precise and detailed particle size measurements across a wide range of applications. However, it is essential to understand the limitations and select the appropriate techniques for specific particle size ranges and measurement requirements.
Limitations and Alternatives to Laser Diffraction
Despite its wide range of applications and advantages, laser diffraction does have some limitations. It is important to be aware of these limitations and consider alternative particle sizing techniques when necessary.
Limitations of Laser Diffraction
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Particle Shape: Laser diffraction measures the size of particles but cannot analyze the shape of the particle. The technique may struggle with sharp edges and non-spherical particles, leading to difficulties in accurately interpreting data. It is more suitable for spherical or near-spherical particles.
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Validation Challenges: Laser diffraction algorithms have faced validation challenges, particularly in cases where complex particle shapes are involved. Ensuring accurate and reliable results requires careful calibration and validation procedures.
Alternative Particle Sizing Techniques
While laser diffraction is a widely used particle sizing technique, there are alternative methods available that can be considered based on specific requirements:
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Dynamic Light Scattering: Dynamic Light Scattering (DLS) is an alternative method for particle sizing. It measures particles from 0.3 nm to 10 µm in diameter by utilizing the Brownian motion of particles suspended in a fluid. DLS provides valuable information about particle size distribution and is particularly useful for studying nanoparticles and macromolecules.
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Photo-Optical Particle Analyzers: Photo-Optical Particle Analyzers employ high-resolution cameras, such as Line Scan cameras, to determine the size and shape of particles. These analyzers offer benefits such as speed, accuracy, reproducibility, and the capability to integrate into existing processes. However, they have limitations such as measuring particles in the range of 10 microns to 4 millimeters and requiring dry, free-flowing material.
It is important to carefully evaluate the specific requirements of your particle sizing needs and consider the advantages and limitations of each technique before making a selection. Laser diffraction remains a powerful and widely used technique, particularly for larger particles and applications where speed and simplicity are essential. However, alternative techniques may provide better accuracy or suitability for specific particle shapes or size ranges.
For more information on laser diffraction and alternative particle sizing techniques, consult reputable sources like W. S. Tyler Blog and Malvern Panalytical.
Standards and Best Practices in Laser Diffraction
To ensure accurate and reliable laser diffraction measurements, various standards and guidelines have been established. These standards provide a framework for instrument calibration, sample preparation, and data analysis. Two prominent standards in the field of laser diffraction are the ISO 13320:2020 Standard for Laser Diffraction Measurements and the United States Pharmacopoeia (USP) Guidelines for Laser Diffraction.
ISO 13320:2020 Standard for Laser Diffraction Measurements
The ISO 13320:2020 standard, developed by the International Organization for Standardization (ISO), provides comprehensive guidelines for the measurement of particle size distribution using laser diffraction. This standard covers various aspects of laser diffraction analysis, including the measurement principle, instrument calibration, and data analysis. By following the guidelines outlined in ISO 13320:2020, researchers and manufacturers can ensure consistency and comparability in their laser diffraction measurements.
Key aspects covered in ISO 13320:2020 include:
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Instrument Calibration: The standard specifies procedures for instrument calibration to ensure accurate and reliable measurements. Calibration involves verifying the alignment, intensity calibration, and sizing calibration of the laser diffraction instrument.
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Sample Preparation: ISO 13320:2020 provides recommendations for sample dispersion techniques, such as wet or dry dispersion, depending on the nature of the sample. Proper sample preparation is crucial to obtain representative and meaningful results.
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Data Analysis: The standard outlines methods for data analysis, including the determination of particle size distribution using mathematical algorithms. It also addresses potential challenges and sources of error in the analysis process.
United States Pharmacopoeia (USP) Guidelines for Laser Diffraction
The United States Pharmacopoeia (USP) includes guidelines for laser diffraction analysis in chapter USP <429>. These guidelines are specifically tailored for pharmaceutical applications, focusing on the measurement of particle size distribution in drug substances and drug products. The USP <429> chapter provides recommendations for instrument qualification, sample preparation, and data interpretation.
Key aspects covered in the USP <429> chapter include:
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Instrument Qualification: The guidelines emphasize the importance of instrument qualification to ensure accurate and reliable laser diffraction measurements. This includes verifying the instrument’s performance, calibration, and compliance with specific requirements.
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Sample Preparation: USP <429> provides guidelines for sample preparation techniques, such as dispersion methods and suitable dispersants for pharmaceutical samples. Proper sample preparation is essential to obtain representative and meaningful results in the pharmaceutical industry.
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Data Interpretation: The USP <429> chapter addresses the interpretation of laser diffraction data for pharmaceutical applications. It provides guidance on assessing the quality of the measurement, identifying potential sources of error, and ensuring compliance with pharmaceutical regulations.
By adhering to the ISO 13320:2020 standard and the USP <429> guidelines, researchers and professionals can ensure the accuracy, precision, and reproducibility of their laser diffraction measurements. These standards serve as valuable references for instrument manufacturers, researchers, and industries that rely on laser diffraction analysis for particle size characterization.
Understanding Laser Diffraction
To comprehend the intricacies of laser diffraction, it is essential to grasp the underlying principles and theories that drive this technique. Laser diffraction measures particle size distributions by analyzing the angular variation in the intensity of light scattered as a laser beam passes through a dispersed particulate sample. This method provides valuable insights into the size distribution of particles present in a sample.
The Principle of Laser Diffraction
The principle of laser diffraction is based on the interaction of laser light with particles in a sample. As a laser beam passes through the sample, the particles scatter the light in different directions. Larger particles tend to scatter light at smaller angles, while smaller particles scatter light at larger angles. By measuring the intensity of light scattered at various angles, it is possible to determine the size distribution of particles in the sample.
The Mie scattering theory, developed by Gustav Mie, is commonly employed in laser diffraction analysis. This theory takes into account the optical properties of the particles and the dispersant to calculate the particle size distribution. The refractive index and imaginary component of the sample, along with the refractive index of the dispersant, are crucial parameters in this calculation. By utilizing the Mie theory, laser diffraction provides accurate particle size information.
Mie Scattering Theory Explained
The Mie scattering theory explains how light interacts with spherical particles of various sizes. It takes into account factors such as particle size, refractive index, and wavelength of light to determine the scattering pattern. This theory is particularly useful for analyzing particles with sizes comparable to the wavelength of light.
However, in cases where the optical properties of the sample are not known or difficult to measure, the Fraunhofer approximation can be employed. The Fraunhofer approximation simplifies the analysis by assuming that the particles are much larger than the wavelength of light, thus eliminating the need for precise knowledge of optical properties. This approximation is effective for larger particles but may not be suitable for smaller or more transparent particles.
Modern laser diffraction instruments often come equipped with databases that contain the optical properties of common dispersants. In cases where the optical properties of a specific sample are unknown, an iterative approach can be used to estimate or measure the necessary parameters based on the fit between the modeled and actual data.
Understanding the principles and theories behind laser diffraction is crucial for accurate and insightful particle size analysis. By leveraging the Mie scattering theory and the Fraunhofer approximation, laser diffraction provides valuable information about particle size distributions in a wide range of applications across various industries.