Gas Adsorption Measurement Analysis of Surface Area and Porosity

Microtrac je přední společnost, která vyvíjí, vyrábí a prodává různé analyzátory pro stanovení množství adsorpce plynů a par, jakož i BET povrchové plochy a distribuce velikosti pórů. Měřicí přístroje používají technologii adsorpce plynu k analýze porézních i neporézních práškových materiálů. Výrobky Microtrac se používají po celém světě ve výzkumu a vývoji (R&D), kontrole kvality (QC) a zajišťování kvality (QA).

Analyzátor plochy povrchu a velikosti pórů

Adsorpce plynů a par

Vyhodnocování katalyzátorů

Měření hustoty

Měření průlomové křivky

Vysokotlaká adsorpce plynu

Rtuťová porozimetrie

Jednotlivé aplikace a měřící zařízení

Co je to adsorpce?

Studie adsorpce má poměrně dlouhou historii. Za první dokument o adsorpci se považuje studie o adsorpčním chování dřevěného uhlí od Fontany publikovaná v roce 1777. V roce 1814, N.T. Saussure provedl spoustu adsorpčních experimentů na dřevěném uhlí. Nyní je jeho adsorpční aparát vystaven v Národním historickém muzeu v Anglii. Dnešní adsorpční technologie je široce používána v průmyslovém procesu (např. Separace plynů a par) a pro charakterizaci jemných materiálů

Příklad adsorpce je znázorněn na obrázku níže. Obrázek neukazuje rozdíl mezi chemisorpcí a fyzisorpcí. Obecně, pokud interakce mezi adsorbátem a adsorbentem je silná (např. Vodíková vazba nebo adsorpce na bázi kyseliny), brání desorpci adsorbátu vakuem při dané adsorpční teplotě nebo teplotě místnosti, nazývá se chemisorpce. Na druhé straně je Physisorption slabá interakce hlavně kvůli van der Waalsovým silám. Adsorbát lze snadno desorbovat vakuováním. V poslední době se místo používání termínů „fyzisorpce“ a „chemisorpce“ začaly používat „reverzibilní“ a „nevratná“ adsorpce.

^{Adsorpční stav}

Gas adsorption is a fundamental analytical technique for evaluating the surface characteristics and internal structure of solid materials. Used across industries such as catalysis, pharmaceuticals, energy storage, and environmental engineering, gas adsorption reveals critical data on surface area, pore size distribution and porosity - key factors in performance and functionality.

Microtrac offers advanced gas adsorption analyzers and adsorption equipment designed to deliver precise, reproducible measurements that comply with international standards such as ISO 9277 and ISO 15901-2. Our instruments serve both R&D and quality control applications, enabling users to better understand and optimize materials.

Learn more about our full range of gas adsorption measurement solutions.

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Why Gas Adsorption?

Gas adsorption involves the adherence of gas molecules onto the surface of a solid. This physical interaction, known as physisorption, forms the basis for characterizing materials with porous or high surface-area structures. By studying how much gas is adsorbed at different pressures, engineers and researchers can derive:

Specific surface area (via BET method and more)
Pore size distribution (via classical methods like BJH, or novel methods like GCMC or DFT models)
Total pore volume

These metrics are vital across multiple applications:

In adsorbents like activated carbon, surface area correlates with adsorption capacity
In catalysis, higher surface area typically means more active sites for chemical reactions
In batteries and fuel cells, pore volume and structure influence energy density and ion transport
In pharmaceuticals, particle surface area affects dissolution rate and bioavailability

Industries in Gas Adsorption Analysis

Catalysis & Petrochemical Engineering

Catalyst efficiency depends heavily on surface area and accessible porosity. Gas adsorption analyzers help quantify the effectiveness of catalyst supports such as alumina, zeolites, and activated carbons. Accurate BET surface area measurements allows quality control, optimization of chemical reactors and extend catalyst life.

Pharmaceuticals

Regulated by compendia such as USP <846>, surface area analysis in drug substances is essential for controlling product behavior. Gas adsorption provides the data needed for consistent release profiles, bioavailability, and tablet performance.

Energy Storage & Conversion

Battery electrodes, supercapacitors, and hydrogen storage materials require a balance between surface area and pore accessibility. Gas adsorption is key to evaluating materials like porous carbons and metal-organic frameworks (MOFs) for optimal charge/discharge efficiency.

Environmental Technologies

Gas adsorption measurements are used to develop materials that capture or separate gases—such as CO₂ or VOCs. From indoor air purifiers to industrial scrubbers, adsorbent performance is driven by total gas uptake, surface area and pore structure analysis.

Construction and Advanced Materials

In construction, ceramics, and filtration media, porosity affects strength, durability, and fluid permeability. Gas adsorption techniques are used to characterize materials such as aerogels, mortars, and porous ceramics, which are applied in both structural and thermal contexts.

Methods and Standardization of Gas Adsorption Measurement

Core Technique: Volumetric Gas Adsorption

The most usual form of gas adsorption measurement is volumetric (manometric) physisorption. This method involves dosing a known volume of adsorptive gas (typically nitrogen or argon) into an evacuated sample cell and monitoring pressure changes as the gas adsorbs onto the sample's surface. The resulting adsorption isotherm—gas volume adsorbed vs. relative pressure (P/P₀)—forms the basis for analytical models.

Key steps:

Degassing (Outgassing): Prior to analysis, samples are heated under vacuum to remove moisture and contaminants.
Cryogenic cooling: Most measurements use liquid nitrogen (77 K) or liquid argon (87 K) to maintain stable, low temperatures ideal for physisorption.
Equilibrium dosing: Gas is introduced incrementally until equilibrium is reached at each pressure step.

Microtrac's instruments support full automation of these steps with integrated degassing stations and precision dosing systems.

Standard Models for Data Analysis

BET Theory (ISO 9277)

The Brunauer–Emmett–Teller (BET) method is the gold standard for calculating specific surface area. It assumes multilayer adsorption and is applied to the linear region of the isotherm (typically P/P₀ = 0.05–0.30; except type I isotherm). BET surface area is calculated from the monolayer capacity using:

Molecular cross-sectional area of the adsorbate (e.g. 0.162 nm² for N₂)
Avogadro’s number
Ideal gas law constants (such us molar volume of gas at STP)

Microtrac systems support both single-point and multi-point BET analysis as per ISO 9277 and ASTM D6556.

BJH Method (ISO 15901-2)

The Barrett–Joyner–Halenda (BJH) method is used to determine mesopore size distribution by analyzing the desorption branch of the isotherm. BJH applies the Kelvin equation to correlate pressure changes with pore diameters, assuming cylindrical pore geometry.

Ideal for:

Silica gels
Porous glass
Mesoporous oxides

DFT, NLDFT & QSDFT

Density Functional Theory (DFT), non-local DFT (NLDFT), and quenched solid DFT (QSDFT) are advanced methods that model gas adsorption in porous materials based on statistical mechanics. Unlike BJH, which relies on certain assumptions about pore geometry and is limited in analyzing micropores, DFT-based methods can accurately account for a range of pore shapes and sizes, making them ideal for characterizing microporous materials such as activated carbon and metal-organic frameworks (MOFs).

Provides high-resolution pore size distributions
Applicable to a range of adsorbates and pore geometries
Built-in libraries in Microtrac software enhance accuracy

Choice of Adsorbate Gases

The selection of gas affects sensitivity and pore accessibility:

Nitrogen (N₂, 77 K): Standard for BET and mesopore analysis. Well-characterized and widely accepted.
Argon (Ar, 87 K): Preferred for micropore analysis due to its non-polar nature and smoother adsorption behavior.
Krypton (Kr, 77 K): Used for low surface area materials (<1 m²/g). Its low saturation pressure increases sensitivity for small sample surfaces.
Carbon Dioxide (CO₂, 273 K or 298 K): Ideal for probing ultra-micropores (<0.7 nm), which are often inaccessible to nitrogen at 77 K due to kinetic restrictions and slower diffusion rates.

Microtrac’s BELSORP series supports all of these gases, enabling flexible, accurate analysis across materials.

Microtrac Gas Adsorption Analyzers: Engineered for Precision

Microtrac’s portfolio of gas adsorption analyzers is designed to deliver maximum reliability, compliance, and ease of use. Key features include:

Multi-Sample Capability

Instruments like the BELSORP MAX X enable simultaneous measurement of multiple samples, reducing analysis time without sacrificing accuracy.

Integrated Software Tools

The BELMaster software provides:

Automated BET, BJH, t-plot, and Langmuir analyses
Comparison tools for overlaying isotherms
Customizable report generation
Most advanced pore size distribution analysis based on Grand Canonical Monte Carlo (GCMC), NLDFT and QSDFT methods

High Vacuum and Pressure Control

Our analyzers operate over a wide pressure range—from high vacuum (10^-6 torr) up to ambient or even elevated pressures—ensuring accurate measurements across micro-, meso-, and macropores.

Compliance and Validation

Microtrac instruments support validation protocols (IQ/OQ), calibration standards, and data traceability required in regulated environments like pharmaceuticals and environmental labs. The wide range of Microtrac products can be used in compliance with FDA 21 CFR Part 11.

Innovation for Advanced Research

Microtrac’s continuous R&D focus ensures that our adsorption equipment meets evolving needs:

Helium-free void volume correction: Reduces errors in microporous sample analysis
High-pressure adsorption models: For hydrogen storage and methane capture studies
Vapor adsorption modes: For assessing hydrophobicity/hydrophilicity, useful in surface energy studies

Additionally, our global support team and technical experts are available to assist with method development, standard implementation, and complex data interpretation.

Conclusion: Precise Gas Adsorption Measurement for Confident Material Design

Gas adsorption is not just a laboratory technique - it is a gateway to understanding how materials behave in real-world applications. Accurate surface area and porosity data can inform:

Material selection
Product formulation
Regulatory approval
Performance optimization

Microtrac’s gas adsorption analyzers empower users to obtain this information quickly, reliably, and in full compliance with international standards. Whether you're testing catalysts, refining pharmaceutical powders, or exploring next-generation adsorbents, we have the adsorption equipment to support your goals.

Learn more about our Gas Adsorption Measurement instruments and how we can help you bring material innovation to life.

Frequently Asked Questions (FAQ)

What is gas adsorption used for?

Gas adsorption is used to determine surface area, pore size distribution, and gas-solid interactions. It is essential for industries like catalysis, energy, and pharmaceuticals.

What is the difference between physisorption and chemisorption?

Physisorption involves weak van der Waals forces and is reversible, while chemisorption involves stronger chemical bonds and is often irreversible. Both are studied using gas adsorption methods.

How do gas adsorption analyzers work?

Gas adsorption analyzers measure the quantity of gas adsorbed on a solid material at varying pressures. This data is used to calculate surface area and porosity using models such as BET or BJH.

What gases are commonly used in gas adsorption?

Nitrogen is the most common gas due to its inertness and consistency. Other gases like argon, CO₂, or krypton may be used for specific materials and applications.