Author: Arella Sun Publish Time: 2026-04-30 Origin: Unionchem
Cellulose derivatives show up in more industrial processes than most people realize. Paper making, textile sizing, mining flotation, oilfield drilling, food thickeners, pharmaceutical binders—the list goes on. Two of the most widely used in this family are CMC (carboxymethyl cellulose) and PAC (polyanionic cellulose).
If you're trying to decide between them for your application, you've probably noticed that the spec sheets look similar, the chemical names sound almost the same, and manufacturers sometimes treat them as interchangeable. They're not. There are real differences in performance, and picking the wrong one costs you money and headaches.
This guide cuts through the confusion and gives you a practical basis for making the right choice.
CMC is derived from cellulose (typically from wood pulp or cotton linters) through a reaction with sodium monochloroacetate in an alkaline environment. The result is an anionic water-soluble polymer with carboxymethyl groups (-CH₂COONa) substituted onto the cellulose backbone.
The degree of substitution (DS)—how many hydroxyl groups on each glucose unit are replaced—determines its solubility and performance characteristics.
Common grades:
Technical grade: Industrial applications with moderate purity requirements
Food grade: Meets FCC specifications for food use
Pharmaceutical grade: Highest purity for drug and tablet formulations
PAC is a modified form of CMC with a higher degree of substitution and, critically, a higher proportion of carboxymethyl groups relative to the cellulose backbone. The "polyanionic" designation refers to its higher charge density.
Technically, all PAC is a type of CMC, but PAC specifically refers to grades with DS values typically above 0.9 and enhanced performance in high-salt environments.
PAC is most commonly used in oilfield applications and high-performance industrial formulations where its superior salt tolerance and viscosity stability provide a meaningful advantage.
CMC produces viscosity at lower concentrations than many other thickeners, but its viscosity profile is more sensitive to salt concentration and temperature.
PAC generally provides higher viscosity stability across a wider range of conditions. Its viscosity retention in high-salt environments is notably better than standard CMC.
In practical terms:
For standard industrial applications where salt levels are low, CMC often provides adequate performance at a lower cost
For applications involving brines, seawater, or high-mineral-content fluids, PAC maintains viscosity more effectively
This is where PAC has a clear advantage.
Environment | CMC Performance | PAC Performance |
Fresh water | Excellent | Excellent |
Low salt (<5%) | Good | Excellent |
Moderate salt (5-15%) | Moderate | Excellent |
High salt (>15%) | Degraded | Good retention |
Saturated brine | Limited functionality | Functional |
If your process involves seawater, produced water, or any high-TDS environment, PAC is the more reliable choice. CMC at high salt concentrations can experience significant viscosity loss due to charge screening effects—the sodium ions from the salt reduce the electrostatic repulsion between CMC chains, causing them to coil and reduce viscosity.
PAC's higher charge density gives it more resistance to this effect.
Both CMC and PAC maintain reasonable functionality across typical temperature ranges, but:
Standard CMC: Some viscosity reduction at elevated temperatures (above 60°C), recovers upon cooling
PAC: Better viscosity retention at higher temperatures, though performance does vary by grade
For oilfield applications involving elevated temperatures (above 100°C), PAC grades specifically formulated for thermal stability are available.
CMC typically hydrates faster than PAC at equivalent concentrations. This matters in some production processes where rapid viscosity development is needed.
PAC's higher degree of substitution actually makes it more water-soluble in ionic environments, but the hydration rate in pure water can be slightly slower due to the higher charge density causing initial repulsion between chains.
In high-salt environments, PAC often hydrates more rapidly than CMC because the salt helps screen the charges and allows faster chain relaxation.
Food and pharmaceutical grade CMC is highly refined, with strict controls on heavy metals and purity. Industrial and technical grades have higher acceptable impurity levels.
PAC grades used in oilfield applications are typically technical grade with specifications tailored for drilling fluid performance rather than human consumption.
If you're using these materials in food, pharmaceutical, or personal care applications, ensure you're sourcing the appropriate grade with the relevant certifications (FDA, FCC, EU standards, Halal/Kosher as applicable).
For drilling fluids, PAC is the standard choice in most markets. Its superior salt tolerance and viscosity stability in challenging downhole conditions make it worth the premium over standard CMC.
Specific use cases for PAC in oilfield:
Drilling fluid viscosifier: Provides cuttings suspension and hole cleaning
Fluid loss control: Reduces filtrate loss to formations
Workover fluids: Maintains viscosity in high-salt completion brines
Fracturing fluids: Thickening agent for proppant suspension
We supply both CMC and PAC for oilfield applications, with specifications matched to regional drilling requirements.
In paper and paperboard manufacturing, CMC is widely used as:
Surface sizing agent: Improves surface strength and printability
Dry strength additive: Increases dry tensile and burst strength
Coating binder: Acts as a binder in coating formulations
PAC is used less commonly in paper applications, though specialty grades exist for specific performance requirements.
Both CMC and PAC function as sizing agents in textile processing, providing viscosity and film formation on yarn to improve weaving efficiency.
Standard CMC grades are typically sufficient for textile sizing where salt tolerance is not a major concern. PAC may be preferred for sizing formulations that involve seawater or mineral-loaded process water.
In mining flotation and mineral processing, PAC is preferred for:
Flotation rheology control: Maintaining appropriate viscosity in flotation pulps
Dust suppression: Binding fine particles
Tailings management: Water retention and rheology control
The high-mineral content of typical mining process water makes PAC's salt tolerance a significant advantage.
For food grade applications, CMC is more commonly used than PAC. CMC serves as:
Ice cream stabilizer: Controls ice crystal growth and texture
Beverage stabilizer: Prevents sediment and haze formation
Sausage casings: Provides water-binding and texture
Baked goods: Controls moisture and improves shelf life
When sourcing food grade CMC, ensure Halal/Kosher certifications are current and batch-specific COA data is available.
In pharmaceutical formulations, high-purity CMC (also called cellulose gum) is used as:
Tablet binder: Provides cohesion in solid dosage forms
Suspending agent: Keeps active ingredients in suspension
Viscosity modifier: Controls flow properties in liquid formulations
Film former: In topical and oral mucosal formulations
Pharmaceutical grade specifications (USP/NF standards) are required for these applications, with tight controls on viscosity, degree of substitution, and purity.
Here's how we typically work through this with our customers:
Salt levels are low or moderate: If your process water is freshwater or low in minerals, CMC performs well and costs less.
Temperature requirements are moderate: Standard CMC handles most room-temperature and moderately elevated-temperature applications.
Rapid hydration is important: If your process requires fast viscosity development, CMC's hydration rate is an advantage.
Cost sensitivity is primary: For applications where performance requirements are modest, CMC is the economical choice.
Food or pharmaceutical use: Food/pharmaceutical grade CMC has established regulatory acceptance and is the appropriate choice.
High salt or brine is involved: Seawater, produced water, saturated brines—PAC holds up.
High-temperature stability is required: Elevated downhole temperatures or process temperatures above 80°C.
Consistent viscosity across variable conditions is critical: PAC provides more stable rheological performance.
Oilfield or mining applications: Where challenging conditions are the norm.
Seawater is your base fluid: Offshore operations, coastal facilities, or any application where seawater is the process medium.
When evaluating CMC or PAC for your application, ask suppliers for:
Degree of substitution (DS): Indicates charge density and solubility profile
Viscosity specifications: Both single-point and across shear rates if available
Salt tolerance data: Viscosity retention in your specific salt system
Temperature stability data: If operating above 60°C
Purity/impurity profile: Especially for food, pharma, or personal care applications
Halal/Kosher documentation: For relevant markets
Sample quantities: To test in your actual formulation
CMC and PAC are both valuable tools in the cellulose derivatives toolkit. The choice between them comes down to understanding your specific operating conditions—particularly salt concentration, temperature, and performance consistency requirements.
In many cases, CMC is the right choice for cost-effective performance in standard conditions. When conditions get challenging—high salt, elevated temperature, variable process water—PAC earns its premium through reliable viscosity control.
If you're working through a sourcing decision and want application-specific guidance, our team at Unionchem can help you match the right product to your requirements. We supply both CMC and PAC across industrial grades and can provide technical documentation for your evaluation process.
Unionchem supplies CMC, PAC, and a complete range of cellulose derivatives to industrial manufacturers in oilfield services, mining, paper, textiles, food processing, and pharmaceutical industries worldwide.
