Chemical removal of barium sulfate scale

20 October 2023| By Abdullah Hussein

Barium sulfate (BaSO₄, barite) is one of the most challenging types of scale commonly encountered in oilfields. Due to its properties and severe impact on production, barite can become a nightmare for operators if it builds up in the production system.   Generally speaking, barite is known for:  

• • Extremely low solubility (2.3 mg/L),
  • High mechanical strength,
  • Rapid formation and accumulation rates (e.g., a North Sea well dropped from 30,000 BPD to zero in 24 hours due to barite scaling),
  • Tendency to accumulate radioactive materials, forming NORM scale.

Fig.1: Scale sample comprises mainly BaSO4, SrSO4 , the sample also was radioactive. 

​In many cases, chemical removal methods fail to dissolve barite, necessitating mechanical alternatives. Sometimes, neither approach is successful, forcing operators to cut out or replace the scaled sections of the system.

​ Commercial BaSO₄ dissolvers exist but face barriers like high cost (especially in large volumes), slow kinetics, and stringent conditions (e.g., high temperature).
​ A cost-effective alternative is polyaminocarboxylate (PAC) chelating agents (e.g., EDTA, DTPA, CDTA, NTA; see Fig. 2), which have successfully dissolved barite in oil/gas fields. PACs offer advantages:  

Fig. 2: Examples of polyaminocarboxylate 

​These chemicals have been used for different applications in oil and gas fields, but as scale dissolvers, they are considered :

• Low cost,
• Non-corrosive,
• Broad applicability (effective on BaSO₄, CaCO₃, CaSO₄, and some sulfide scales),
• Ease of handling with minimal safety/environmental risks,
• Flexible formulation, and tunable efficiency via catalysts.

​ While PAC efficiency varies in literature, their efficiency largely depends on their optimal application. 

 Here are some helpful tips to effectively remove barite scale using PAC at a cheap price: 

1. Lab Analysis:
2. • Determine scale composition (including polymorphs) and layer-wise distribution.
   • Measure physical properties (thickness, hardness) to design cleaning.
3. Dissolver Selection:
4. • DTPA is most effective but costly; test alternatives (e.g., EDTA may suffice at lower cost).
5. Conduct lab dissolution studies (Fig. 3) to determine:
6. • Optimal concentration
   • Catalyst use
   • Temperature and soaking time
   • Any side effects or risks

Fig. 3: Dissolution of barite scale sample using PACs

​4. Enhance PAC performance with catalysts, such as:

1. • Oxalate
   • Thiosulfate
   • Glycolate
   • Maleate
   • Succinate
   • Phosphonates

​ 5. Maintain pH

1. • Adjust the dissolver pH > 10 (ideally 10–11.5) for best chelation performance. Note: pH above 11.5 can lead to unwanted precipitation when in contact with produced water.

    6. Maintain temperature

1. • Adjust the temperature (> 60°C) to speed up dissolution. Downhole heat can be utilized, or external heaters/heat exchangers used for surface facilities.

    7. Maintain soaking time

1. • from several hours to a few days depending on scale thickness. Amorphous scale generally dissolves faster.

    8. Pre-Treatment:

1. • Flush with organic solvent to remove oil films covering barite.
   • For acid-soluble components, use inhibited acid flushing to weaken scale (follow with water flush to avoid PAC-acid interference).

    9. Execution:

1. • Soak dissolver for predetermined time (hours to days; repeat for thick/aged scale).
   • Agitate/circulate if possible.
   • Combine with mechanical aids (wireline tools, pigging, coiled tubing) to enhance dissolution.

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 Further reading

• Mineral scales management (chapter 15), Essentials of flow assurance solids in oil and gas operations