Q1 Research Application · Frontier Focus

Leaching variability of calcium-bearing phases in steel slag treated with ammonium acetate and ultrasonic enhancement mechanism

This Separation and Purification Technology paper (2026) is indexed as a Xianghu equipment application case for XH-300PE; key results include Leaching efficiency 10%.

Paper ID 654
Application Focus Steel-slag valorization, ultrasound-enhanced
Key Result Leaching efficiency 10%
Core Condition Temperature 60 °C
Paper ID
654
Journal
Separation and Purification Technology
Impact Factor
8.6
CAS Zone
Zone 1
Year
2026
Equipment Model
XH-300PE
Affiliations
Central South University
Research Directions
Steel-slag valorization ultrasound-enhanced

Fact Snapshot

  • Paper: Leaching variability of calcium-bearing phases in steel slag treated with ammonium acetate and ultrasonic enhancement mechanism
  • Equipment: XH-300PE
  • Source: Separation and Purification Technology, 2026
  • Research direction: steel-slag valorization and ultrasound-enhanced
  • Core conditions: Temperature 60 °C, Ultrasonic power 400 W, and Time 30 min
  • Key results: Leaching efficiency 10%

Research Abstract

Leaching variability of calcium-bearing phases in steel slag treated with ammonium acetate and ultrasonic enhancement mechanism was published in Separation and Purification Technology (2026) and is indexed as a Xianghu Q1 application case for XH-300PE. The source record connects it with steel-slag valorization and ultrasound-enhanced. Core operating conditions include Temperature 60 °C, Ultrasonic power 400 W, and Time 30 min. Key reported results include Leaching efficiency 10%.

Research Background and Problem

The paper is positioned around steel-slag valorization and ultrasound-enhanced. The equipment record identifies XH-300PE as the Xianghu instrument context for this application case. The source affiliation record includes Central South University.

Equipment Use and Experimental Conditions

ItemParameter
Temperature60 °C
Ultrasonic power400 W
Time30 min

Key Result

Leaching efficiency 10%
MetricResult
Leaching efficiency10%

Evidence Details

Equipment-detail evidence

Equipment-detail evidence: source values include 25 kHz, 400 W, 60 °C, 30 min, 10%. Entities: XH-300PE.

Equipment-detail evidence

Equipment-detail evidence: source values include 25 kHz, 10%.

Equipment-detail evidence

Equipment-detail evidence: source values include 25 kHz. Entities: XH-300PE.

Ultrasonic-method evidence

Ultrasonic-method evidence: source values include 3.5 mol/L, 60 °C, 30 min, 10%.

Mechanism / Method Highlights

  • Method context: Temperature 60 °C, Ultrasonic power 400 W, and Time 30 min.
  • Equipment-detail evidence: source values include 25 kHz, 400 W, 60 °C, 30 min, 10%. Entities: XH-300PE
  • Equipment-detail evidence: source values include 25 kHz, 10%
  • Equipment-detail evidence: source values include 25 kHz. Entities: XH-300PE
  • Reported outcome: Leaching efficiency 10%.

Application Value

  • Provides a peer-reviewed SoarNova / Xianghu Q1 application case for XH-300PE.
  • Supports English discovery around Steel-slag valorization and ultrasound-enhanced.
  • Preserves quantitative result evidence: Leaching efficiency 10%.
  • Maintains source-level evidence details: Equipment-detail evidence: source values include 25 kHz, 400 W, 60 °C, 30 min, 10%. Entities: XH-300PE, Equipment-detail evidence: source values include 25 kHz, 10%, Equipment-detail evidence: source values include 25 kHz. Entities: XH-300PE, and Ultrasonic-method evidence: source values include 3.5 mol/L, 60 °C, 30 min, 10%.

Related Equipment

FAQ

Which Xianghu instrument is covered by this page?
The structured source records XH-300PE for this paper.
What is the main application direction?
The source tags this paper under steel-slag valorization and ultrasound-enhanced.
Which publication does this case come from?
It comes from Separation and Purification Technology (2026), DOI 10.1016/j.seppur.2025.135503.
Citation
Leaching variability of calcium-bearing phases in steel slag treated with ammonium acetate and ultrasonic enhancement mechanism
Separation and Purification Technology, 2026
DOI: 10.1016/j.seppur.2025.135503