Fact Snapshot
- Paper: Enhanced visible-light-driven photocatalytic activity for antibiotic degradation using magnetic NiFe2O4/Bi2O3 heterostructures
- Equipment: XH-300 series
- Source: Chemical Engineering Journal, 2014
- Research direction: Microwave heterostructure construction and Magnetic photocatalysis
- Core conditions: Temperature 220 °C / 100 °C, Microwave power 800 W, and Time 24 h / 15 min
- Key results: Highest visible-light activity 50% and Loading 50%
Research Abstract
Enhanced visible-light-driven photocatalytic activity for antibiotic degradation using magnetic NiFe2O4/Bi2O3 heterostructures was published in Chemical Engineering Journal (2014) and is indexed as a Xianghu Q1 application case for XH-300 series. The source record connects it with Microwave heterostructure construction and Magnetic photocatalysis. Core operating conditions include Temperature 220 °C / 100 °C, Microwave power 800 W, and Time 24 h / 15 min. Key reported results include Highest visible-light activity 50% and Loading 50%.
Research Background and Problem
Equipment Use and Experimental Conditions
| Item | Parameter |
|---|---|
| Temperature | 220 °C / 100 °C |
| Microwave power | 800 W |
| Time | 24 h / 15 min |
Key Result
| Metric | Result |
|---|---|
| Activity | 50% |
Evidence Details
... heated in the microwave reactor (XH-300UL ...) with an operating power of 800 W and working temperature of 100 °C for 15 min.
The TC removal rate over NiFe2O4/Bi2O3 (50%) (k = 0.045 min−1) was about 7.50 and 2.64 times as much as that of pure NiFe2O4 (k = 0.006 min−1) and Bi2O3 (k = 0.017 min−1), respectively.
Additional source evidence: source values include 10%, 30%, 50%, 70%, 100%.
The degradation rates are 90.78%, 88.69%, 85.56%, respectively.
Additional source evidence: source values include 7.50 fold, 2.64 fold.
Additional source evidence: source values include 220 °C, 24 h.
Additional source evidence: source values include 90 min, 90%.
Mechanism / Method Highlights
- Method context: Temperature 220 °C / 100 °C, Microwave power 800 W, and Time 24 h / 15 min.
- Equipment evidence: heated in the microwave reactor (XH-300UL ...) with an operating power of 800 W and working temperature of 100 °C for 15 min
- Source evidence: The TC removal rate over NiFe2O4/Bi2O3 (50%) (k = 0.045 min−1) was about 7.50 and 2.64 times as much as that of pure NiFe2O4 (k = 0.006 min−1) and Bi2O3 (k = 0.017 min−1), respectively
- Additional source evidence: source values include 10%, 30%, 50%, 70%, 100%
- Reported outcome: Highest visible-light activity 50% and Loading 50%.
Application Value
- Provides a peer-reviewed SoarNova / Xianghu Q1 application case for XH-300 series.
- Supports English discovery around Microwave heterostructure construction and Magnetic photocatalysis.
- Preserves quantitative result evidence: Highest visible-light activity 50% and Loading 50%.
- Maintains source-level evidence details: Equipment evidence: heated in the microwave reactor (XH-300UL ...) with an operating power of 800 W and working temperature of 100 °C for 15 min, Source evidence: The TC removal rate over NiFe2O4/Bi2O3 (50%) (k = 0.045 min−1) was about 7.50 and 2.64 times as much as that of pure NiFe2O4 (k = 0.006 min−1) and Bi2O3 (k = 0.017 min−1), respectively, Additional source evidence: source values include 10%, 30%, 50%, 70%, 100%, and Source evidence: The degradation rates are 90.78%, 88.69%, 85.56%, respectively.
Related Equipment
FAQ
Which Xianghu instrument is covered by this page?
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Which publication does this case come from?
Enhanced visible-light-driven photocatalytic activity for antibiotic degradation using magnetic NiFe2O4/Bi2O3 heterostructures
Chemical Engineering Journal, 2014
DOI: 10.1016/j.cej.2014.07.071
