Q1 Research Application · Frontier Focus

Electronic Structure Regulation of Layered Vanadium Oxide via Interlayer Doping Strategy toward Superior High-Rate and Low-Temperature Zinc-Ion Batteries

This Advanced Functional Material paper (2019) is indexed as a Xianghu equipment application case for XH-800S; key results include Capacity 367 mAh g-1.

Paper ID 259
Application Focus Rapid microwave synthesis
Key Result Capacity 367 mAh g-1
Core Condition Temperature 200 °C / 20 °C
Paper ID
259
Journal
Advanced Functional Material
Impact Factor
18.808
CAS Zone
Zone 1
Year
2019
Equipment Model
XH-800S
Affiliations
Guangdong University of Technology
Research Directions
Rapid microwave synthesis

Fact Snapshot

  • Paper: Electronic Structure Regulation of Layered Vanadium Oxide via Interlayer Doping Strategy toward Superior High-Rate and Low-Temperature Zinc-Ion Batteries
  • Equipment: XH-800S
  • Source: Advanced Functional Material, 2019
  • Research direction: rapid microwave synthesis
  • Core conditions: Temperature 200 °C / 20 °C and Time 3 h
  • Key results: Capacity 367 mAh g-1

Research Abstract

Electronic Structure Regulation of Layered Vanadium Oxide via Interlayer Doping Strategy toward Superior High-Rate and Low-Temperature Zinc-Ion Batteries was published in Advanced Functional Material (2019) and is indexed as a Xianghu Q1 application case for XH-800S. The source record connects it with rapid microwave synthesis. Core operating conditions include Temperature 200 °C / 20 °C and Time 3 h. Key reported results include Capacity 367 mAh g-1.

Research Background and Problem

The paper is positioned around rapid microwave synthesis. The equipment record identifies XH-800S as the Xianghu instrument context for this application case. The source affiliation record includes Guangdong University of Technology.

Equipment Use and Experimental Conditions

ItemParameter
Temperature200 °C / 20 °C
Time3 h

Key Result

Capacity 367 mAh g-1
MetricResult
Capacity367 mAh g-1

Evidence Details

Equipment evidence

the mixed solution were transferred into a 100 mL autoclave and placed in a microwave instrument (XH-800G), and maintained at 200 °C for 3 h.

Abstract evidence

the Mn0.15V2O5·nH2O electrode shows a high specific capacity of 367 mAh g−1 ... Even at a low temperature of −20 °C, a reversible specific capacity of 100 mAh g−1 can be achieved

Mechanism / Method Highlights

  • Method context: Temperature 200 °C / 20 °C and Time 3 h.
  • Equipment evidence: the mixed solution were transferred into a 100 mL autoclave and placed in a microwave instrument (XH-800G), and maintained at 200 °C for 3 h
  • Abstract evidence: the Mn0.15V2O5·nH2O electrode shows a high specific capacity of 367 mAh g−1 ... Even at a low temperature of −20 °C, a reversible specific capacity of 100 mAh g−1 can be achieved
  • Reported outcome: Capacity 367 mAh g-1.

Application Value

  • Provides a peer-reviewed SoarNova / Xianghu Q1 application case for XH-800S.
  • Supports English discovery around Rapid microwave synthesis.
  • Preserves quantitative result evidence: Capacity 367 mAh g-1.
  • Maintains source-level evidence details: Equipment evidence: the mixed solution were transferred into a 100 mL autoclave and placed in a microwave instrument (XH-800G), and maintained at 200 °C for 3 h and Abstract evidence: the Mn0.15V2O5·nH2O electrode shows a high specific capacity of 367 mAh g−1 ... Even at a low temperature of −20 °C, a reversible specific capacity of 100 mAh g−1 can be achieved.

Related Equipment

FAQ

Which Xianghu instrument is covered by this page?
The structured source records XH-800S for this paper.
What is the main application direction?
The source tags this paper under rapid microwave synthesis.
Which publication does this case come from?
It comes from Advanced Functional Material (2019), DOI 10.1002/adfm.201907684.
Citation
Electronic Structure Regulation of Layered Vanadium Oxide via Interlayer Doping Strategy toward Superior High-Rate and Low-Temperature Zinc-Ion Batteries
Advanced Functional Material, 2019
DOI: 10.1002/adfm.201907684