Q1 Research Application · Frontier Focus

Porous SnO2 microsphere and its carbon nanotube hybrids: Controllable preparation, structures and electrochemical performances as anode materials

This Electrochimica Acta paper (2021) is indexed as a Xianghu equipment application case for XH-MC-1; key results include Capacity 860.59 mAh g-1.

Paper ID 432
Application Focus lithium-ion battery, Microwave material synthesis, SnO2
Key Result Capacity 860.59 mAh g-1
Core Condition See experimental conditions below
Paper ID
432
Journal
Electrochimica Acta
Impact Factor
6.901
CAS Zone
Zone 1
Year
2021
Equipment Model
XH-MC-1
Affiliations
Jiangxi University of Science and Technology; Jiangxi Key laboratory of Power Battery and Material, Faculty of Materials Metallurgy and Chemistry, Jiangxi University of Science and Technology, Ganzhou 341000, China; School of Chemistry and Chemical Engineering, Qufu Normal University, Qufu 273165, China; State Key Laboratory of Advanced Special Steel & School of Materials Science and Engineering, Shanghai University, Shanghai 200444, China
Research Directions
lithium-ion battery Microwave material synthesis SnO2

Fact Snapshot

  • Paper: Porous SnO2 microsphere and its carbon nanotube hybrids: Controllable preparation, structures and electrochemical performances as anode materials
  • Equipment: XH-MC-1
  • Source: Electrochimica Acta, 2021
  • Research direction: lithium-ion battery, microwave material synthesis, and SnO2
  • Key results: Capacity 860.59 mAh g-1

Research Abstract

Porous SnO2 microsphere and its carbon nanotube hybrids: Controllable preparation, structures and electrochemical performances as anode materials was published in Electrochimica Acta (2021) and is indexed as a Xianghu Q1 application case for XH-MC-1. The source record connects it with lithium-ion battery, microwave material synthesis, and SnO2. Key reported results include Capacity 860.59 mAh g-1.

Research Background and Problem

The paper is positioned around lithium-ion battery, microwave material synthesis, and SnO2. The equipment record identifies XH-MC-1 as the Xianghu instrument context for this application case. The source affiliation record includes Jiangxi University of Science and Technology and Jiangxi Key laboratory of Power Battery and Material, Faculty of Materials Metallurgy and Chemistry, Jiangxi University of Science and Technology, Ganzhou 341000, China.

Key Result

Capacity 860.59 mAh g-1
MetricResult
Capacity860.59 mAh g-1

Evidence Details

Equipment-detail evidence

Equipment-detail evidence: source values include 1:20.

Process evidence

0.8 mL n-butanol was quickly added into and kept at 60 °C for 3.5 min

Microwave-method evidence

Microwave-method evidence: source mentions XH-MC-1.

Mechanism / Method Highlights

  • Equipment-detail evidence: source values include 1:20
  • Process evidence: 0.8 mL n-butanol was quickly added into and kept at 60 °C for 3.5 min
  • Microwave-method evidence: source mentions XH-MC-1
  • Reported outcome: Capacity 860.59 mAh g-1.

Application Value

  • Provides a peer-reviewed SoarNova / Xianghu Q1 application case for XH-MC-1.
  • Supports English discovery around lithium-ion battery, Microwave material synthesis, and SnO2.
  • Preserves quantitative result evidence: Capacity 860.59 mAh g-1.
  • Maintains source-level evidence details: Equipment-detail evidence: source values include 1:20, Process evidence: 0.8 mL n-butanol was quickly added into and kept at 60 °C for 3.5 min, and Microwave-method evidence: source mentions XH-MC-1.

Related Equipment

FAQ

Which Xianghu instrument is covered by this page?
The structured source records XH-MC-1 for this paper.
What is the main application direction?
The source tags this paper under lithium-ion battery, microwave material synthesis, and SnO2.
Which publication does this case come from?
It comes from Electrochimica Acta (2021), DOI 10.1016/j.electacta.2021.138582.
Citation
Porous SnO2 microsphere and its carbon nanotube hybrids: Controllable preparation, structures and electrochemical performances as anode materials
Electrochimica Acta, 2021
DOI: 10.1016/j.electacta.2021.138582