Volume 7

Innovative Energy & Research

ISSN: 2576-1463

Advanced Energy Materials 2018

August 13-14, 2018

Page 40

conference

series

.com

August 13-14, 2018 | Dublin, Ireland

20

th

International Conference on

Advanced Energy Materials and Research

Xiaodong Li, Innov Ener Res 2018, Volume 7

DOI: 10.4172/2576-1463-C1-001

Biomass-derived activated carbon scaffolds for electrochemical energy storage

W

ith increasing energy and environment concerns, how to efficiently convert and store energy has become a critical topic.

Electrochemical energy storage devices, such as supercapacitors and batteries, have been proven to be the most effective energy

conversion and storage technologies for practical application. Supercapacitors and lithium-based batteries are particularly promising

because of their excellent power density and energy density. However, further development of these energy storage devices is hindered

by their poor electrode performance. The carbon materials in supercapacitors and batteries, such as graphite, activated carbons and

various nanostructured carbonmaterials (ordered porous carbon, CNT, graphene etc.), are often derived fromnonrenewable resources

under relatively harsh environments. Naturally abundant biomass with hierarchically porous architecture is a green, alternative

carbon source with many desired properties for supercapacitors and lithium-based batteries. Recently, we converted cotton, banana

peel, and recycled paper into highly porous, conductive activated carbon scaffolds for advanced energy storage applications via

a low-cost and high throughput manufacturing process. The activated carbon scaffolds were further coated with active materials

such as NiCo

2

O

4

, NiO, Co-Al layered double hydroxides (Co-Al LDHs), Ni

2

S, sulfur nanoparticles, and graphene to enhance their

electrochemical properties. The biomass-derived activated carbon materials are effective in improving supercapacitor’s energy density

and in blocking the dissolution of reaction intermediates in lithium sulfur batteries. Especially, the biomass-derived carbons provide

scaffolds for hosting sulfur in lithium sulfur batteries to manipulate the “shuttle effects” of polysulfides and improve the utilization

of sulfur. In particular, the activated carbon textiles (derived from cotton textiles) are flexible and conductive, and an ideal substrate

for constructing flexible supercapacitors, batteries, and self-powered flexible solar cell/supercapacitor (or battery) systems. Using

biomasses is definitely the right track towards making renewable carbon materials for future energy storage devices.

Recent Publications

1. Gao Z, Bumgardner C, Song N, Zhang Y, Li J, Li X (2016) Cotton-textile-enabled flexible self-sustaining power packs via

roll-to-roll fabrication. Nature communications 7: 11586.

2. Gao Z, Song N, Zhang Y, Li X (2015) Cotton Textile enabled, flexible lithium-ion batteries with enhanced capacity and

extended Lifespan. Nano letters 15: 8194–8203.

3. Bao L, Li X (2012) Towards textile energy-storage from cotton T-shirts. Advanced materials 24: 3246-3252.

4. Zhang Y. Gao Z, Li X (2017) Capillarity composited recycled paper/graphene scaffold for lithium-sulfur batteries with

enhanced capacity and extended lifespan. Small 13: 1701927.

5. Zhang Y, Gao Z, Song N, Li X (2016) High-performance supercapacitors and batteries derived from activated banana-peel

with porous structures. Electrochimica acta 222: 1257–1266.

Biography

Xiaodong Li is a Rolls-Royce Commonwealth Professor at the University of Virginia with expertise and interests including nanomaterial-enabled energy systems, biological and bio-inspired materials

and devices, additive manufacturing, smart manufacturing, biomechanics, micro/nanomechanics, surface engineering, and tribology. His stature in the field of his expertise includes over 230 peer-

reviewed journal articles in prestigious journals such as

Science, Nature Communications, Advanced Materials,

and

Advanced Energy Materials;

over 12,000 citations with H-index of 54; TMS

MPMD Distinguished Scientist/Engineer Award (2015), Professional Engineering Publisher's PE Prize (2008); over 80 invited plenary lectures/keynotes/talks at international conferences/workshops;

Fellow of theAmerican Society of Mechanical Engineers (ASME); and Fellow of the Society of Experimental Mechanics (SEM). His breakthrough work has been featured by over 1,000 media outlets

worldwide including BBC, Discovery News, Science Daily, and MSNBC. His innovation on cotton textile based composites was recently selected by New York Times – Year in Ideas for Year 2010.

xl3p@virginia.edu

Xiaodong Li

University of Virginia, USA