advanced-materials-2018-keynote

Volume 6

Research & Reviews: Journal of Material Sciences

ISSN: 2321-6212

Advanced Materials 2018

September 04-06, 2018

Page 40

conference

series

.com

September 04-06, 2018 | Zürich, Switzerland

International Conference on

Advanced Materials & Nanotechnology

Dieter M Gruen, Res. Rev. J Mat. Sci. 2018, Volume 6

DOI: 10.4172/2321-6212-C3-019

Hybrid conversion solar system (HYCSOS)

ith increasing energy and environment concerns, how to efficiently convert and store energyhas 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 carbon materials

(ordered porous carbon, CNT, graphene etc.), are often derived from nonrenewable 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

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

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. Mareš J J, Hubík P, Krištofik J, Kindl D, Fanta M, Nesládek M, Williams O and Gruen D M (2006) Weak localization in

ultra-nano crystalline diamond. Applied Physics Letters. 88: (092107).

2. Auciello O, Krauss A R, Gruen D M, Meyer E M, Busmann H G, Tucek J, Sumant A, Jayatissa A, Moldovan N, Mancini D

C and Gardos M N Two- and three-dimensional ultra-nano crystalline diamond (UNCD) structures for a high resolution

diamond-based MEMS technology. Materials Research Society Symposium 605:73-78.

3. Dhote AM, AucielloO, GruenDMand Ramesh R (2001) Studies of thin filmgrowth and oxidation processes for conductive

Ti-Al diffusion barrier layers via in situ surface sensitive analytical techniques. Applied Physics Letters 79:800-802.

4. BusmannHG, PagelerA, BrauneckUandGruenDM(2000)Grainboundaries andmechanical properties of nanocrystalline

diamond films. Journal of Metastable and Nanocrystalline Materials 8:255-260.

5. Auciello O, Krauss A R, Jaemo I M, Dhote A, Gruen DM, Aggarwal S, Ramesh R, Irene E A, Gao Y andMueller AH (1999)

Studies of ferroelectric heterostructure thin films, interfaces, and device-related processes via in situ analytical techniques.

Integrated Ferroelectrics 27:103-118.

Biograpy

Dieter M Gruen is an Argonne Distinguished Fellow, Emeritus and President of Dimerond Technologies, LLC’s. He has completed his BS cum laude and MS degrees at

Northwestern University and his PhD in Chemical Physics at University of Chicago. He had a distinguished research career involving several disciplines of material science

relevant to fission and fusion energy.

dietergruen@comcast.net

Dieter M Gruen

Dimerond Technologies, USA