3D Printed Rechargeable Lithium-ion Batteries and High Performance Anode Materials Wang Ye Research Fellow.

Slides:

Advertisements

Similar presentations

How to power your smartphone for a week!. 2 Presentation name What is a battery? A device that stores chemical energy in its active materials and converts.

Advertisements

NPRE 498 Energy Storage Systems Garrett Gusloff 11/21/2014

PH 0101 Unit-5 Lecture-61 Introduction A fuel cell configuration Types of fuel cell Principle, construction and working Advantage, disadvantage and application.

Silicon Nanowires for Rechargeable Li-Ion Batteries Onur Ergen, Brian Lambson, Anthony Yeh EE C235, Spring 2009.

Structural and energy storage studies of Copper Oxide Mei Shiyuan 1, M.V. Reddy 2, 3*, S. Adams 3, B.V.R.Chowdan 2 1 SRP student, Hwa Chong Institution,

Sulfur-Rich Cathode Materials for High-Energy Batteries Achievement A family of new lithium polysulfidophosphate (LPSP) compounds enables stable cycling.

Commercial Voltaic Cells A voltaic cell can be a convenient, portable source of electricity. We know them as batteries. Batteries have been in use for.

Lithium-ion Batteries MEEN 3344 Shaun Miller.  More than half of the world’s lithium can be found under the Bolivian desert.  Spodumene (hard rock)

The Significance of Carbon Nanotubes and Graphene in Batteries and Supercapacitors Elena Ream and Solomon Astley.

Batteries Physics. Power Cell Device for storing chemical energy and then releasing it in the form of electricity when current is needed.

MOBILE POWER SOURCES TEAM 7. INTRODUCTION Chemical Batteries Mechanical Energy Wireless Energy Butane Energy.

CS 3651 – Prototyping Intelligent Appliances Batteries Georgia Institute of Technology.

Rechargeable Batteries By: Tolaz Hewa. Chemistry behind Batteries O A battery is a package that consist of one or more galvanic cells used for the production.

Fuel Cells and Rechargeable Batteries C5. C.5.1 Describe how a hydrogen oxygen fuel cell works. Alkaline fuel cells usually use a mobilized or immobilized.

6A Luk Pui Lam (7). Lead-acid accumulator Lithium battery charged A secondary cell is any kind of electrolytic cell in which the electrochemical reaction.

EE235 Nanofabrication John Gerling High-performance lithium battery anodes using silicon nanowires.

PH0101 UNIT-5 LECTURE 7 Introduction Types of battery Lithium battery

Rechargeable batteries!

The UK Energy Storage Supergen Consortium Prof Peter Hall Dept Chemical Engineering University of Strathclyde Glasgow Scotland.

Brian Kim 5/16/13.  Introduction  What are batteries?  Objective?  Materials and Method  Results and Discussion  Data and Evidence of the Data 

Modeling and study of lithium ion cell at Nano scale.

Tufts Lithium-ion Thin Film Rechargeable Battery.

Oxidation and Reduction

Rechargeable Batteries By: Tolaz Hewa. Chemistry behind Batteries O A battery is a package that consist of one or more galvanic cells used for the production.

By. A battery is an electric storage device, which can come in a variety of shape, size, voltage and capacity, and translate chemical energy into electricity.

Lithium-Ion Battery By QingjieBao. A lithium-ion battery (sometimes Li-ion battery or LIB) is a family of rechargeable battery types in which lithium.

Nanotechnology and the Lithium-ion Battery. Batteries in General –Electrolyte –Electrodes –Anode –Cathode Nanotechnology and the Lithium-ion Battery.

Salt Power Chloe Shreve and Helen Row.  It uses an electrochemical cell. In the cell there are anodes, cathodes and electrolytes that concert chemical.

CELL CELL IS A DEVICE WHICH CONVERT CHEMICAL ENERGY INTO ELECTRICAL ENERGY AND VICE VERSA.

Cells and Batteries A cell is a unit which includes two electrodes and one electrolyte.

PACEMAKER BATTERIES. Introduction -pacemaker  Small electrical device that runs on batteries.  Watches electrical signal of our heart and provide the.

Nanodots Nanocurves Nano-lithography/machining Nanogrids ~10 nm Atomic Force Microscope + Near Field Optics (Grigoroporos, UC Berkeley) Manufacturing /

Lithium Ion Batteries Science of Energy Technologies Utkarsh Gupta Rajaswit Das October 08, 2015.

LITHIUM POLYMER BATTERIES DAVID AUSLENDER NICHOLAS FORTENBERRY.

Electrochemical Cells in Actions Batteries and Fuel Cells Chapter 15.

SEC 598 – PV SYSTEMS ENGINEERING Project -1 A Brief Study on Lithium-Ion Battery Technology For Large Scale Residential Systems - GOVINDARAJASEKHAR SINGU.

Introduction Introduction Background Background Objectives Objectives Design Specifications Design Specifications Risk Analysis Risk Analysis Budget Budget.

Electrochemical Reactions. Anode: Electrons are lost due to oxidation. (negative electrode) Cathode: Electrons are gained due to reduction. (positive.

ALEX LOPEZ Tesla Batteries. Timeline July Tesla Motors is incorporated February 2004 – Elon Musk becomes chairman of Tesla, investing $7.5 million.

Battery Models. EMF and voltage What is EMF? – Electro Motive Force What is the difference between EMF and battery voltage? – The battery has internal.

BIO BATTERY a fuel of next generation… Submitted By:- Abhinav Pathak 10EUDEC002.

Electrochemical Reactions. Anode: Electrons are lost due to oxidation. (negative electrode) Cathode: Electrons are gained due to reduction. (positive.

Circuit Electricity. Electric Circuits The continuous flow of electrons in a circuit is called current electricity. Circuits involve… –Energy source,

Project Overview  Introduction  Frame Build  Motion  Power  Control  Sensors  Advanced Sensors  Open design challenges  Project evaluation.

Lithium-Ion Battery By QingjieBao.

Secondary Cell Nickel Cadmium (NiCd) Cells and Batteries

Engineering Chemistry CHM 406

John Mortimer, Fan Xia and Junjie Niu

Date of download: 10/17/2017 Copyright © ASME. All rights reserved.

Prepared by T Vigneshkumar S Vijayakumar

TO MEET AUTOMOTIVE POWER NEEDS

Engineering Chemistry

H2-O2 FUEL CELL By Mrs. Anuja Kamthe.

Jian Sun Director Center for Future Energy Systems.

BIO BATTERY -Power For Future

JINGYU SI Mechanical Engineering Department

Volume 2, Issue 2, Pages (February 2017)

1. Introduction to Electrochemical Cells

Nat. Rev. Mater. doi: /natrevmats

Aim # 36: What is the difference between a

High-Energy Li Metal Battery with Lithiated Host

Lithium Sulfur Batteries

In-Situ observation of lithium dendrites in lithium metal anodes

JINGYU SI Ph.D. Dissertator Mechanical Engineering Department

Voltage in Electrical Systems

Fig. 5 Electrochemical performance of stretchable aqueous rechargeable lithium-ion battery using a GAP multilayer conductor as a current collector. Electrochemical.

A. Oxidation-Reduction Reactions

Electric Double Layer Capacitors aka Coin Cell Supercapacitors

Presentation transcript:

3D Printed Rechargeable Lithium-ion Batteries and High Performance Anode Materials Wang Ye Research Fellow

2 Energy transmission High efficient energy storage devices Daily applications Market: million dollars Advantages of lithium ion batteries: 1. Various shape and size. 2. No memory effect.3. Environment friendly, non-toxic element. 4. Low cost. 5. High voltage. 6. Large energy density. 7. High cycle-life. 8. Low self-discharge rate. Introduction: Energy storage and 3D printing technology Distribution

Introduction: 3D printing technology Outstanding performance1 st 3D printed LIBs. Issue: High temperatureNot wearable 1.Zhu, C. etc. Nat. Commun. 2015, 6. 2.Sun, K. etc. Adv. Mater. 2013, 25, (33), D printing technology 1 st 3D printed micro-LIBs Why 3D Battery! DIW (direct ink writing) print graphene aerogel Additive technology! 3D! Large area, High power/energy density.

My work on 3D printed Lithium ion batteries Direct ink writing LIBs Fabrication process (a)Print/write current collector, anode, cathode electrodes. (b)Packaged by PDMS block. (c)Fill in electrolyte. Result: (a)Flexible substrate (b)Can power 10 LEDs for mins (c)Capacity: 0.05 mAh per cell How to improve : High performance active materials, device architecture! Achievement: 3D printed micro-LIBs (proof-of-concept) Fabrication processSet up: new direct writing 3D printer Set-up principle:  Robot move dispenser in X Y Z directions.  Drop/print ink on demand in line.  Line forms when Ink solidified by evaporating solvent by heating.

How to improve the performance? Please go to Poster 125 for more details!