EL PARTNER TECNOLÓGICO STABLE – Reference Li-air cell.

Slides:

Advertisements

Similar presentations

How to Make Battery Web:

Advertisements

STABLE Description WP3 LEITAT– January,2013 Synthesis and optimization of electrolyte of Li-air cells David Amantia Christophe Aucher LEITAT STABLE WP3.

Polymer graphite composite anodes for Li-ion batteries Basker Veeraraghavan, Bala Haran, Ralph White and Branko Popov University of South Carolina, Columbia,

STATO DI SVILUPPO DELL’ACCUMULO ENERGETICO PER VIA ELETTROCHIMICA

Current trends in materials development for Li-ion batteries

Filippo Parodi /Paolo Capobianco (Ansaldo Fuel Cells S.p.A.)

Materials for Electrochemical Energy Conversion

Molten Salt Method of Preparation and Optimization of TiO 2 Phases Chan Tze Yang, Aloysius 1,2, M.V. Reddy 2,3 *, S. Adams 3 and B.V.R. Chowdari 2 1 SRP.

Biological Engineering Electrochemistry & Virus-Templated Electrodes F. John Burpo Biomolecular Materials Laboratory Massachusetts Institute of Technology.

Created by C. Ippolito March 2007 Updated March 2007 Chapter 22 Electrochemistry Objectives: 1.describe how an electrolytic cell works 2.describe how galvanic.

Battery University online: Brief history of the battery.

Electrochemical Cells

Galvanic Cells What will happen if a piece of Zn metal is immersed in a CuSO 4 solution? A spontaneous redox reaction occurs: Zn (s) + Cu 2 + (aq) Zn 2.

Types of Electrochemical Cells Electrolytic Cells: electrical energy from an external source causes a nonspontaneous reaction to occur Voltaic Cells (Galvanic.

Oxidation and reduction reactions occur in many chemical systems. Examples include the rusting of iron, the action of bleach on stains, and the reactions.

Studies on Capacity Fade of Spinel based Li-Ion Batteries by P. Ramadass, A. Durairajan, Bala S. Haran, R. E. White and B. N. Popov Center for Electrochemical.

Please Pick Up Electrochemical Cells Problem Set.

High Capacity Graphite Anodes for Li-Ion battery applications using Tin microencapsulation Basker Veeraraghavan, Anand Durairajan, Bala Haran Ralph White.

Capacity Fade Studies of LiCoO 2 Based Li-ion Cells Cycled at Different Temperatures Bala S. Haran, P.Ramadass, Ralph E. White and Branko N. Popov Center.

Prabhu Ganesan, Hector Colon, Bala Haran, R. E. White and Branko Popov Department of Chemical Engineering University of South Carolina, Columbia, SC

Electrochemistry Two broad areas Galvanic Rechargeable Electrolysys Cells batteries Cells.

Electrochemistry Ch. 17. Moving Electrons What kind of chemical reaction relates to the concept of electricity? What kind of chemical reaction relates.

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

Nanotechnology for Future Batteries

Tufts Lithium-ion Thin Film Rechargeable Battery.

Thin Film & Battery Materials Lab. National Research Lab. Kangwon Nat’l Univ. Heon-Young Lee a, Seung-Joo Lee b, Sung-Man Lee a a Department of Advanced.

Electrochemistry. Electrochemical Cells  Electrons are transferred between the particles being oxidized and reduced  Two types –Spontaneous = Voltaic.

ELECTROLYSIS Decomposition using an electric current.

1 Niobium Powder Production in Molten Salt by Electrochemical Pulverization Boyan Yuan * and Toru H. Okabe ** *: Graduate Student, Department of Materials.

11/8/ Development of Lithium Batteries for Powering Sensor Arrays SFR Workshop November 8, 2000 Nelson Chong, James Lim, Jeff Sakamoto and Bruce.

STABLE Kick-off meeting Torino – October 25 th - 26 th,2012 POLITO’s proposal for measurement standard cell STABLE project 1 st skype call November 22.

Group 07 Kristen Losensky Trenton Wood

Thin Film & Battery Materials Lab. National Research Lab. Kangwon Nat’l Univ. AS deposited LiCoO 2 thin film cathodes prepared by RF magnetron sputtering.

Chapter 17 Corrosion and Degradation of Materials.

SOLID OXIDE FUEL CELL BASED ON PROTON- CONDUCTING CERAMIC ELECTROLYTE* U. (Balu) Balachandran, T. H. Lee, and S. E. Dorris Argonne National Laboratory.

NOVEL NANOARRAY STRUCTURES FORMED BY TEMPLATE BASED APPROACHES: TiO 2 NANOTUBES ARRAYS FABRICATED BY ANODIZING PROCESS COMPOSITE OF V 2 O 5 AEROGEL NANOWIRES.

Mitglied der Helmholtz-Gemeinschaft DEPOSITION OF CORROSION PREVENTING COATINGS FOR DUAL-ION BATTERIES Motivation The CV and CA diagrams confirm the electrochemical.

STABLE Kick-off meeting Torino – October 25 th - 26 th,2012 LUREDERRA’s proposal of commercial compounds to be used as anode, cathode and electrolyte STABLE.

STABLE Kick-off meeting Torino – October 25 th - 26 th,2012 Synthesis and optimization of electrolyte of Li-air cells David Amantia Christophe Aucher LEITAT.

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

Chemical Energy Energy that is released via chemical reactions.

9.2 Electrochemical cells. Two types of electrochemical cells Voltaic cell Spontaneous Chemical  Electrical Uses activity differences between two metals.

Chapter 7 Electrochemistry § 7.6 Reversible cell.

Zn (s) + Cu2+ (aq)  Zn2+ (aq) + Cu (s)

Photovoltaic Systems Engineering

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

BATTERIES THAT CHARGES ON AIR

Ch. 20: Electrochemistry Lecture 4: Electrolytic Cells & Faraday’s Law.

Chemistry AS – Redox reactions

Overview of Lithium-Air (Lithium-Oxygen) Batteries

Abstract Questions Results Methods & Materials A Learning Process

Senior Design : Shape Conformable Battery Pack

Electrochemical cells

Senior Design : Shape Conformable Battery Pack

JINGYU SI Mechanical Engineering Department

4.0 V Aqueous Li-Ion Batteries

10.2 Electrochemistry Objectives S2

Redox #’s 1-5 #1) The reaction absorbs energy, therefore it is electrolytic (A). #3) Electrolysis requires an external power source (A). #4) Reduction.

Multinuclear NMR Probehead for in situ

Electrochemistry.

Catalyst coated membrane for zero-gap alkaline water electrolyzer

Sujong Chae, Minseong Ko, Kyungho Kim, Kihong Ahn, Jaephil Cho Joule

Cycling Li-O2 batteries via LiOH formation and decomposition

Sujong Chae, Minseong Ko, Kyungho Kim, Kihong Ahn, Jaephil Cho Joule

Lithium Sulfur Batteries

Zn (s) + Cu2+ (aq)  Zn2+ (aq) + Cu (s)

Lithium-Anode Protection in Lithium–Sulfur Batteries

Ashlee N. Gordon Mentor: Dr. Quinton Williams 20 July 2018

Cycling Li-O2 batteries via LiOH formation and decomposition

Presentation transcript:

EL PARTNER TECNOLÓGICO STABLE – Reference Li-air cell

2 Outline -Cell configuration (general) -Li-Anode (WP1) - Separator (WP1) -Air-cathode material (WP2) - Electrolyte - Characterization

33 Reference conditions Gas Type Cell Collector Anode AnodeMembrane Collecteur Cathode Cathode O2 (99,99998%) Swagelok Copper Rod (or copper foam) Lithium chips Wahtman GF/A Alluminium (Al) tube (or stainless steel) + SS spring + component melt by spot resistance Al tube (or SS tube) AirCoin Cell Stainless Steel (SS) Lithium chips Wahtman GF/A SS mesh + SS spring + component melt by spot resistance SS mesh Electrolyte OrganicRTIL SolventSaltSolventSalt EC/DECLiPF6EMITFSILiTFSI NB1: This is not only a blibliographic research. Theses configurations are used at the moment NB2: Pouch cell is the step farther

4 Cell configuration Swagelok cell (O 2 ) Name: PFA Swagelok tube fitting ½ inch Reference: PFA Web link: 6&item=2b c169-4f69-bac4-8bfa338a165b# 6&item=2b c169-4f69-bac4-8bfa338a165b# Active surface area: 10 mm-diameter Current collector: Anode: Copper rod Cathode: Al or Stainless steal tube Coin cell (Air) Name: Meshed CR2032 Coin Cells Cases (20d x 3.2mm) for Lithium Air Battery Research (1 pair with seal O-ring) Reference: EQ-CR2032-CASE-304-MES Web link: aspx aspx Active surface area: 14 mm-diameter

5 Air-cathode materials Current collector: 304 Stainless Steel Meshed Disc (80 mesh woven from mm dia. Wire, Alfa Aesar) as Electrode Substrate for CR2032 – EQ-SSMD-304 (MTI.Corp.) Active material: Graphite Super C65 (CAS: – TIMCAL) Binder: PVDF ADX 161 (CAS: – Arkema) Solvent for slurry preparation: N-methyl-2-pyrrolidone (CAS: – Sigma Aldrich, anhydrous, 99.5% )  Diameter for Swagelok cell: 10 mm  Diameter for coin cell: 14 mm Composition ref.

6 Swagelok cell Why is it the good choice. -Everybody is using it, easier to compare to previous results -Cheap and Versatile cell: Possibility to change each component one by one Possibility to tune (melting by spot resistance, 2 or 3 electrodes, line of several cells…) Contacts melt by spot resitance Gas in Gas out Vale for charge /discharge Battery

7 Anode materials Active material: Lithium (CAS: ) Name: Lithium Chip 15.6 Diax0.25t mm for Li-ion Battery R&D 100g/bottle (4000 pcs) Reference: EQ-Lib-LiC25 Web link: Name: Lithium ( Li ) Foil: 30000mm Length x 35 mm Width x 0.17mm Thick Reference: Lib-LiF-30M Web link:  Diameter for Swagelok cell: 12 mm  Diameter for coin cell: 14 mm Copper foam for nanostructuration (lithium eletrodepositon), disc of 12 mm taken from Good fellow (LS396347), 6.35 mm, 0.85/cm 2, 99.9%, 16 Pores/cm, 150 x 150 mm, 120g.

8 Electrolyte Carbonate-based electrolyte Solvent: EC/DEC (2/1 volume).. Working very well, better than DMC or PC mielts. EC: Ethylene carbonate (CAS: – Sigma Aldrich ) DEC: Diethyl carbonate (CAS: – Sigma Aldrich ) Salt: LiPF 6 – Lithium hexafluorophosphate (CAS: – Sigma Aldrich ) Concentration: 1 mol/L Ionic liquid electrolyte EMIM TFSI – 1-Ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide (CAS: – Sigma Aldrich 11291) LiTFSI – Bis(trifluoromethane)sulfonimide lithium salt (CAS: – Sigma Aldrich ) Concentration: 1 mol/L

9 Separator Name: Whatman® glass-fiber filter paper, Grade 25 Reference: Z EA Web link:  Diameter for Swagelok cell: 10 mm  Diameter for coin cell: 16 mm  LISICON commercially available ??

10 Electrochemical characterization  Method - Galvanostatic charge /discharge, cycling: Current: 50 to 1000 µA/cm 2 Potential window: [2 V : 4 V] -Impedance spectroscopy: ± 200 mV to E OC  Gas -Condition 1: O 2 / Flow rate: 0.1 SCFH (Premier or Ultrapuro Plus, < 5 or < 2 ppm of inpurities) -Condition 2: Mediterranean Air atmosphere of Barcelona.

11 Leitat team ContactDivisionPositionTasks David Amantia, PhD. Nano Material External coordinator (STABLE) Team leader Co-leader STABLE (LEITAT) Coordination External/Internal Materials Christophe Aucher, PhD. Renewable Energy Researcher Co-leader STABLE (LEITAT) Co-Coordination Internal Electrochemistry Albert Almarza, engineer Nano MaterialResearcherMaterial Étienne Knipping, engineer Renewable EnergyResearcherElectrochemistry José A. Sáez, PhD. Smart SystemTeam leaderModeling / Simulation