Advanced Energy Storage Materials for Battery Applications. Advanced Materials December 12 th, 2012. Peter H.L. Notten

Similar documents

Microstockage d énergie Les dernières avancées. S. Martin (CEA-LITEN / LCMS Grenoble)

Microstockage d énergie Les dernières avancées. S. Martin (CEA-LITEN / Grenoble)

Solar Photovoltaic (PV) Cells

Storage technologies/research, from physics and chemistry to engineering

State of Solid-State Batteries

Steve Harris. UC Berkeley

Design of inductors and modeling of relevant field intensity

Second International Renewable Energy Storage Conference November 2007 Bonn/Germany. Overview on current status of lithium-ion batteries

WŝŽŶĞĞƌŝŶŐ > ĞǆƉĞƌŝĞŶĐĞ ƐŝŶĐĞ ϭϵϳϰ WŝĐŽƐƵŶ ^he > Ρ ZͲƐĞƌŝĞƐ > ƐǇƐƚĞŵƐ ƌŝěőŝŷő ƚśğ ŐĂƉ ďğƚǁğğŷ ƌğɛğăƌđś ĂŶĚ ƉƌŽĚƵĐƟŽŶ d, &hdhz K& d,/e &/>D /^, Z

鋰電池技術及產業發展趨勢

Micro-Power Systems for Ambient Intelligence

The Lithium-Ion Battery. Service Life Parameters

U N. Supercapattery: A Super Battery Approach. George Z. Chen

A Comparison of Lead Acid to Lithium-ion in Stationary Storage Applications

Capacitors for Power Grid Storage

High Energy Rechargeable Li-S Cells for EV Application. Status, Challenges and Solutions

Lithium-Ion Battery Safety Study Using Multi-Physics Internal Short-Circuit Model

Sony s Energy Storage System. The Sony Lithium Ion Iron Phosphate (LFP) advantage

How Much Lithium does a LiIon EV battery really need?

Baterías de flujo: conceptos y aplicación futura. Catalonia Institute for Energy Research

Development of Materials for Mobile-use Lithium-ion Batteries and Fuel Cells

Nanotechnologies for the Integrated Circuits

Damage-free, All-dry Via Etch Resist and Residue Removal Processes

LITHIUM/AIR SEMI-FUEL CELLS: HIGH ENERGY DENSITY BATTERIES BASED ON LITHIUM METAL ELECTRODES

Supporting Information

Solar Powered Wireless Sensors & Instrumentation: Energy Harvesting Technology Reduces Operating Cost at Remote Sites

Electric Battery Actual and future Battery Technology Trends

Sputtered AlN Thin Films on Si and Electrodes for MEMS Resonators: Relationship Between Surface Quality Microstructure and Film Properties

ALD from Lab to Fab Atom Level Control for Industrial Thin Films Kokkola Material Week September 23, 2014

Overview of Energy Harvesting Systems (for low-power electronics)

Sodium Sulfur Battery. ENERGY STORAGE SYSTEM for Reducing CO2 Emissions

Modification of Pd-H 2 and Pd-D 2 thin films processed by He-Ne laser

Energy Storage Systems Li-ion Philippe ULRICH

ES Program ORNL. Michael R. Starke, PhD Oak Ridge National Laboratory Power and Energy Systems Energy & Transportation Science Division

Picosun World Forum, Espoo years of ALD. Tuomo Suntola, Picosun Oy. Tuomo Suntola, Picosun Oy

Fuel Cells for Renewable Energy and for Transportation IFCBC Meeting Prof. E. Peled School of Chemistry Tel Aviv University, Israel

Photolithography. Class: Figure Various ways in which dust particles can interfere with photomask patterns.

能量採集技術簡介及發展現況

ELG4126: Photovoltaic Materials. Based Partially on Renewable and Efficient Electric Power System, Gilbert M. Masters, Wiely

Results Overview Wafer Edge Film Removal using Laser

DEVELOPMENTS & TRENDS IN FEOL MATERIALS FOR ADVANCED SEMICONDUCTOR DEVICES Michael Corbett mcorbett@linx-consulting.com Semicon Taiwan2015

T. Suntola: 30 years of ALD ALD 2004, Aug , 2004, University of Helsinki, Finland. 30 years of ALD Tuomo Suntola

Vacuum Evaporation Recap

IAA Commercial Vehicles Battery Technology. September 29 th, 2010

Micro-Power Generation

Chem 1721 Brief Notes: Chapter 19

Abuse Testing of Lithium Ion Cells: Internal Short Circuit, Accelerated Rate Calorimetry and Nail Penetration in Large Cells (1-20 Ah)

MAKING LITHIUM-ION SAFE THROUGH THERMAL MANAGEMENT

Exploring the deposition of oxides on silicon for photovoltaic cells by pulsed laser deposition

Ultra-High Density Phase-Change Storage and Memory

1. PECVD in ORGANOSILICON FED PLASMAS

Reactive Sputtering Using a Dual-Anode Magnetron System

Pacers use a 5-letter code: first 3 letters most important

Solid Oxide Fuel Cell Development at Topsoe Fuel Cell A/S

Sn-Cu Intermetallic Grain Morphology Related to Sn Layer Thickness

Optical Properties of Sputtered Tantalum Nitride Films Determined by Spectroscopic Ellipsometry

How To Make A Plasma Control System

Introduction to VLSI Fabrication Technologies. Emanuele Baravelli

Performance of Carbon-PTFE Electrodes and PTFE Separators in Electrochemical Double Layer Capacitors (EDLCs)

Energy Harvesting in Practical Applications. Roy Freeland President, Perpetuum Ltd

Coating Technology: Evaporation Vs Sputtering

Supercapacitors. Advantages Power density Recycle ability Environmentally friendly Safe Light weight

Lezioni di Tecnologie e Materiali per l Elettronica

Neal O Hara. Business Development Manager

Basic Properties and Application Examples of PGS Graphite Sheet

Silicon Wafer Solar Cells

Supporting information

Through-mask Electro-etching for Fabrication of Metal Bipolar Plate Gas Flow Field Channels

Practical Examples of Galvanic Cells

The Internet of Things: Opportunities & Challenges

ISOTROPIC ETCHING OF THE SILICON NITRIDE AFTER FIELD OXIDATION.

Micro Power Generators. Sung Park Kelvin Yuk ECS 203

Solid State Detectors = Semi-Conductor based Detectors

Study on Wet Etching of AAO Template

F ormation of Very Low Resistance Contact for Silicon Photovoltaic Cells. Baomin Xu, Scott Limb, Alexandra Rodkin, Eric Shrader, and Sean Gamer

Neuere Entwicklungen zur Herstellung optischer Schichten durch reaktive. Wolfgang Hentsch, Dr. Reinhard Fendler. FHR Anlagenbau GmbH

The Tesla Roadster battery pack is comprised of about 6800 of these cells, and the entire pack has a mass of about 450kg.

Chemical Sputtering. von Kohlenstoff durch Wasserstoff. W. Jacob

Building Battery Arrays with Lithium-Ion Cells

ELECTRIC VEHICLES WITH V2G

A metal-free polymeric photocatalyst for hydrogen production from water under visible light

Effect of Dissolved CO 2 in De-ionized Water in Reducing Wafer Damage During Megasonic Cleaning in MegPie. Arizona 85721, USA. Arizona 85721, USA

PHYSICS PAPER 1 (THEORY)

TRANSPORT OF DANGEROUS GOODS

EVERGREEN (C.P.) USA INC. TEL: (650) FAX: (650) SPECIFICATIONS Lithium Battery CR123A- 1700mAh

Automotive Lithium-ion Batteries

Optical Hyperdoping: Transforming Semiconductor Band Structure for Solar Energy Harvesting

Coating Thickness and Composition Analysis by Micro-EDXRF

UN Manual of Tests and Criteria, Sub-section 38.3, Amendments to the 5 th edition, effective 2014 January 1 st

The Future of Battery Technologies Part I

Dry Etching and Reactive Ion Etching (RIE)

Energy Harvesting Powered Wireless Sensor Node and Asset Tracking Solutions in Random Vibration Environments

NANO SILICON DOTS EMBEDDED SIO 2 /SIO 2 MULTILAYERS FOR PV HIGH EFFICIENCY APPLICATION

Sputtering Targets and Sputtered Films: Technology and Markets

Spectroscopic Ellipsometry:

Development of Grid-stabilization Power-storage Systems Using Lithium-ion Rechargeable Batteries

Transcription:

Advanced Energy Storage Materials for Battery Applications Advanced Materials December 12 th, 2012 Peter H.L. Notten Eindhoven University of Technology p.h.l.notten@tue.nl >> Focus on sustainability, innovation and international

Diversification Automotive : The dream Automotive System Batteries Supercaps Fuel Cells µ-power Batteries Fuel Cells Portable Batteries Mini-FC Autonomous devices Integrated Batteries Supercaps Energy density mwh Wh kwh

Diversification Automotive : The dream Automotive System Batteries Supercaps Fuel Cells µ-power Batteries Fuel Cells Portable Batteries Mini-FC Autonomous devices Integrated Batteries Supercaps Energy density mwh Wh kwh

Ambient Intelligence In-Home Autonomous devices optical Server 1Gb/s Residential Ambient Intelligence Server 100bit/s 5Mb/s µwatt node mwatt node 10Gb/s Router ~ 10 other homes 100Mb/s Watt node

Autonomous device Light Temperature Speed Vibrations Magnetic Acoustics Moisture Air pressure Sensor(s) Communication Microcontroller Energy scavenging Power Supply Energy storage Optical RF Acoustics Light Temperature Vibrations Acoustic waves

Thin Film Micro-batteries

Li-ion battery concept lithium electrode cobaltoxide electrode storage capacity LiC ch Li + e - Li + - CoO 2 charge C Li + e - d LiCoO 2 discharge

Planar All-Solid-State batteries Drawbacks: Low storage capacity: only 45 µah/cm 2. µm Low power capability Metallic Lithium moving interface low melting point

Phase diagram LiSi Li 21 Si 5

Morphology after Li-(de)intercalation in single-crystal Si-wafer 2 µm Philips 50 µm

Li-storage in Si-nanowires B. Laic, Electrochim. Acta, 53 (2008) 5528. L. Baggetto, Thesis Eindhoven University (2010).

Li-storage in Si-nanowires L. Baggetto, Thesis Eindhoven University (2010).

Li-storage in honeycomb-structured Si before Lithiation L. Baggetto et al., Adv. Mater. 23 (2011) 1563.

Li-storage in honeycomb-structured Si before Lithiation L. Baggetto et al., Adv. Mater. 23 (2011) 1563.

Li-storage in honeycomb-structured Si before Lithiation after Lithiation L. Baggetto et al., Adv. Mater. 23 (2011) 1563.

Li-storage in honeycomb-structured Si before Lithiation after Lithiation L. Baggetto et al., Adv. Mater. 23 (2011) 1563.

Li-storage in honeycomb-structured Si before Lithiation after Lithiation L. Baggetto et al., Adv. Mater. 23 (2011) 1563.

Li-storage in honeycomb-structured Si 0 % 15 % 40 % 70 % 100 % L. Baggetto et al., Adv. Mater. 23 (2011) 1563.

LPCVD p-si thin film electrodes φ=15 mm Ti N p-si O-ring Patterning provides an accurate amount of active material p-si Ti N

Thin film Si-electrode Silicon: >3500 >3000 mah/g Graphite: 375 mah/g!

Rate capability Si-electrode 1 300 C, 0.2 min 0.75 E(V) 0.5 0.25 0.1 C, 10 hours 0 0 850 1700 2550 3400 Baggetto et al., Adv. Funct. Mat. 18 (2008) 1. Capacity (mah/g)

Cycle-life of 50nm-thick PECVD a-si 3500 Capacity (mah/g) 2500 1500 500 Liquid electrolyte 0 10 20 30 40 50 60 70 Cycle Notten et al., Adv. Mat., 19 (2007) 4564.

Cycle-life of 50nm-thick PECVD a-si 3500 Capacity (mah/g) 2500 1500 Solid-state electrolyte 500 Liquid electrolyte 0 10 20 30 40 50 60 70 Cycle Notten et al., Adv. Mat., 19 (2007) 4564.

Planar all-solid-state battery Current collector LiCoO 2 Solid-state electrolyte Metallic Li Philips Storage capacity: 45 µah/cm 2. µm

Integrated All-Solid-State battery. Si-substrate Notten et al., Adv. Mat., 19 (2007) 4564.

Integrated All-Solid-State battery - Current collector. Si-substrate Notten et al., Adv. Mat., 19 (2007) 4564.

Integrated All-Solid-State battery - Current collector. Si-substrate Notten et al., Adv. Mat., 19 (2007) 4564.

Integrated All-Solid-State battery - Current collector.. Si-substrate Barrier layer Notten et al., Adv. Mat., 19 (2007) 4564.

Integrated All-Solid-State battery - Current collector... Si-substrate Si Barrier layer Notten et al., Adv. Mat., 19 (2007) 4564.

Integrated All-Solid-State battery - Current collector Solid electrolyte.... Si-substrate Si Barrier layer Notten et al., Adv. Mat., 19 (2007) 4564.

Integrated All-Solid-State battery -. Current collector LiCoO 2 Solid electrolyte.... Si-substrate Si Barrier layer Notten et al., Adv. Mat., 19 (2007) 4564.

Current collector, e.g. Pt + Integrated All-Solid-State battery - Current collector LiCoO 2. Solid electrolyte.... Si-substrate Si Barrier layer Notten et al., Adv. Mat., 19 (2007) 4564.

Surface area calculation A = 2 ll + 2hl ( L ( w + s) s) L L = 1 cm l = 1 cm s = 2 µm w = 2 µm h = 50 µm s w h l A = 50 cm 2 /cm 2 Notten et al., Adv. Mat., 19 (2007) 4564.

Autonomous integrated energy system Integrated solar cell Integrated battery

In vivo Integrated Energy system Integrated fuel cell Integrated battery

RIE-etching of slits in crystalline-si Surface 10 µm Notten et al., Adv. Mat., 19 (2007) 4564. 2 µm

RIE-etching of pores in crystalline-si Cross-section Surface 5 µm 5 µm Notten et al., Adv. Mat., 19 (2007) 4564.

LPCVD reactor

Plasma-assisted ALD Home-built ALD-I system (remote plasma, 4 wafers, open-load) Oxford Instruments FlexAL system (remote plasma, 8 wafers, loadlock)

ALD-deposited 3D-TiN Top Aspect ratio=21; T dep =90 o C; plasma exposure=20 s Bottom

LPCVD 3D-Si anode Top TiN Middle Bottom Si Si-substrate Si TiN Si-substrate

LPCVD 3D-LiCoO 2 cathode 500 nm 10 µm 400 nm

Q Battery =10.000 Notten et al., Adv. Mat., 19 (2007) 4564. * Q Integrated capacitors! Roozeboom, et al., Thin Solid Films 504 (2006) 391.

All-solid-state batteries a challenging route towards 3D-integration facilitating future Autonomous devices Medical implants

Targeted specifications All-solid-state micro-batteries 40-60x surface enlargement increasing Energy and Power density Capacity density: 2 mah / µm.cm 2 (double-sided) Voltage: 3.8 V Energy density: 10 mwh / µm.cm 2 ( 1 $) Power density: 1 mw / µm.cm 2 at 0.1 C-rate 100 mw / µm.cm 2 at 10 C-rate Notten et al., Adv. Mat., 19 (2007) 4564.

LPCVD deposition of LiTaO 3 electrolyte -20 T (K) 900 800 700 600 Ln Rdep(mole cm -2 s -1 ) -22-24 -26-28 -30 Diffusion controlled Kinetically controlled -32 1 1.2 1.4 1.6 Inverse of the Susceptor Temperature ( 10-3 K -1 )

LPCVD deposition of LiTaO 3 electrolyte -20 T (K) 900 800 700 600 Ln Rdep(mole cm -2 s -1 ) -22-24 -26-28 -30 Diffusion controlled Kinetically controlled 10 µm 3 µm Diffusion controlled Kinetically controlled 873 K, 5 h 773 K, 5 h 673 K, 20 h -32 1 1.2 1.4 1.6 Inverse of the Susceptor Temperature ( 10-3 K -1 ) 1 µm

Pinholes creating art.!

Pinholes creating art.!

Q Battery =10.000 Notten et al., Adv. Mat., 19 (2007) 4564. * Q Integrated capacitors! Roozeboom, et al., Thin Solid Films 504 (2006) 391.