Monoclinic Li2FeSiO4 that crystallizes in P21/n space group was investigated as a potential cathode material for lithium-ion batteries. A combined X-ray diffraction and Mössbauer spectroscopy study was used for the structural investigation. It was found that the crystal structure is prone to an “antisite” defect, the one in which the Fe ion and the Li ion exchange places. This finding was also confirmed by the Mössbauer spectroscopy. In order to obtain composites of Li2FeSiO4 and carbon, several synthesis techniques that use different carbon sources were involved. Electrochemical performances were investigated through galvanostatic charge/discharge tests. Discharge curve profile did not reflect a two-phase intercalation reaction (no obvious voltage plateau) due to the low conductivity at room temperature

Avdeev, Max

Dominko, R.

Ivanovski, V. N.

Jokić, Bojan

Jugović, Dragana

Milović, Miloš

Mitrić, Miodrag

Uskoković, Dragan

Ivanovski, Valentin N.

Avdeev, Maxim

Dominko, Robert

Serbian Academy of Science and Arts Digital Archive (DAIS)

SIXTEENTH ANNUAL CONFERENCE   YUCOMAT 2014 Hunguest Hotel Sun Resort Herceg Novi, Montenegro,  September 1-5, 2014 http://www.mrs-serbia.org.rs     Programme  and  The Book of Abstracts    Organised by: Materials Research Society of Serbia   Endorsed by: Federation of European Material Societies and Materials Research Society Title:  THE SIXTEENTH ANNUAL CONFERENCE YUCOMAT 2014 Programme and The Book of Abstracts    Publisher: Materials Research Society of Serbia   Knez Mihailova 35/IV, 11000 Belgrade, Serbia   Phone: +381 11 2185-437; Fax: + 381 11 2185-263   http://www.mrs-serbia.org.rs    Editors:  Prof. Dr. Dragan P. Uskoković and Prof. Dr. Velimir Radmilović    Technical editor:  Aleksandra Stojičić    Cover page:  Aleksandra Stojičić and Milica Ševkušić Back cover photo: Author: Rudolf Getel Source: Flickr (www.flickr.com/photos/rudolfgetel/4280176487) Licence: CC BY 2.0    Copyright  2014 Materials Research Society of Serbia    Acknowledgments: This conference is held in honour of Prof. Dragan Uskoković’s 70th birthday.                        Printed in: Biro Konto   Sutorina bb, Igalo – Herceg Novi, Montenegro    Phones: +382-31-670123, 670025, E-mail: bkonto@t-com.me   Circulation: 220 copies. The end of printing: August 2014 SIXTEENTH ANNUAL CONFERENCE YUCOMAT 2014 Herceg Novi, September 1-5, 2014   6O.S.A.3 Li2FeSiO4 CATHODE MATERIAL: THE STRUCTURE  AND ELECTROCHEMICAL PERFORMANCES    Dragana Jugović1, M. Milović1, M. Mitrić2, V.N. Ivanovski2,  M. Avdeev3, B. Jokić4, R. Dominko5, D. Uskoković1 1Institute of Technical Sciences of SASA, Belgrade, Serbia, 2Vinča Institute of Nuclear Sciences, University of Belgrade, Belgrade, Serbia, 3Bragg Institute, Australian Nuclear Science and Technology Organisation, Locked Bag 2001, Kirrawee DC, NSW, Australia, 4Faculty of Technology and Metallurgy, University of Belgrade, Belgrade, Serbia, 5Laboratory for Materials Electrochemistry, National Institute of Chemistry, Ljubljana, Slovenia  Monoclinic Li2FeSiO4 that crystallizes in P21/n space group was investigated as a potential cathode material for lithium-ion batteries. A combined X-ray diffraction and Mössbauer spectroscopy study was used for the structural investigation. It was found that the crystal structure is prone to an “antisite” defect, the one in which the Fe ion and the Li ion exchange places. This finding was also confirmed by the Mössbauer spectroscopy. In order to obtain composites of Li2FeSiO4 and carbon, several synthesis techniques that use different carbon sources were involved. Electrochemical performances were investigated through galvanostatic charge/discharge tests. Discharge curve profile did not reflect a two-phase intercalation reaction (no obvious voltage plateau) due to the low conductivity at room temperature.    O.S.A.4 RHEED STUDY OF THE EARLY STAGES OF OXIDE FILM FORMATION AND QUANTIFICATION OF THE GROWTH KINETICS  Anatole N. Khodan1, M.V. Sorokin1, D.-G. Crete2 1National Research Center "Kurchatov Institute", Moscow, Russian Federation, 2Unite Mixte de Physique C.N.R.S./THALES, Palaiseau, France  RHEED was applied for in situ study of homoepitaxial SrTiO3 (STO) film growth with the aim to find accordance between estimations following from theoretical growth models and real film parameters measured by AFM, XRD and RHEED. Pulsed Laser Deposition (PLD) with constant pulse rate up to 5 Hz was used and relaxation kinetics of the deposited particles was estimated from RHEED intensity changes caused by the surface layer ordering. The proposed data treatment allowed us to estimate the relaxation rate in the deposited surface layer and the overall relaxation of the structure of homoepitaxial thin film. It has been shown that growth at temperatures above 650 °C is characterized by presence of surface phase. It mean, that experimental estimations of a kinetic processes at the surface are attributing first of all to the surface phase properties, whereas a growing film structure is formed deeper, under film-surface layer interface and determined by the conditions of phase stability. This structural transition occurs at depth, which exceeds the number of not completely filled monolayers. In this connection, the evolution of the theory of Smooth Multilayer Growth (SML) seems promising enough.

English

Li2FeSiO4 cathode material: the structure and electrochemical performances

Jokić, Bojan M.

Repository of the Vinča Nuclear Institute (VinaR)

Digital Repository of the Institute of Technical Sciences of SASA

SIXTEENTH ANNUAL CONFERENCE  
 
YUCOMAT 2014 
Hunguest Hotel Sun Resort Herceg Novi, Montenegro,  
September 1-5, 2014 
http://www.mrs-serbia.org.rs 
 
 
 
 
Programme  
and  
The Book of Abstracts 
 
 
 
Organised by: 
Materials Research Society of Serbia 
 
 
Endorsed by: 
Federation of European Material Societies 
and 
Materials Research Society 
Title:  THE SIXTEENTH ANNUAL CONFERENCE 
YUCOMAT 2014 
Programme and The Book of Abstracts 
 
 
 
Publisher: Materials Research Society of Serbia 
  Knez Mihailova 35/IV, 11000 Belgrade, Serbia 
  Phone: +381 11 2185-437; Fax: + 381 11 2185-263 
  http://www.mrs-serbia.org.rs 
 
 
 
Editors:  Prof. Dr. Dragan P. Uskoković and Prof. Dr. Velimir Radmilović 
 
 
 
Technical editor:  Aleksandra Stojičić 
 
 
 
Cover page:  Aleksandra Stojičić and Milica Ševkušić 
Back cover photo: Author: Rudolf Getel 
Source: Flickr (www.flickr.com/photos/rudolfgetel/4280176487) 
Licence: CC BY 2.0 
 
 
 
Copyright  2014 Materials Research Society of Serbia 
 
 
 
Acknowledgments: This conference is held in honour of Prof. Dragan Uskoković’s 70th birthday. 
 
                   
 
 
 
Printed in: Biro Konto 
  Sutorina bb, Igalo – Herceg Novi, Montenegro  
  Phones: +382-31-670123, 670025, E-mail: bkonto@t-com.me 
  Circulation: 220 copies. The end of printing: August 2014 
SIXTEENTH ANNUAL CONFERENCE 
YUCOMAT 2014 
Herceg Novi, September 1-5, 2014 
 
 
6
O.S.A.3 
Li2FeSiO4 CATHODE MATERIAL: THE STRUCTURE  
AND ELECTROCHEMICAL PERFORMANCES   
 
Dragana Jugović1, M. Milović1, M. Mitrić2, V.N. Ivanovski2,  
M. Avdeev3, B. Jokić4, R. Dominko5, D. Uskoković1 
1Institute of Technical Sciences of SASA, Belgrade, Serbia, 2Vinča Institute of Nuclear Sciences, 
University of Belgrade, Belgrade, Serbia, 3Bragg Institute, Australian Nuclear Science and 
Technology Organisation, Locked Bag 2001, Kirrawee DC, NSW, Australia, 4Faculty of 
Technology and Metallurgy, University of Belgrade, Belgrade, Serbia, 5Laboratory for Materials 
Electrochemistry, National Institute of Chemistry, Ljubljana, Slovenia 
 
Monoclinic Li2FeSiO4 that crystallizes in P21/n space group was investigated as a potential 
cathode material for lithium-ion batteries. A combined X-ray diffraction and Mössbauer 
spectroscopy study was used for the structural investigation. It was found that the crystal structure 
is prone to an “antisite” defect, the one in which the Fe ion and the Li ion exchange places. This 
finding was also confirmed by the Mössbauer spectroscopy. In order to obtain composites of 
Li2FeSiO4 and carbon, several synthesis techniques that use different carbon sources were 
involved. Electrochemical performances were investigated through galvanostatic charge/discharge 
tests. Discharge curve profile did not reflect a two-phase intercalation reaction (no obvious 
voltage plateau) due to the low conductivity at room temperature.  
 
 
O.S.A.4 
RHEED STUDY OF THE EARLY STAGES OF OXIDE FILM FORMATION AND 
QUANTIFICATION OF THE GROWTH KINETICS 
 
Anatole N. Khodan1, M.V. Sorokin1, D.-G. Crete2 
1National Research Center "Kurchatov Institute", Moscow, Russian Federation, 
2Unite Mixte de Physique C.N.R.S./THALES, Palaiseau, France 
 
RHEED was applied for in situ study of homoepitaxial SrTiO3 (STO) film growth with the 
aim to find accordance between estimations following from theoretical growth models and real 
film parameters measured by AFM, XRD and RHEED. Pulsed Laser Deposition (PLD) with 
constant pulse rate up to 5 Hz was used and relaxation kinetics of the deposited particles was 
estimated from RHEED intensity changes caused by the surface layer ordering. The proposed data 
treatment allowed us to estimate the relaxation rate in the deposited surface layer and the overall 
relaxation of the structure of homoepitaxial thin film. It has been shown that growth at 
temperatures above 650 °C is characterized by presence of surface phase. It mean, that 
experimental estimations of a kinetic processes at the surface are attributing first of all to the 
surface phase properties, whereas a growing film structure is formed deeper, under film-surface 
layer interface and determined by the conditions of phase stability. This structural transition 
occurs at depth, which exceeds the number of not completely filled monolayers. In this 
connection, the evolution of the theory of Smooth Multilayer Growth (SML) seems promising 
enough.


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Li2FeSiO4 cathode material: the structure and electrochemical performances

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Serbian Academy of Science and Arts Digital Archive (DAIS)

Repository of the Vinča Nuclear Institute (VinaR)

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