MINERALS AS a SOURCE of NOVEL Li-ION BATTERY ELECTRODE MATERIALS

MINERALS AS a SOURCE of NOVEL Li-ION BATTERY ELECTRODE MATERIALS

Macedonian Journal of Chemistry and Chemical Engineering, Vol. 34, No. 1, pp. 145–149 (2015) MJCCA9 – 674 ISSN 1857-5552 e-ISSN 1857-5625 Received: December 15, 2014 UDC: 549.091.3/.4:621.352 Accepted: February 17, 2015 Original scientific paper MINERALS AS A SOURCE OF NOVEL Li-ION BATTERY ELECTRODE MATERIALS Anti Liivat, Josh Thomas* Ångström Advanced Battery Centre, Department of Chemistry, Uppsala University, Box 538, SE-751 21 Uppsala, Sweden *[email protected] As a tribute to the major contribution made by Academician Gligor Jovanovski to the field of Mineralogy in Macedonia, this paper promotes the potential role that minerals can have as a future source of inspiration in identifying novel materials for sustainable energy storage in general, and for advanced Li-ion batteries in particular. We exemplify this by indicating the innovative use of polyanions in novel Li-ion battery cathode materials such as the olivine lithium iron phosphate (LiFePO4), and in an even newer material – the orthosilicate lithium iron silicate (Li2FeSiO4). Both materials have strong intrinsic links to mineralogy – and illustrate well how mineralogy can lead to new material breakthroughs in this and other areas of modern technology. Keywords: minerals; Li-ion battery; electrodes; cathodes МИНЕРАЛИТЕ КАКО ИЗВОР НА НОВИ МАТЕРИЈАЛИ ЗА ЕЛЕКТРОДИ НА ЛИТИУМСКИТЕ БАТЕРИИ Во чест на големиот придонес направен од страна на академик Глигор Јовановски на полето на минералогијата во Македонија, овој труд ја промовира потенцијалната улога што можат да ја имаат минералите како инспирација за идентификување нови материјали како извори за одржливо складирање на енергија воопшто, и особено за развој на литиумските батерии. Ова го докажуваме со индикација на иновативна употреба на полианјони во нови катодни материјали на Li-јонски батерии, како што се на пример оливин литиумжелезен фосфат (LiFePO4), и еден уште понов материјал – ортосиликат литиумжелезен силикат (Li2FeSiO4). Обата материјала имаат силна внатрешна врска со минералогијата – и добро илустрираат каква улога минералогијата може да има за продор на нови материјали во ова, но и во други подрачја на модерната технологија. Клучни зборови: минерали; Li-јон батерии; електроди; катоди 1. INTRODUCTION fuel-cell and supermagnet materials. We draw special attention here to the potential role of In spite of their inorganic and essentially minerals as a source of inspiration in these en- inanimate nature, minerals lie at the very core of deavors, while – at the same time – we pay tribute our search today for materials which can promote to the key role played by Professor Jovanovski in technological breakthroughs in many areas, not documenting the wealth of natural resources still least in the context of the needs of our modern waiting to be exploited in the rich mineral deposits society in the area of sustainable energy generation within the borders of Macedonia [1]. We and storage. The most obvious examples appear in demonstrate this potential through our on-going our hunt for new materials for solar-cell, battery, search worldwide for novel materials for energy Dedicated to Academician Gligor Jovanovski on the occasion of his 70th birthday. 146 A. Liivat, J. Thomas storage and conversion applications – especially in unexploited minerals? It has become increasingly the field of next-generation Li-ion battery technol- clear that the ultimate solution within available ogies; see [2]. battery (electro)chemistries must be based on the cheapest and most abundant transition-metal – iron 2. ENERGY STORAGE AND CONVERSION (Fe) – in combination with a graphite (C) or silicon MATERIALS (Si) anode. Iron (Fe) is the only truly cheap transition-metal, so iron-based cathodes have "Earth, air, fire, water" – these were believed recently come to dominate much of the current by the Ancient Greeks to be the basic building research effort in the area of large-scale Li-ion blocks (elements) of their World [3]. Seen in battery development [5]. today’s perspective, "air, fire, water" correspond to the essential material components in electro- 3. Fe-BASED Li-ION BATTERY chemical energy conversion devices now known as ELECTRODE MATERIALS fuel-cells, while the fourth element "earth" (read: the mineral content of the Earth’s crust) is the Pioneering work by Thackeray et al. [6] in source of active electrode materials in advanced the early 1980s demonstrated the feasibility of battery concepts, which are today proving so electrochemically inserting lithium into magnetite relevant to the development of next-generation (Fe3O4) and hematite (Fe2O3). Despite the fact that sustainable transport and communication solutions. the electrochemical potential of iron oxides is too As our global population continues to grow and low for practical cathode materials (< 2 V), the become more mobile, the reduction of Greenhouse foundations for the development of one of the most Gas (GHG) emissions from the transport sector important cathode materials – the manganese presents an ever more urgent challenge. They are spinel LiMn2O4 [7] – had been laid (Fig. 1). More currently responsible for roughly one third of the recently, however, the reversible conversion of World’s total GHG emissions [4]. The hematite into nanosize metallic iron has also development of on-board storage of electrical revived interest in developing high-capacity and energy derived from sustainable power sources in low-cost Fe-based anode materials for “green” Li- cheap, large-scale batteries is slowly emerging as a and Na-ion battery applications [8]. critical element of many long-term solutions. However, an efficient battery technology capable of meeting this challenge is still lacking to a large extent, mainly because of performance inadequacies in terms of energy- and power- density, safety, etc. Above all, their high cost can be seen as the major hinder holding back large- scale battery development. Although we have seen significant breakthroughs in recent years, these must be consolidated if we are to achieve commercially realistic sustainable solutions. It is already clear that rechargeable Li-ion batteries (as already used widely in mobile-phones and portable computers) are also fast becoming the battery of choice in next-generation hybrid and pure-electric (HEV, P-HEV and EV) vehicle concepts, as well Fig. 1. The structure of spinel AB2O4 (magnetite, as in large-scale sustainable energy storage hausmannite) shown for the Li-insertion material LiMn2O4, applications. No other battery technology has yet with Mn octahedral coordination (green) and Li-ions (yellow). to emerge to pose a serious challenge. As ever- LiMn2O4 spinel can be synthesized in a simple solid state larger Li-ion battery packs are developed, we will reaction of hausmannite (Mn3O4) and zabuyelite (Li2CO3), and provides a facile, three-dimensional network for Li-ion be forced to exploit significantly cheaper cathode diffusion. materials – with the cost of the cathode material corresponding to more than one-third of the total material costs in a Li-ion battery. Huge savings can A major breakthrough for Fe-containing Li- be made if the cost of cathode materials can be ion battery cathodes came with the demonstration reduced; so the question arises: can significant of electrochemical activity in the olivine structure breakthroughs be found amongst as yet lithium iron phosphate (LiFePO4) [9, 10]; a mate- Maced. J. Chem. Chem. Eng. 34 (1), 145–149 (2015) Minerals as a source of novel Li-ion battery electrode materials 147 rial occurring naturally as triphylite in pegmatite as occurring in the archetypal olivine deposits, converting to heterosite following the (Fe,Mg)2SiO4, see Figure 2. It has many clear ad- electrochemical extraction of lithium [11–13]. vantages over existing materials; see Table 1: LiFePO4 satisfies many of the demands – It is cheap – potentially even cheaper than which can be placed on a potential cathode materi- the phosphate derivatives – with iron and silicon al for large-scale Li-ion battery applications. Its oxides making up >10% of the Earth’s crust! strong covalent P-O bonds ensure electrochemical – Its two-dimensional network for Li-ion stability within a voltage range, where only a min- diffusion makes it less prone to conduction path- imal surface film (the so-called SEI layer) is way blockage and performance degradation due to formed on cell cycling [14]. LiFePO4 is also impurities, as occurs in one-dimensional channel “green” and relatively cheap. Its main drawback is materials like LiFePO4 [25]; this further reduces its its low electronic conductivity (ca. 10–9 S cm–1 at preparation costs since cheaper, less pure reactants room temperature), but the negative consequences can be used. of this have been minimized by reducing the effec- – It is an essentially “green” material with tive conduction path length, e.g., by preparing virtually no direct environmental hazards com- nano-size or nano-porous particles [15.16], and/or pared to cobalt-based cathodes, cf. LiCoO2. by coating the active particles with a thin electroni- – It has been shown to compare favourably cally conducting layer (generally carbon) [17]. One in terms of its mechanical, chemical and electro- serious problem still remains, however: its theo- chemical properties with other candidate cathodes, retical gravitometric capacity is still only ca. 170 and cycles well with low capacity loss. mAh/g, resulting in a 15–20% lower energy den- – It can also be prepared by a variety of syn- sity compared to that of the standard mobile-phone thetic techniques within the micro- and nano-range battery cathode material LiCoO2 [18]. Improve- of particle sizes necessary to combat the persisting ments on LiFePO4 have been sought intensively, problem of low electronic conductivity. and one of the more popular family of materials – As for LiFePO4, nano-coating facilitates under current focus is the neso- or orthosilicates the electronic wiring of the active cathode particles (from the Greek νησος (nesos): island); typically, to the current collector, where we can again expect the iron silicate system Li2FeSiO4 [19–24].

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