The Role of Sulfide Additives in Achieving Long Cycle Life Rechargeable Iron Electrodes in Alkaline Batteries

Beneficial effects of carbon grafting into the iron active material for rechargeable alkaline-iron-electrodes with and without Bi 2 S 3 additive is probed by in situ X-ray diffraction in conjunction with Extended X-ray Absorption Fine Structure (EXAFS) and electrochemistry. EXAFS data unravel that the composition of pristine active material (PAM) for iron electrodes comprises 87% of magnetite and 13% of α-iron while carbon-grafted active material comprises 60% of magnetite and 40% of α-iron. In situ XRD patterns are recorded using a specially designed electrochemical cell. XRD data reflect that magnetite present in PAM iron electrode, without bismuth sulfide additive, is not reduced during charging while PAM iron electrode with bismuth sulfide additive is partially reduced to α-Fe/Fe(OH) 2 . Interestingly, carbon-grafted-iron electrodes with bismuth sulfide exhibit complete conversion of active material to α-Fe/Fe(OH) 2 . The ameliorating effect of carbon grafting is substantiated by kinetic parameters obtained from steady-state potentiostatic polarization and Tafel plots. The mechanism for iron-electrode charge -discharge reactions are discussed in the light of the potential -pH diagrams for Fe -H 2 O, S -H 2 O and FeS ads -H 2 O systems and it is surmised that carbon grafting into iron active material promotes its electrochemical utilization.

supporting

confidence: 72%

In Situ Crystallographic Probing on Ameliorating Effect of Sulfide Additives and Carbon Grafting in Iron Electrodes

Ravikumar

Rajan

Sampath

et al. 2015

“…4) and further recombination of these ions with iron hydroxide to form iron sulfide within the electrode structure. [38][39][40] The amount of iron sulfide formation is proportional to the availability of iron (II) hydroxide formed during the forward reaction. After ten cycles, there are three well-developed oxidation peaks (A 0 , observed at −0.966 V, A 1 at −0.70 V and A 2 at −0.44 V), which are related to the adsorption of hydroxide ion, 41 further oxidation of Fe to Fe(II) and Fe(II) to Fe(III) respectively.…”

Section: Resultsmentioning

confidence: 99%

Core/Shell Structure Nano-Iron/Iron Carbide Electrodes for Rechargeable Alkaline Iron Batteries

Paulraj

Kiros

Skårman

et al. 2017

In this work, we have studied a 2% copper substituted core shell type iron/iron carbide as a negative electrode for application in energy storage. The NanoFe-Fe 3 C-Cu delivered 367 mAh g −1 at ≈80% current efficiency, successfully running for over 300 cycles. The superior electrode kinetics and performance were assessed by rate capability, galvanostatic, potentiodynamic polarization measurements in 6 M KOH electrolyte and at ambient temperature. Ex-situ XRD characterizations and SEM images of both the fresh and used electrode surfaces show that nanoparticles were found to be still intact with negligible particle agglomeration. The electrodes have shown stable performances with low capacity decay, whereas sulfur dissolution from the additive Bi 2 S 3 was found to decrease the charging efficiency with time. This core-shell type structured nano material is, consequently, an auspicious anode candidate in alkaline-metal/air and Ni-Fe battery systems. Electricity generation away from fossil fuels by renewable energy resources (RER) is increasing at a remarkable pace both as a means of mitigating greenhouse gas emissions as well as offsetting the global energy demand for sustainable development. Since the end of the 1990s, the world cumulative energy generation by both wind and solar has shown an exponential growth rate. In 2015, the global installed capacity of photovoltaics was 227.1 GW an increase by 25% and the total installed wind power was 432.9 GW, a rise by 17% compared to 2014 for both energy systems.1,2 However, both wind and solar are very dependent on weather conditions and there is a high quest for electrical energy storage (EES) for integration with these renewables. The variability in energy output is due to the stochastic nature and availability of the renewable sources, unreliable demand and supply of electricity, distributed energy generation, maintenance and utilization of load balance in peak shaving and leveling, stabilization of transmission and distribution to the grid, uninterruptable power supply with frequency control, voltage fluctuations and energy arbitrage. EES is considered to be vital and indispensable technology for both utility and transport applications.1,3-7 Among EES technologies, electrochemical energy storage systems in the form of batteries have characteristic features in the form of modularity and scalability, fast response time and high energy efficiency, although they do significantly differ in energy and power densities, charge and discharge duration, cycling behavior and capital cost.There are several rechargeable (secondary) battery energy storage systems (BESS) that are widely used or are under demonstrations/development phases and these among others include; lead-acid, Li-ion, the nickel-based batteries (Ni-MH, Ni-Cd, Ni-Fe, Ni-Zn, NaNiCl 2 ), redox flow batteries (Vanadium, Zn-Br, Zn-Cl, Zn-Ce, FeCr, V-Br), NaS and Air-metal batteries (Fe-air, Zn-air, Li-air, Mgair).6-10 The last type of "batteries" are essentially a hybridization of anodes in the form of metals and a f...

“…The iron (II) sulfide is sparingly soluble in the electrolyte, allowing pressed plate electrodes to be discharged at rates as high as 3C, and sustained charge and discharge cycling for over 1000 cycles. 44,45 We found that a sintered electrode could also be prepared with iron (II) sulfide. The discharge rate capability of such a sintered electrode with iron (II) sulfide was found comparable to that of the pressed plate iron electrode containing iron sulfide.…”

Section: Resultsmentioning

confidence: 97%

“…17 Our recent efforts with a "pressed-plate" type iron electrode have led to remarkable advances in charging efficiency and rate capability, achieved through electrode re-design and re-formulation. 17,[43][44][45] Such "pressed-plate" electrodes were prepared by hot-pressing of a mixture of the carbonyl iron particles, sulfide-containing additives, a pore-forming additive and a polymeric binder. However, greater mechanical robustness is projected for a "sintered-type" iron electrode when compared to other types of electrodes.…”

mentioning

confidence: 99%

“…17,43 The role of sulfides in increasing discharge capacity and the factors affecting the cycle life of iron electrodes have also become better understood. 44,45 As a result, iron electrodes with charging efficiencies as high as 96% and with the ability to sustain discharge rates up to 3C, have now been demonstrated. This performance represents a significant improvement compared to the charging efficiency of 55-70% and the recommended discharge Journal of The Electrochemical Society, 164 (2) A418-A429 (2017) A419 rate of 0.2 C of commercial nickel-iron batteries.…”

mentioning

confidence: 99%

See 1 more Smart Citation

A High-Performance Sintered Iron Electrode for Rechargeable Alkaline Batteries to Enable Large-Scale Energy Storage

Yang

Manohar

Narayanan

2017

Self Cite

Iron-based alkaline rechargeable batteries such as iron-air and nickel-iron batteries are particularly attractive for large-scale energy storage because these batteries can be relatively inexpensive, environment-friendly, and also safe. Therefore, our study has focused on achieving the essential electrical performance and cycling properties needed for the widespread use of iron-based alkaline batteries in stationary and distributed energy storage applications. We have demonstrated for the first time, an advanced sintered iron electrode capable of 3500 cycles of repeated charge and discharge at the 1-hour rate and 100% depth of discharge in each cycle, and an average Coulombic efficiency of over 97%. Such a robust and efficient rechargeable iron electrode is also capable of continuous discharge at rates as high as 3C with no noticeable loss in utilization. We have shown that the porosity, pore size and thickness of the sintered electrode can be selected rationally to optimize specific capacity, rate capability and robustness. These advances in the electrical performance and durability of the iron electrode enables iron-based alkaline batteries to be a viable technology solution for meeting the dire need for large-scale electrical energy storage. Electrical energy storage systems will enable the seamless integration of the electricity generated from wind turbines and solar photovoltaics into the electricity grid. Rechargeable batteries are particularly good candidates for such large-scale energy storage because of their high round-trip efficiency, inherent scalability, and flexibility for being located almost anywhere.1-6 Batteries such as vanadiumredox, lead-acid and lithium-ion are under consideration for this application because of their commercial availability. Yet, the widespread deployment of these battery systems is limited by their materials cost, lifetime, safety concerns, and the high cost of delivered energy. 7,8Rechargeable iron-based alkaline batteries such as nickel-iron and iron-air have unique advantages that make them particularly attractive for meeting the emerging demands of grid-scale electrical energy storage systems.6,9-12 Iron, the primary raw material for these battery systems, is globally abundant, relatively inexpensive, eco-friendly and is recycled readily. Thus, iron is particularly attractive as a raw material for batteries required at such a large scale.6 Iron-based batteries such as the nickel-iron battery are historically well known for their extraordinary robustness to thousands of cycles of charge and discharge, and tolerance to overcharge and over-discharge. [13][14][15][16] Such robustness is generally uncommon among rechargeable batteries; other types of batteries in use today degrade in about 1000 cycles.17 For example, lead-acid batteries typically offer 500-800 cycles, and lithium-ion batteries usually last no more than 1000 cycles especially when subjected to deep discharge.18 Despite these striking attributes of iron-based batteries, the large-scale use of these batteries ...