From kröhnkite- to alluaudite-type of structure: novel method of synthesis of sodium manganese sulfates with electrochemical properties in alkali-metal ion batteries

Marinova, D.; Kostov, V; Nikolova, Rositsa; Kukeva, Rositsa; Zhecheva, E.; Sendova-Vasileva, M.; Stoyanova, Р.

doi:10.1039/c5ta07204b

Cited by 42 publications

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References 34 publications

(117 reference statements)

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a Recently, several excellent SO4-based polyanion cathodes for Na-ion batteries (NIBs) were exploited, e.g. 29 To search for more excellent SO 4 -based insertion materials for NIBs, We studied the Na 2 SO 4 -MnSO 4 system and isolated another new compound Na 2 Mn 3 (SO 4 ) 4 . To search for more excellent SO4-based materials for NIBs, we studied the Na2SO4-MnSO4 system and isolated a new compound Na2Mn3(SO4)4, which crystallizes in orthorhombic space group Cmc21 with a=14.8307(18) Å, b=9.9107(18)Å, c = 8.6845(12)Å, and Z=4.

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Preparation, structure and properties of Na₂Mn₃(SO₄)₄: a new potential candidate with high voltage for Na-ion batteries

et al. 2016

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a Recently, several excellent SO4-based polyanion cathodes for Na-ion batteries (NIBs) were exploited, e.g. Na2+2xM2-x(SO4)3 (M=Fe and Mn), which can make the NIBs competitive with the state-of-the-art Li-ion batteries (LIBs). To search for more excellent SO4-based materials for NIBs, we studied the Na2SO4-MnSO4 system and isolated a new compound Na2Mn3(SO4)4, which crystallizes in orthorhombic space group Cmc21 with a=14.8307(18) Å, b=9.9107(18)Å, c = 8.6845(12)Å, and Z=4. The structure has the tunnels for migration of Na + ions, which can be confirmed by the BVS maps. The impedance studies further demonstrated the mobility of Na + ions. A high redox potential with the value of 4.48V was obtained using the density functional theory (DFT) method based on the ab initio calculations. Additionally, magnetic test, infrared spectra (IR), and differential scanning calorimeter (DSC) were also employed for the characterization of the material. 28 Almost at the same time, Marinova et al also reported that Na 2+σ Mn 2-σ/2 (SO 4 ) 3 has electrochemical activity in the lithium ions cell. 29 To search for more excellent SO 4 -based insertion materials for NIBs, We studied the Na 2 SO 4 -MnSO 4 system and isolated another new compound Na 2 Mn 3 (SO 4 ) 4 . Herein, we report the synthesis (containing crystal growth), structure, magnetic properties and conductivity of the title compound. In addition, we also calculated the Na + ions diffusional pathway and the redox potential.

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Preparation, structure and properties of Na₂Mn₃(SO₄)₄: a new potential candidate with high voltage for Na-ion batteries

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“…The observed small hyperfine interactions of 23 Na ions can serve as direct evidence for the unpaired spin observed by pulsed EPR on the terephthalic molecule . In addition, Marinova et al prepared well‐crystallized alluaudite‐type Na 2+δ Mn 2−δ/2 (SO 4 ) 3 by simple dehydration of the kröhnkite‐type Na 2 Mn(SO 4 ) 3 ·2H 2 O, and the thermal dehydration process was interpreted from manganese coordination by in situ EPR spectroscopy from 290 to 380 K . The EPR spectrum undergoes a strong change at a temperature of 380 K (107 °C), which is a convolution of two overlapping signals with Lorentzian shape shown in Figure c–e.…”

Section: Novel Methods For Sodium‐ion Battery Materialsmentioning

confidence: 99%

“…Although the second signal can also be associated with Mn 2+ ions, they have completely different coordination relative to Mn 2+ in the kröhnkite phase. With the increase of temperature above 450 K, a further change of the EPR spectrum occurs with a water molecule being released, leading to a structural transformation into Na 2 Mn(SO 4 ) 2 , which has been further determined by the XRD patterns …”

Section: Novel Methods For Sodium‐ion Battery Materialsmentioning

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Novel Methods for Sodium‐Ion Battery Materials

Zhao

et al. 2017

Small Methods

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Sodium‐ion batteries (NIBs) as an ideal candidate for large‐scale energy‐storage systems (ESSs) have been the subject of extensive attention worldwide as a result of the ever‐growing energy demands. Development of advanced NIB techniques with potentially higher performance is of great concern to meet the requirements of ESSs. Based on modern material characterization methods and technological optimizations, the systematic understanding of rechargeable batteries has been further developed. Novel methods for NIB materials could provide a rational guideline for the fundamental understanding and practical optimization of battery systems. Here, the focus is mainly on a discussion of novel or fresh experimental methods and characterization techniques for NIB materials from the relationships between properties and performances, which are roughly classified into four parts: structure‐related techniques, composition‐related techniques, size‐ and morphology‐related techniques, and surface‐ and interface‐related techniques. Respective detection mechanisms of each method will be discussed, and special attention is paid to examples of these characterization techniques for NIB devices. It is hoped that by the study of NIB‐related details, a certain reference to the development of advanced materials can be provided.

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“…Furthermore, the thermal treatment of the kröhnkite-phase at 227 C, led to the formation of an alluaudite-phase with the composition Na 2+g -Mn 1Àg/2 (SO 4 ) 3 . 20 A similar phase could also be prepared via a solid state synthesis route when a mixture of Na 2 SO 4 and MnSO 4 was Although, the ve phases were prepared from the same precursors, their crystal structures are different (Fig. 7).…”

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Structural and thermal properties of Na₂Mn(SO₄)₂·4H₂O and Na₂Ni(SO₄)₂·10H₂O

2020

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From kröhnkite- to alluaudite-type of structure: novel method of synthesis of sodium manganese sulfates with electrochemical properties in alkali-metal ion batteries

Cited by 42 publications

References 34 publications

Preparation, structure and properties of Na₂Mn₃(SO₄)₄: a new potential candidate with high voltage for Na-ion batteries

Preparation, structure and properties of Na₂Mn₃(SO₄)₄: a new potential candidate with high voltage for Na-ion batteries

Novel Methods for Sodium‐Ion Battery Materials

Structural and thermal properties of Na₂Mn(SO₄)₂·4H₂O and Na₂Ni(SO₄)₂·10H₂O

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From kröhnkite- to alluaudite-type of structure: novel method of synthesis of sodium manganese sulfates with electrochemical properties in alkali-metal ion batteries

Cited by 42 publications

References 34 publications

Preparation, structure and properties of Na2Mn3(SO4)4: a new potential candidate with high voltage for Na-ion batteries

Preparation, structure and properties of Na2Mn3(SO4)4: a new potential candidate with high voltage for Na-ion batteries

Novel Methods for Sodium‐Ion Battery Materials

Structural and thermal properties of Na2Mn(SO4)2·4H2O and Na2Ni(SO4)2·10H2O

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Preparation, structure and properties of Na₂Mn₃(SO₄)₄: a new potential candidate with high voltage for Na-ion batteries

Preparation, structure and properties of Na₂Mn₃(SO₄)₄: a new potential candidate with high voltage for Na-ion batteries

Structural and thermal properties of Na₂Mn(SO₄)₂·4H₂O and Na₂Ni(SO₄)₂·10H₂O