Electrochemical reversibility of magnesium deposition-dissolution on aluminum substrates in Grignard reagent/THF solutions

Abstract: The electrochemical behavior of magnesium deposition-dissolution on scratched aluminum foils in Grignard reagent/tetrahydrofuran (THF) solutions (1 mol L 1 EtMgBr/THF), which is regarded as a potential electrolyte of rechargeable magnesium batteries, was studied by using various methods such as cyclic voltammetry (CV), scanning electron microscopy (SEM), X-ray diffraction (XRD) and charge-discharge (deposition-dissolution) tests. The results present that the obtained magnesium deposits do not exhibit the morp… Show more

“…43,46,48 Furthermore, the difference in the morphology between dendritic Mg and dendritic Li results from the low diffusion energy and high adsorption energy of the Mg atom, as shown by the DFT calculation results. [41][42][43]45 Our group observed by operando X-ray imaging (Figure 4a) that spherical deposits are formed at 2 mA/cm 2 , but branched dendritic Mg are formed at 10 mA/cm 2 in PhMgCl in THF electrolyte. 45 Interestingly, unlike dendritic Li, the dead Mg formation during the stripping process is not mentioned.…”

“…The polyhedral Mg deposits are also reported in the presence of Grignard reagent electrolyte, which consist of crystalline Mg (Figure 3b). 43 Similarly, in Mg(TFSI) 2 electrolytes, small 3D crystalline structured Mg is formed during deposition. 37 In Mg(TFSI) 2 in glyme/diglyme 1:1 volume ratio electrolyte, the scanning electron microscopy (SEM) image (Figure 3c) shows agglomerated Mg particles consisting of 50 nm hemispherical crystals at high current density (3.25 mA/cm 2 ).…”

“…25,26 The morphology of Mg deposits shows hemispherical or grape-like structure, which is distinct from that of the needle-like Li dendrites, and this set the ground for Mg as nondendritic metal anodes. 43,44 A strong, insoluble native oxide layer of Al requires unique ionic liquid electrolytes for the Al metal anode, which makes the reaction mechanism different from those of other metal anodes, as AlCl 4 − is the main charge transfer agent. 55 The pebble-like morphology of dendritic Al results from the Al 2 O 3 layer and sluggish AlCl 4 − reaction.…”

On the Road to Stable Electrochemical Metal Deposition in Multivalent Batteries

“…43,46,48 Furthermore, the difference in the morphology between dendritic Mg and dendritic Li results from the low diffusion energy and high adsorption energy of the Mg atom, as shown by the DFT calculation results. [41][42][43]45 Our group observed by operando X-ray imaging (Figure 4a) that spherical deposits are formed at 2 mA/cm 2 , but branched dendritic Mg are formed at 10 mA/cm 2 in PhMgCl in THF electrolyte. 45 Interestingly, unlike dendritic Li, the dead Mg formation during the stripping process is not mentioned.…”

“…The polyhedral Mg deposits are also reported in the presence of Grignard reagent electrolyte, which consist of crystalline Mg (Figure 3b). 43 Similarly, in Mg(TFSI) 2 electrolytes, small 3D crystalline structured Mg is formed during deposition. 37 In Mg(TFSI) 2 in glyme/diglyme 1:1 volume ratio electrolyte, the scanning electron microscopy (SEM) image (Figure 3c) shows agglomerated Mg particles consisting of 50 nm hemispherical crystals at high current density (3.25 mA/cm 2 ).…”

“…25,26 The morphology of Mg deposits shows hemispherical or grape-like structure, which is distinct from that of the needle-like Li dendrites, and this set the ground for Mg as nondendritic metal anodes. 43,44 A strong, insoluble native oxide layer of Al requires unique ionic liquid electrolytes for the Al metal anode, which makes the reaction mechanism different from those of other metal anodes, as AlCl 4 − is the main charge transfer agent. 55 The pebble-like morphology of dendritic Al results from the Al 2 O 3 layer and sluggish AlCl 4 − reaction.…”

On the Road to Stable Electrochemical Metal Deposition in Multivalent Batteries

“…Ethereal solutions of RMgX, Mg(AlCl 3 R) 2 , and Mg(AlCl 2 RR′) 2 (R and R′ = alkyl or allyl groups) are widely used because they enable a stable Mg metal deposition/dissolution behavior. 2,5,7 In addition, magnesium-aluminum chloride complexes provide a wide electrochemical window within the anodic limit of Mg deposition-dissolution. 8 The Mg source Mg[TFSA] 2 (TFSA = bis(trifluoromethylsulfonyl)amide) readily dissolves in polar solvents and its Mg 2+ ions have a high affinity to σ-donor ligands.…”

Homoleptic octahedral coordination of CH₃CN to Mg²⁺ in the Mg[N(SO₂CF₃)₂]₂–CH₃CN system

“…This was the first demonstration of a family of Mg-electrolytes. The Aurbach group proposed a series of organometallic electrolytes by combining a Lewis acid and a Lewis base, with close to 100% Coulombic efficiency. − They demonstrated reversible Mg-intercalation in the Chevrel phase cathode, Mo 6 S 8 . Another prominent organohaloaluminate-based electrolyte is the all-phenyl complex or APC, formed by the reaction of PhMgCl with AlCl 3 in tetrahydrofuran (THF) .…”

Efficient Magnesium Plating and Stripping in DOL/DME-Mg(HMDS)₂-Based Electrolytes and Application in Mg/S Batteries