In Situ Probing Potassium-ion Intercalation-induced Amorphization in Crystalline Iron Phosphate Cathode Materials

Abstract: <p>Na-ion and K-ion batteries are promising alternatives for large-scale energy storage applications due to their abundancy and lower cost. However, designing an electrode structure to reversibly accommodate these large alkali-ions is the remaining challenge before their commercialization. Intercalation of these large ions could cause irreversible structural deformations and amorphization in the crystalline electrodes. The designing of new amorphous electrodes is another route to develop electrodes to s… Show more

“…Composite electrodes were prepared by mixing pristine lithium iron phosphate (LiFePO 4 , LFP, Hanwha Chemical) with sodium carboxymethyl cellulose (binder, CMC, Aldrich) and conductive additive (carbon black, Alfa Aesar) in 8:1:1 mass ratio. Iron phosphate (FePO 4 , FP) composite electrode was formed by electrochemical displacement technique using a pristine LFP composite electrode [21][22][23][24] via galvanostatic cycle at a rate of C/ the composite electrode were used as a speckle pattern suitable for the calculations of displacement fields and their resultant strain distribution on the electrode surface.…”

“…[26] A recent in situ XRD study also demonstrated the amorphization of the crystalline iron phosphate during the intercalation of K ions. [21] The corresponding electrochemical strains in the electrodes upon Li, Na, and K intercalation are shown in respectively. K ions were only able to intercalate into electrode structure up to an SOD of ca.…”

“…XRD studies on K ion intercalation into iron phosphate demonstrated amorphization in the crystalline structure. [19,21] Therefore, progressive evolution of the strain rates in the electrodes is likely due to the occurrence of plastic deformation in the electrode structure. Constant strain rates during Li and Na intercalation can be interpreted as preserving crystalline structure while removing these ions from the host structure.…”

“…Recently, we developed a new experimental approach to monitor dynamic physical and structural changes in the amorphous phase of the electrodes by combining in situ strain measurements via digital image correlation (DIC) and in-operando XRD techniques. [21] The study detected the redox chemistry and the associated electrochemical strains in the amorphous phases of the iron phosphate electrode during K ion intercalation. [21] In this work, we compare the operando physical and electrochemical responses of the host cathode electrode upon intercalation of Li, Na, and K ions using DIC and electrochemical methods.…”

“…[21] The study detected the redox chemistry and the associated electrochemical strains in the amorphous phases of the iron phosphate electrode during K ion intercalation. [21] In this work, we compare the operando physical and electrochemical responses of the host cathode electrode upon intercalation of Li, Na, and K ions using DIC and electrochemical methods. Iron phosphate was selected as a model system because it allows intercalation of Li, Na, and K ions.…”

The impact of alkali‐ion intercalation on redox chemistry and mechanical deformations: Case study on intercalation of Li, Na, and K ions into FePO₄ cathode

“…Composite electrodes were prepared by mixing pristine lithium iron phosphate (LiFePO 4 , LFP, Hanwha Chemical) with sodium carboxymethyl cellulose (binder, CMC, Aldrich) and conductive additive (carbon black, Alfa Aesar) in 8:1:1 mass ratio. Iron phosphate (FePO 4 , FP) composite electrode was formed by electrochemical displacement technique using a pristine LFP composite electrode [21][22][23][24] via galvanostatic cycle at a rate of C/ the composite electrode were used as a speckle pattern suitable for the calculations of displacement fields and their resultant strain distribution on the electrode surface.…”

“…[26] A recent in situ XRD study also demonstrated the amorphization of the crystalline iron phosphate during the intercalation of K ions. [21] The corresponding electrochemical strains in the electrodes upon Li, Na, and K intercalation are shown in respectively. K ions were only able to intercalate into electrode structure up to an SOD of ca.…”

“…XRD studies on K ion intercalation into iron phosphate demonstrated amorphization in the crystalline structure. [19,21] Therefore, progressive evolution of the strain rates in the electrodes is likely due to the occurrence of plastic deformation in the electrode structure. Constant strain rates during Li and Na intercalation can be interpreted as preserving crystalline structure while removing these ions from the host structure.…”

“…Recently, we developed a new experimental approach to monitor dynamic physical and structural changes in the amorphous phase of the electrodes by combining in situ strain measurements via digital image correlation (DIC) and in-operando XRD techniques. [21] The study detected the redox chemistry and the associated electrochemical strains in the amorphous phases of the iron phosphate electrode during K ion intercalation. [21] In this work, we compare the operando physical and electrochemical responses of the host cathode electrode upon intercalation of Li, Na, and K ions using DIC and electrochemical methods.…”

“…[21] The study detected the redox chemistry and the associated electrochemical strains in the amorphous phases of the iron phosphate electrode during K ion intercalation. [21] In this work, we compare the operando physical and electrochemical responses of the host cathode electrode upon intercalation of Li, Na, and K ions using DIC and electrochemical methods. Iron phosphate was selected as a model system because it allows intercalation of Li, Na, and K ions.…”

The impact of alkali‐ion intercalation on redox chemistry and mechanical deformations: Case study on intercalation of Li, Na, and K ions into FePO₄ cathode