The long service life of batteries is one of the most desired parameters for the battery industry and end-users.Several doping elements have been proposed to increase discharge capacity, capacity retention, and rate capabilityof high voltage LiNi0.5Mn1.5O4 (LNMO) cathode. In this study, two different doping elements, i.e., boron(III) and vanadium (IV), are compared to investigate the doping effect on capacity retention of LNMO-electrodesat high temperatures (50 C) and extended cycle performance. Different doping amounts are investigated forcomparison, i.e., 1, 3, 5, 7, 10 wt% for boron and 10 wt% for vanadium. The actual benefit of doping is observedover extended cycle tests (> 1000 cycles) at 50 C and 1C. While pristine LNMO electrodes fail after 80 cycles,10% B-doped LNMO exhibits the highest capacity retention, 80% at 50 C and 1C after 1200 cycles. The operandodifferential electrochemical mass spectroscopy results reveal that LNMO electrodes show the highest amount ofgas emission (H2 and O2) at ~ 4.7 V, where the oxidation of Ni4þ/3þ and Ni3þ/2þ occurs. Since high amountdoping strategy increases Mn3þ amount and, consequently, the charge voltage plateau at ~4 V (Mn3þ/Mn4þ), thisimplicitly prevents electrolyte decomposition at high voltage due to decreasing of nickel voltage plateau and lesscharging step duration at ~ 4.7 V. This investigation shows that the cathode life remarkably can be extended byreducing the nickel content with high amount of doping.

Effect of doping amount on capacity retention and electrolyte decomposition of LiNi0.5Mn1.5O4-based cathode at high temperature

Francesca De Giorgio;
2022

Abstract

The long service life of batteries is one of the most desired parameters for the battery industry and end-users.Several doping elements have been proposed to increase discharge capacity, capacity retention, and rate capabilityof high voltage LiNi0.5Mn1.5O4 (LNMO) cathode. In this study, two different doping elements, i.e., boron(III) and vanadium (IV), are compared to investigate the doping effect on capacity retention of LNMO-electrodesat high temperatures (50 C) and extended cycle performance. Different doping amounts are investigated forcomparison, i.e., 1, 3, 5, 7, 10 wt% for boron and 10 wt% for vanadium. The actual benefit of doping is observedover extended cycle tests (> 1000 cycles) at 50 C and 1C. While pristine LNMO electrodes fail after 80 cycles,10% B-doped LNMO exhibits the highest capacity retention, 80% at 50 C and 1C after 1200 cycles. The operandodifferential electrochemical mass spectroscopy results reveal that LNMO electrodes show the highest amount ofgas emission (H2 and O2) at ~ 4.7 V, where the oxidation of Ni4þ/3þ and Ni3þ/2þ occurs. Since high amountdoping strategy increases Mn3þ amount and, consequently, the charge voltage plateau at ~4 V (Mn3þ/Mn4þ), thisimplicitly prevents electrolyte decomposition at high voltage due to decreasing of nickel voltage plateau and lesscharging step duration at ~ 4.7 V. This investigation shows that the cathode life remarkably can be extended byreducing the nickel content with high amount of doping.
2022
Istituto per lo Studio dei Materiali Nanostrutturati - ISMN
High voltage spinel
LNMO
Boron doping
Vanadium doping
Operando differential electrochemical mass spectroscopy (DEMS)
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/440908
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