Add to ORKGCarbonate-based electrolytes in Li-ion batteries exhibit long range order in a frozen state, which enables their non-destructive analysis by diffraction methods. In the current study the spatial distribution of lithium and electrolyte inside the graphite anode was determined in cycled Li-ion cells using monochromatic spatially-resolved neutron diffraction measurements at 150 K. The results indicate a loss of lithium and electrolyte and their non-uniform distribution in the graphite anode in aged Li-ion cells. The observed lithium and electrolyte losses are directly correlated with two electrochemical performance degradation mechanisms, which are responsible for the cell capacity fade
Although the growth of the solid electrolyte interphase is considered one of the most important degr...
Ex situ and time-resolved in operando neutron powder diffraction (NPD) has been used to study the st...
Commercial 18650 lithium ion cells containing a blended positive electrode of layered LiNi 0.5 Mn 0....
Spatially-resolved neutron powder diffraction with a gauge volume of 2 × 2 × 20 mm$^{3}$ has been ap...
The two‐dimensional lithium distribution in the graphite anode was non‐destructively probed by spati...
Integrity and uniformity are crucial factors for stable, safe, robust and well-predicted operation o...
The structural response to electrochemical cycling of the components within a commercial Li-ion batt...
We report an in-situ neutron diffraction study of a large format pouch battery cell. The succession ...
The distribution of lithium inside electrodes of a commercial Li-ion battery of 18650-type with LiFe...
We demonstrate the lithiation process in graphitic anodes using in situ neutron radiography and diff...
A combination of high-resolution neutron powder diffraction, energy-dependent cold-neutron radiograp...
Anode and cathode materials, graphite and LiCoO2, are studied by neutron diffraction under “in opera...
Spatially-resolved neutron diffraction has been applied to probe the lithium distribution in radial ...
Since their commercialization in 1991, lithium-ion batteries (LIBs) have revolutionized our way of l...
Neutron diffraction is a powerful technique to localize and quantify lithium in battery electrode ma...
Although the growth of the solid electrolyte interphase is considered one of the most important degr...
Ex situ and time-resolved in operando neutron powder diffraction (NPD) has been used to study the st...
Commercial 18650 lithium ion cells containing a blended positive electrode of layered LiNi 0.5 Mn 0....
Spatially-resolved neutron powder diffraction with a gauge volume of 2 × 2 × 20 mm$^{3}$ has been ap...
The two‐dimensional lithium distribution in the graphite anode was non‐destructively probed by spati...
Integrity and uniformity are crucial factors for stable, safe, robust and well-predicted operation o...
The structural response to electrochemical cycling of the components within a commercial Li-ion batt...
We report an in-situ neutron diffraction study of a large format pouch battery cell. The succession ...
The distribution of lithium inside electrodes of a commercial Li-ion battery of 18650-type with LiFe...
We demonstrate the lithiation process in graphitic anodes using in situ neutron radiography and diff...
A combination of high-resolution neutron powder diffraction, energy-dependent cold-neutron radiograp...
Anode and cathode materials, graphite and LiCoO2, are studied by neutron diffraction under “in opera...
Spatially-resolved neutron diffraction has been applied to probe the lithium distribution in radial ...
Since their commercialization in 1991, lithium-ion batteries (LIBs) have revolutionized our way of l...
Neutron diffraction is a powerful technique to localize and quantify lithium in battery electrode ma...
Although the growth of the solid electrolyte interphase is considered one of the most important degr...
Ex situ and time-resolved in operando neutron powder diffraction (NPD) has been used to study the st...
Commercial 18650 lithium ion cells containing a blended positive electrode of layered LiNi 0.5 Mn 0....