Determination of 14 Impurity Elements in Lithium Carbonate Using ICP-OES
Applications | 2020 | Agilent TechnologiesInstrumentation
Lithium ion batteries are a foundational technology for renewable energy storage and electric vehicles. The purity of lithium carbonate feedstock strongly influences battery performance, durability, and manufacturing cost. Reliable impurity analysis supports raw material qualification and ensures consistent battery quality.
This study presents a streamlined ICP OES method using the Agilent 5110 VDV instrument and a multi element standard addition approach to quantify 14 impurities in lithium carbonate. The goal is to achieve accurate detection of alkaline, transition and metalloid elements including silicon in a single analysis with high throughput.
A 0.3 g sample of lithium carbonate is acid digested with nitric acid, diluted to 30 mL, and used both for analysis and matrix blanks. Multi standard addition calibration is employed to match matrix effects and enable axial measurement of alkali elements. Calibration range covers 0.005 to 0.1 mg/L for most elements. Background correction is automated by fitted background correction algorithms.
- Agilent 5110 Vertical Dual View ICP OES with vertical torch configuration
- SeaSpray concentric glass nebulizer and double pass cyclonic spray chamber
- Easy fit demountable dual view torch with 1.8 mm inner injector
- Solid state radio frequency generator at 27 MHz for stable plasma
- VistaChip III CCD detector for full wavelength read in a single exposure
- Cooled cone interface to reduce easily ionized element interferences
Method detection limits for all 14 elements are below 1 µg/L, enabling low level monitoring. Calibration linearity is excellent with correlation coefficients above 0.9995. Spike recoveries at 50 µg/L fall between 95 and 102 percent. A 2.5 hour stability test shows relative standard deviations under 2 percent for all analytes, demonstrating method precision and robustness.
- Single run analysis of major, minor and trace impurities including silicon simplifies workflow
- High throughput with 60 second analysis time reduces argon consumption and energy use
- Standard addition corrects matrix effects and minimizes dilution errors
- Reliable quality control tool for battery grade lithium carbonate in production and research settings
The method can be extended to other battery materials such as lithium hydroxide and cathode precursors. Integration with automation and online sampling could further increase throughput. Advances in detector technology and data processing may lower detection limits and enable comprehensive impurity profiling. Coupling with speciation techniques could provide additional insight into impurity states.
The Agilent 5110 VDV ICP OES combined with standard addition calibration offers a fast, accurate and robust solution for quantifying 14 impurity elements in lithium carbonate. The method meets stringent quality control requirements and supports the manufacturing of high performance lithium ion batteries.
ICP-OES
IndustriesEnvironmental
ManufacturerAgilent Technologies
Summary
Significance of the topic
Lithium ion batteries are a foundational technology for renewable energy storage and electric vehicles. The purity of lithium carbonate feedstock strongly influences battery performance, durability, and manufacturing cost. Reliable impurity analysis supports raw material qualification and ensures consistent battery quality.
Objectives and study overview
This study presents a streamlined ICP OES method using the Agilent 5110 VDV instrument and a multi element standard addition approach to quantify 14 impurities in lithium carbonate. The goal is to achieve accurate detection of alkaline, transition and metalloid elements including silicon in a single analysis with high throughput.
Methodology and instrumentation
A 0.3 g sample of lithium carbonate is acid digested with nitric acid, diluted to 30 mL, and used both for analysis and matrix blanks. Multi standard addition calibration is employed to match matrix effects and enable axial measurement of alkali elements. Calibration range covers 0.005 to 0.1 mg/L for most elements. Background correction is automated by fitted background correction algorithms.
Instrumentation
- Agilent 5110 Vertical Dual View ICP OES with vertical torch configuration
- SeaSpray concentric glass nebulizer and double pass cyclonic spray chamber
- Easy fit demountable dual view torch with 1.8 mm inner injector
- Solid state radio frequency generator at 27 MHz for stable plasma
- VistaChip III CCD detector for full wavelength read in a single exposure
- Cooled cone interface to reduce easily ionized element interferences
Main results and discussion
Method detection limits for all 14 elements are below 1 µg/L, enabling low level monitoring. Calibration linearity is excellent with correlation coefficients above 0.9995. Spike recoveries at 50 µg/L fall between 95 and 102 percent. A 2.5 hour stability test shows relative standard deviations under 2 percent for all analytes, demonstrating method precision and robustness.
Benefits and practical applications of the method
- Single run analysis of major, minor and trace impurities including silicon simplifies workflow
- High throughput with 60 second analysis time reduces argon consumption and energy use
- Standard addition corrects matrix effects and minimizes dilution errors
- Reliable quality control tool for battery grade lithium carbonate in production and research settings
Future trends and opportunities
The method can be extended to other battery materials such as lithium hydroxide and cathode precursors. Integration with automation and online sampling could further increase throughput. Advances in detector technology and data processing may lower detection limits and enable comprehensive impurity profiling. Coupling with speciation techniques could provide additional insight into impurity states.
Conclusion
The Agilent 5110 VDV ICP OES combined with standard addition calibration offers a fast, accurate and robust solution for quantifying 14 impurity elements in lithium carbonate. The method meets stringent quality control requirements and supports the manufacturing of high performance lithium ion batteries.
References
- Agilent Technologies Application Note Determination of Elemental Impurities in Graphite based Anodes using the Agilent 5110 ICP OES 5991 9508EN
- Agilent Technologies Application Note Determination of Elements in Ternary Nickel Cobalt Manganese Hydride 5991 9506EN
- Agilent Technologies Application Note Rapid Analysis of Elemental Impurities in Battery Electrolyte by ICP OES 5994 1937EN
- IEC 62321 2008 Electrotechnical products Determination of levels of six regulated substances
- GB T 11064.16 2013 Methods for chemical analysis of lithium carbonate lithium hydroxide monohydrate and lithium chloride Part 16 Inductively coupled plasma atomic emission spectrometry
- Agilent Technologies Application Note Fitted Background Correction FBC fast accurate and fully automated background correction 5991 4836EN
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