VIDEO
HIGHLIGHT
Log InSign up
What Makes XPS So Powerful? The Science Behind Its Superiority!
SummaryTranscriptChat

What Makes XPS So Powerful? The Science Behind Its Superiority!

XPS: Advantages and Techniques

Key Advantages of X-ray Photoelectron Spectroscopy (XPS)

  • XPS has two main advantages over similar techniques:
  • Surface Sensitivity: It detects elements only in a very thin region, enhancing the accuracy of surface analysis.
  • Chemical Environment Differentiation: It can distinguish how carbon bonds with other elements, revealing detailed chemical environments.

Elemental Identification and Chemical Environment

  • Elemental identification is achieved through survey spectra, which help identify existing elements.
  • High-resolution XP spectra focus on specific peaks to analyze chemical environments, such as chlorine bonding characteristics.

Understanding Surface Sensitivity

  • The photoelectrons generated during XPS are affected by inelastic collisions:
  • In deeper regions (beyond 10 nm), electrons lose energy and contribute to background noise rather than useful signals.
  • In the topmost layer (around 10 nm), photoelectrons maintain their energy and form distinct peaks for analysis.

Comparison with Other Techniques

  • Ultraviolet Photoelectron Spectroscopy (UPS):
  • Extremely surface-sensitive but only detects elements within a thickness of about 2 nm.
  • Energy Dispersive X-ray Spectroscopy (EDX):
  • Coupled with scanning electron microscopy for qualitative and quantitative elemental analysis.

Insights into Chemical Environments

  • XPS reveals binding energies that indicate different bonding situations:
  • Carbon bonded to carbon vs. carbon bonded to oxygen shows variations in binding energy due to electronegativity differences.
  • The technique provides insights into neighboring elements affecting oxidation states and overall binding energies.

Binding Energy Variations

  • Changes in neighboring atoms influence binding energies significantly; this is crucial for understanding material properties.
  • High-resolution spectra allow for the detection of minor variations in binding energy that standard survey spectra cannot reveal.
  • For example, titanium compounds exhibit different binding energies based on their oxidation states, which can be distinguished using high-resolution techniques.
Playlists: XPS - X-rays Photoelectron Spectroscopy
Video description

Two main advantages of X-rays Photoelectrons Spectroscopy There are two advantages over other similar characterization techniques, like UPS and EDX 1- Surface sensitivity (∼10 nm) - elemental composition 2- Its ability to distinguish in Chemical Environment Let's discuss each one in detail: XPS is a surface sensitive technique: XPS only detects elements at a very thin region ~10 nm. In fact, x-rays (Al Kα~1486.6 eV and Mg Kα line ~1253.6 eV) can penetrate to a micro meter thick region however, the photoelectrons lost its energy completely owing to inelastic scattering and can not reached the XPS detector. Just below the 10 nm region, the photoelectron may encounter a few inelastic scattering and reach to the XPS detector, but they only contribute to the background of the XPS peaks. The photoelectrons escaped only from the ~10 nm will reach the XPS detector and give rise to XPS photoelectrons and Auger electron Peaks. In XPS, the elemental identification can be achieved by running a survey spectra. XPS also reveal about the chemical environment: The chemical environment includes factors like the nearest neighbour elements and oxidation state of the elements, which affects the Binding energy (BE)of the Auger electrons and Photoelectrons Peaks. For example, the BE of a carbon atom in a C=O bond will be different from that in the C-H bond. This small variation in BE is NOT possible with SURVEY Spectra. Therefore, we have to run the High Resolution Spectra. For instance, it is observed that the BE for C 1s increases significantly when the bonded oxygen atoms increases i.e., the BE for O-C=O is greater than C =O and C-O, it is because oxygen is more electronegative than carbon and will be attracting more electrons away from carbon. This way, the carbon atom should become more positively charged, resulting in an enhance BE for C 1s. Similarly, the chemical state of Ti, TiO, and TiO2 with oxidation state Ti (0), Ti(II), and Ti(III), respectively showing different BE their different oxidation states and chemical environment. This variation in the BE can ONLY be possible and can be accomplished by running High Resolution XPS spectra. Please subscribe to my channel and share it. Best,