XPS Basics: Understanding Binding Energy (BE) in X-ray Photoelectron Spectroscopy

Name: XPS Basics: Understanding Binding Energy (BE) in X-ray Photoelectron Spectroscopy
Uploaded: 2024-07-16T06:56:21.000Z
Duration: 12 min 26 s

Understanding Binding Energy in X-ray Photoelectron Spectroscopy (XPS)

Introduction to Binding Energy

Binding energy is a crucial concept in X-ray Photoelectron Spectroscopy (XPS), indicating how tightly electrons are bound to the nucleus.

The binding energy varies between different atoms; for example, Titania has a higher binding energy than oxygen due to its greater number of protons influencing electron attraction.

Importance of Binding Energy in XPS Analysis

Binding energy helps determine elemental composition and chemical environments within samples, revealing interactions between atoms.

In an XPS spectrum, binding energy is plotted on the x-axis (ranging from 0 to 1400 eV), while the y-axis represents the number of electrons counted per second.

Core Electrons and Their Influence

Core electrons are more tightly bound to the nucleus compared to valence electrons, resulting in higher binding energies due to stronger nuclear attraction.

The difference in binding energies allows for identification of elements present in a sample by comparing measured values against known binding energy tables.

Comparative Analysis of Elements

For instance, comparing Titania (22 protons) with oxygen (8 protons), it is evident that Titania's core electrons exhibit significantly higher binding energies.

This comparison highlights how atomic size and proton count influence electron binding strength.

Mechanism of Electron Ejection in XPS

Higher binding energy indicates stronger nuclear attraction; thus, removing an electron requires more energy.

The XPS spectrum shows that as one moves from left to right on the graph, binding energies increase.

Ionization Process and Measurement

The process involves shining X-rays on a sample, causing ionization where core electrons are ejected based on their respective binding energies.

The difference between initial and post-ionization energies defines the concept of binding energy within this context.

This structured overview provides insights into key concepts surrounding binding energy as it relates to X-ray Photoelectron Spectroscopy. Each point links back to specific timestamps for further exploration.

Playlists: XPS - X-rays Photoelectron Spectroscopy

Video description

What is Binding Energy (BE) in X-rays Photoelectron Spectroscopy (XPS)? BE generally refers to "how tightly the electron is attached to the nucleus". Let's take oxygen atom and lead (Pb) atom, the 1s electrons of Pb are MORE tightly bound to the nucleus as compared to the 1selectrons of oxygen atom. This means that the BE for 1s electrons in the case Pb is very high as compared to oxygen 1 s electrons. Another way to explain it is to consider oxygen atom, which has electronic configuration 1s²2s²2p⁴. The 1s² electrons have very high BE as compared to the 2s² & 2p⁴ electrons because 1s² electrons are closely bound to the nucleus and more energy is required to remove these electrons as compared to the 2s² & 2p⁴ electrons In XPS, BE is a crucial concept used to identify the elemental composition & their chemical environment. What is elemental composition? It means what types of elements exist in the sample, like Cu, Zn, O, C, Ti, Pb,........ What is the chemical environment? It means that how the atoms are making bonds with neighboring atoms, whether the atom loses or gains electrons, the change in the oxidation state .... all these effects refer to the chemical environment. BE in the context of XPS is the energy required to remove an electron from the atom and move it to the Fermi level (in the case of metals) or to the vacuum level (in the case of insulators or semiconductors). BE may be regarded as the difference in energy between the initial state of an atom and the final states of ion after the photoionization (when photoelectron has left the atom). I hope the BE concept is generally clear and also for XPS analysis. XPS - X-rays Photoelectron Spectroscopy || Surface vs. Ultra thin film vs. Thin film https://youtu.be/3slRII-sJEI Secret Behind "hv = BE+KE+Ø" Equation for X-rays Photoelectron Spectroscopy https://youtu.be/zKbBA-Mdcqg XPS vs XRF vs Auger Effect- X-rays Photoelectron Spectroscopy https://youtu.be/WMSiReWsUCk Why X-rays photoelectron spectroscopy is a Surface Sensitive Technique? https://youtu.be/xb3jZ7Z9EoU Why p-orbital, d-orbital, f-orbital have TWO Peaks- Doublet in XPS Spectra https://youtu.be/LL281sSvdDc Why Only Core Electrons Peaks in XPS - X-rays Photoelectron Spectroscopy https://youtu.be/lOGKcXS11RM Please SUBSCRIBE my channel and share it. Best,