Principle of SIMS

In SIMS, a sample surface is bombarded with a high-energy primary ion beam. The primary ion energy is transferred to target atoms via atomic collisions resulting in a so-called collision cascade. Part of the energy is carried back to the surface and subsequently atomic and molecular particles are emitted from the outer layers. A fraction of these particles, which can vary over several orders of magnitude depending on the ionization probability of the respective species, is charged. These secondary ions are extracted by an electric field into a mass spectrometer, where their mass and thus their chemical structure are determined. The emission process of secondary ions is limited to the uppermost one to three monolayers (typically less than one nanometer in thickness) of a solid sample. Secondary ions can be elemental ions, clusters, molecular fragments and/or intact molecules that are desorbed from the surface. The detection limits are generally in the ppm to ppb range. These capabilities make SIMS a highly sensitive analytical technique delivering information about the chemical composition of a sample's surface.

Time-of-flight mass spectrometry has the ability to detect in parallel all generated ions, making it the optimum spectrometer for surface analysis by SIMS. Other types of mass spectrometers (quadrupole, magnetic sector) are also used for SIMS, but spectra must be developed sequentially because only selected ions pass through a slit. Parallel detection, on the other hand, in combination with unlimited mass range ensures that all of the generated ions (inorganic and organic) are used for the analysis. Thus, it is possible to only consume a minimal part of the surface during analysis leaving the sample effectively undamaged (“static SIMS”). Alternatively, the surface can be eroded layer by layer (dynamic SIMS) in order to gain information about the in-depth distribution of elements and compounds in surface-near regions.

Surface Spectroscopy

The typical result from a ToF-SIMS analysis is a mass spectrum of secondary ions reflecting the chemistry on the sample surface. Figure 1 shows a detail of a mass spectrum of positively charged secondary ions around the nominal mass of 27 amu. Two peaks are clearly resolved in this spectrum and have been identified as Al⁺ and the small organic fragment ion C₂H₃⁺. A mass resolution of at least 650 (defined as the nominal mass 27 amu divided by the mass difference between the masses of Al⁺ and C₂H₃⁺) is needed to separate these peaks. This demonstrates that a high mass resolution is necessary for unambiguous identification of the collected ions. Modern ToF mass spectrometers deliver mass resolutions over 13,000 in the higher mass range and approximately 9,000 around mass 27 amu.

Figure 1: Detail of a positive secondary ion mass spectrum demonstrating the need for good mass resolution. The Al-peak and the C₂H₃-peak are clearly separated.

Although the low mass range (1–200 amu) delivers information about elemental and small molecular fragment ions, the full strength of ToF-SIMS comes into play when evaluating the higher mass range of a spectrum. Molecules with masses of up to several 1000 amu are often represented in the mass spectrum by their molecular ions or as large characteristic fragments after the loss of a functional group like a hydroxyl-group (OH). Therefore, it is possible to characterize even chemically complex systems on a surface. A typical example is given in Figure 2, which shows the range between 450 amu and 750 amu of a mass spectrum of positively charged secondary ions generated from a polypropylene surface. Three distinct peak groups are detected, which can be identified as the molecular ions of the polymer additives Tinuvin 770 (a UV-stabilizer), Irganox 565 (a thermal stabilizer), and Cyanox 1790 (an antioxidant).

Figure 2: Detail of a positive secondary ion mass spectrum of a polypropylene surface. Three additives were identified: the UV stabilizer Tinuvin 770, the thermal stabilizer Irganox 565, and the antioxidant Cyanox 1790.

Chemical Imaging of Surfaces

ToF-SIMS analysis is not limited to the spectral characterization of chemical compounds on a surface. By scanning the finely focused primary ion beam over the sample surface, it is possible to generate chemical maps (up to 500 × 500 μm²) showing the lateral distribution of compounds on the surface. Imaging of larger samples (up to 90 × 90 mm² or up to 300 mm in diameter for circular samples) is accommodated by physically scanning the specimen stage under the primary ion beam. During imaging analysis, all ions generated in each pixel are collected by the mass spectrometer and stored in a data file (a spectrum image), making it possible to display distribution maps for all elements and compounds detected on the sample. The achievable lateral resolution is limited by the focus of the probing ion beam. Modern liquid-metal ion guns can be focused down to some 10 nm in DC-beam operation and to approximately 50 nm in pulsed-beam operation. (Pulsing of the primary beam is necessary for ToF-SIMS.)

Figure 3 gives an example of such an imaging analysis. The analytical task was to detect the origin of a blooming of whitish crystals on the surface of a car bumper. A small piece was cut from the bumper and placed into the mass spectrometer for analysis. Figure 3a depicts a light optical image of the sample inside the mass spectrometer. The whitish crystals on the surface can easily be seen. Figure 3b shows a three color overlay of chemical maps of several compounds detected on the surface (Figures 3c to 3e). The crystals on the surface were identified as a segregation of the phosphate antioxidant Ultranox 626 (Figure 3d, green color). Unrelated to the crystal formation, residues of the release agent Li stearate (Figure 3e, blue color) were also found on the sample.

Figure 3: (a) Light optical image of white crystals blooming on a car bumper (field of view about 800 × 800 μm²). (b) 3-color overlay of secondary ion images detected on a blooming area (field of view 500 × 500 μm²). (c) (Red) base polymer of bumper. (d) (Green) antioxidant Ultranox 626. (e) (Blue) release agent Li stearate.

Until recently, this type of analysis was not commonplace, because it was often not possible to achieve good image contrast. Despite the good focus of the primary beam, the intensity for many structurally significant secondary ions (like molecular ions) in the higher mass range was too low. This has changed with the use of polyatomic primary ions as projectiles resulting in a dramatic increase (typically by two orders of magnitude) in the number of secondary ions that can be generated from a certain surface area compared to monoatomic primary ions [Reference Kollmer3]. This rise in efficiency combined with the focus quality of modern liquid metal ion sources, using bismuth or gold cluster ions, has pushed the lateral resolution of ToF-SIMS images of organic compounds into the range of 100 nm.

Depth Profiling

ToF-SIMS also can be applied to analyze the in-depth distribution of chemical compounds in sub-surface regions and to characterize the interfaces between different layers. This is done by using ion bombardment for the controlled erosion of a sample and analyzing the freshly exposed surface in parallel. With the proper selection of the analytical conditions, ToF-SIMS can be used for high-performance, ultra-shallow depth profiling with sub-nanometer-depth resolution as well as for the analysis of several micrometer-thick layers. Figure 4 shows a profile of a multilayer system on glass. The sample is a piece of a halogen spotlight reflector consisting of 10 double layers of titanium oxide and glass. The thickness of the layers increases with depth in order to accomplish a broadband reflection of the visual spectrum of the halogen bulb. A boron surface contaminant was detected at the start of the profile. As expected, the boron intensity rises again in the glass bulk.

Figure 4: ToF-SIMS depth profile of a multilayer coating on a halogen spotlight reflector.

3D-Analysis

Combining depth profiling with imaging analysis, ToF-SIMS can even be used to produce three-dimensional analyses of small volumes. An example from the field of metallurgy is shown in Figure 5. The sample is a polycrystalline metal oxide with the nominal composition O_2.8Mg_0.2Ga_0.8 Sr_0.2La_0.8 and a thin overlayer of Cr, Fe, and Y on the top. ToF-SIMS was used to study the diffusion from the overlayer into the polycrystalline bulk. Figure 5 shows the distribution of Mg (bulk) and Y (from the overlayer) in a cube of the size of the analyzed volume (60 × 60 × 0.8 μm³). A complete mass spectrum is saved for every voxel (the volume equivalent of a pixel) in the analyzed volume. It is possible to reconstruct spectra, images, and profiles from any region of interest inside the analyzed volume as demonstrated in Figure 6. After identifying the grain structure of the polycrystalline material from the secondary ion images, depth profiles from the grain boundaries and from the grains themselves were reconstructed. It is obvious that the diffusion of the elements from the overlayer is more pronounced along the grain boundaries. This possibility of retroactively mining a data set has proven to be very powerful, especially for these complex types of analyses.

Figure 5: 3D-distribution of Mg and Y in a polycrystalline metal oxide O_2.8Mg_0.2Ga_0.8Sr_0.2La_0.8 with an overlayer of Cr, Fe, and Y. The analyzed volume is 60 × 60 × 0.8 μm³.

Figure 6: Depth profiles on different areas (blue: grain boundaries; red: grains) reconstructed from the raw data of the 3D-analysis of a polycrystalline metal oxide O_2.8Mg_0.2Ga_0.8Sr_0.2La_0.8 with an overlayer of Cr, Fe, and Y (see Figure 5). The diffusion is more pronounced along the grain boundaries. The total field of view is 60 × 60 μm².

Acknowledgment

The author wants to thank his colleagues at Tascon and ION-TOF. The grain boundary sample was provided by Prof. Martin, RWTH Aachen, Germany.