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Semiconductors are the fundamental components of modern electronic goods. Cleanliness is crucial inside of a semiconductor fabrication facility, considering the scale of the working surfaces (nanometers). Contaminants of all types can result in defects, leading manufacturers to implement extremely strict and precise production control procedures with high reproducibility, especially during one the most important production steps: wafer surface treatment with etching and cleaning baths for impurity removal and surface texturing. This article highlights the benefits for semiconductor manufacturers to implement near-infrared spectroscopy (NIRS) in wafer pretreatment processes for real-time analysis, 100% traceability, optimal product safety, and maximum wafer carrier throughput.

Close-up view of a silicon wafer. Each miniature square is a chip with microscopic transistors and circuits.
Close-up view of a silicon wafer. Each miniature square is a chip with microscopic transistors and circuits.

Would you like to know more about how NIR spectroscopy works? Check out some of our other blog posts:

Frequently asked questions in near-infrared spectroscopy analysis – Part 1

Benefits of NIR spectroscopy: Part 2

Equipping semicon wet benches with a 2060 The NIR Analyzer

In a semiconductor fabrication facility, a typical wet bench unit consists of several individual baths with specific purposes (i.e., chemical etching, cleaning, and rinsing). For these tasks, each process line requires different acid or base mixtures or various organic components. Figure 1 illustrates the typical setup of a wet bench with one of several available configurations for the 2060 The NIR Analyzer from Metrohm Process Analytics.

This example includes the etching bath HF Dip (hydrofluoric acid with a certain concentration level which is based on a specific etching rate), SC1 (standard clean treatment consisting of ammonium hydroxide and hydrogen peroxide in water), SC2 (standard clean treatment consisting of hydrochloric acid and hydrogen peroxide in water), HotPhos (phosphoric acid in water), and others (rinsing steps which are not monitored with NIRS). 

Figure 1. Typical wet bench setup showing the installed NIR clamp-on flow cell (in orange) for continuous monitoring of bath composition.

Chemicals are circulated using pumps with some integrated filters that aim to prevent the semicon wafers from contamination. The wafer carrier is dipped into each bath for a certain amount of time, dependent on the  concentration of chemicals. As the carrier holds many highly valuable wafers, exact knowledge of the process conditions at any time is crucial. Real-time process monitoring is performed by using clamp-on flow cell sensors which are implemented into the circulation line of each bath (Figure 1).

The results of this real-time monitoring are available within a Process Control System (PCS) for fast intervention and controlling if any measured parameters fall out of specification.

Non-invasive clamp-on flow cell with optical fibers (in blue) attached to the wet bench circulation stream. Note the protective and purged tube around the fiber, preventing corrosion.
Figure 2. Non-invasive clamp-on flow cell with optical fibers (in blue) attached to the wet bench circulation stream. Note the protective and purged tube around the fiber, preventing corrosion.

Inside of a wet bench, a sensor is attached to each of the process lines (Figure 2). This clamp-on flow cell was designed and customized together with our partners from the semiconductor industry. Some of the major benefits for users are listed below:

  • completely contactless and non-invasive, preventing contamination and downtime
  • plug and play: easy to implement and no need to modify existing installations
  • adaptable to the main process line for easy measurements
  • PTFE material and purging option for optics and light fibers, preventing corrosion

The sensors are attached to the 2060 The NIR Analyzer – the centerpiece and intelligent evaluation unit – which provides a fast, reliable measuring technique that can analyze all relevant quality parameters within seconds. This high-tech process analyzer is ideal for monitoring wet bench bath composition:

  • multiplexing allows users to measure a variety of parameters in up to five process streams with a single analyzer
  • plug and play ability means seamless integration and faster start-up
  • high quality optical fibers connected to probes and analyzer transmit data quickly and reliably even over long distances from the wet bench
  • result monitoring of an entire wet bench unit in less than five minutes – meaning real-time process monitoring
  • intelligent process control, e.g., for prioritizing sample streams by the PCS for higher measurement frequencies when needed


If space is limited such as in difficult to access cleanroom areas, the 2060 The NIR-R Analyzer can be mounted outside the cleanroom area. The distance between the NIR cabinet and the sampling point(s) can be up to hundreds of meters—achievable with the use of low-dispersion optical fibers. Additionally, up to two different wet bench units can be monitored and controlled with one Human Interface. This is extremely beneficial when space is at a premium and analysis costs need to be saved, as this setup can monitor up to ten sampling points (Figure 3).

Figure 3. (L) Easy implementation and accessibility using the remote version of the 2060 The NIR Analyzer with the possibility of two parallel working spectrometer cabinets. (R) 2060 The NIR Analyzer and 2060 The NIR-R Analyzer.

Enhanced product and process safety by critical data availability and process condition monitoring

Predictive maintenance and vital data availability are phrases often used when discussing Process Analytical Technology (PAT). In addition to the actual concentration measurement, the 2060 The NIR Analyzer provides secondary process information which can be used as conditions for further actions. For example, depending on the measured process temperature, the process analyzer could automatically utilize a specific NIR calibration model or send a warning to a DCS/PLC/Scada in case of an unwanted temperature change. However, there are many more points to consider that can lead to enhanced product and process safety together as well as better process understanding. These include:

  • using traceable standards for automated internal instrument calibration and self-diagnosis
  • automated instrument calibration and hardware performance tests (health checks) within defined intervals or for checking validity of measurements
  • status of maintenance requirements
  • additional chemometric parameters to check the bath quality in addition to concentration measurements (e.g., outlier detection)
  • using a temperature-stabilized spectrometer for stable conditions and the highest precision
  • implementation of a power buffer and controlled shutdown sequence to maintain data availability


Find out more about the advantages of Process Analytical Technology (PAT) in our blog series.

To automate or not to automate? Advantages of PAT – Part 1

Typical applications for the 2060 The NIR Analyzer within the semiconductor industry

Plant manufacturers customize their wet benches for the specifications of each end customer, and so does Metrohm Process Analytics. We offer applications for a wide range of critical chemical parameters in every combination, concentration, and temperature range—even including those which haven’t been developed yet. 

Table 1. Typical etching and cleaning chemicals implemented into wet benches.

Bath name Composition
HotPhos H3PO4 / H2O
HF Dip/DHF HF / H2O
BOE NH4F / HF / H2O
PETCH HF / HNO3 / H2O
SC1/APM NH4OH / H2O2
SC2 HCl / H2O2 / H2O
SPM H2O2 / H2SO4
TMAH TMAH / H2O
HCl HCl / H2O
HF / HNO3 / CH3COOH HF / HNO3 / CH3COOH
IPA C3H8O / H2O
NaOH NaOH (In addition to semiconductor applications, NaOH is mainly used for glass etching processes.)
KOH KOH

Increased process reliability and bath lifetimes with real-time monitoring

Now knowing which chemicals are generally used in a front-end production line for wafer processing leads to the question: Why is it mandatory to monitor all of these parameters in real time?

Looking back at Figure 1, carriers containing multiple wafers are dipped into various etching and cleaning baths. By doing so, the chemicals react with the wafer surface, resulting in a permanent change of the chemical composition – mostly a decrease of the etching/cleaning agent concentration. Within a very short time, the precisely adjusted etch rate (abrasion of the wafer surface over time, directly correlated to the HF concentration) would no longer match the strict specifications, and the entire batch of wafers would be rejected. To avoid permanent renewal of the baths and to ensure a very reproducible process under strict specifications, the HF concentration must be known at any time in order to be properly adjusted. 

Figure 4 shows a concentration trend chart measured by NIRS from a standard clean 1 (SC1) bath which consists of ammonia (NH3) and hydrogen peroxide (H2O2). Based upon certain concentration limits or time limits, bath exchanges are induced. It is very important that both of these parameters are monitored independently of each other.

Figure 4. Real-time monitoring of ammonia and hydrogen peroxide in SC1 (L), with a closer look at the ammonia concentration trend (R).

A closer look at the trend chart in Figure 4 shows how accurate and precise the NIRS measurements are. In this example, the goal was to monitor the ammonia dosage within the SC1 bath in order to optimize recirculation for fast and homogeneous mixing. Each NH3 dose is detected as a peak followed by a slight decrease of <0.10 wt% within the next five minutes. Even small concentration changes can be resolved. The 2060 The NIR Analyzer measurement repeatability is outstanding. It is application-dependent and able to monitor chemical concentrations down to <0.02 wt%. Ultimately, very precise chemical dosing in wafer baths with real-time data analysis can be achieved—true process optimization and control. A 2060 The NIR Analyzer shows its full potential by increasing bath lifetimes, reducing chemical waste, and minimizing costly product loss (i.e., discarded semiconductor wafer batches).

Conclusion

One of the primary goals at a semiconductor fabrication facility is to achieve the highest throughput of wafer carriers in a wet bench without any delays or product loss—otherwise there are significant economic repercussions. However, these manufacturing plants already run at maximum capacity and each hour of downtime leads to a loss of hundreds of thousands of euros.

Real-time monitoring of the chemical composition is mandatory for wet bench baths. The 2060 The NIR Analyzer from Metrohm Process Analytics was developed for situations just like this, and offers users much more than just a concentration measurement:

  1. Real-time monitoring of up to two entire wet benches for semiconductor wafer cleaning and etching baths
  2. Flexible software for straightforward control – Intelligent Metrohm Process Analytics Control Technology (IMPACT) – with parallel analysis possible with a single process analyzer
  3. Plug and play options for almost any chemical composition and end-user requirement

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Author
Hakelberg

Sabrina Hakelberg

Product Manager Process Spectroscopy
Deutsche Metrohm Prozessanalytik (Germany)

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