Serving the best interests of our clients, our people and our communities, MSR-FSR employs an Integrated Management System to assure the provision of the highest Quality services, through practices that promote the Health and Safety of workers and provides for the protection of our Environment.

Our EHS & Commitment
Our Quality Commitment


ISO 9001 Certified Since 2011

ISO 9001:2015 specifies requirements for a Quality Management System when an organization:

  1. a) needs to demonstrate its ability to consistently provide products and services that meet customer and applicable statutory and regulatory requirements, and
  2. b) aims to enhance customer satisfaction through the effective application of the system, including processes for improvement of the system and the assurance of conformity to customer and applicable statutory and regulatory requirements.

NOTE: MSR-FSR’s Global Quality Director is a Subject Matter Expert formerly serving on the ISO Technical Committee 176, responsible for development of ISO 9001! 


ISO 45001 Certified Since 2020
Maintained OHSAS 18001 Certification 2011-2020
ISO 45001 Replaced OHSAS 18001 in 2020

ISO 45001:2018 Occupational Health and Safety (OH&S) Management System, helps an organization to achieve the intended outcomes of its OH&S management system. Consistent with the organization’s OH&S policy, the intended outcomes of an OH&S management system include:

  1. a) continual improvement of OH&S performance;
  2. b) fulfilment of legal requirements and other requirements;
  3. c) achievement of OH&S objectives.

NOTE: MSR-FSR’s Global EHS Director is one of the original Subject Matter Experts serving on the US Technical Advisory Group to ISO Technical Committee 283, responsible for the development of ISO 45001!   


ISO 14001 Certified Since 2011

ISO 14001:2015 specifies the requirements for an Environmental Management System that an organization can use to enhance its environmental performance. ISO 14001:2015 is intended for use by an organization seeking to manage its environmental responsibilities in a systematic manner that contributes to the environmental pillar of sustainability.


Environmental, Health and Safety Policy

At MSR-FSR we exist because of our customers; we excel because of our employees. Keeping our employees safe is a value embedded in our corporate culture. Safety is NOT simply an MSR-FSR priority. Safety is an intrinsic MSR-FSR Value. Priorities may Change, but Values are embedded in our Corporate Culture.

MSR-FSR EHS Leadership Commitment Pledge:

Provide for the protection of people, property, and the environment, commensurate with the concepts of ISO 45001 and 14001, to enable safe and healthy working conditions that prevent work-related injury or ill health, to the maximum extent achievable throughout the organization.

We will accomplish this by:

  • Using Key Performance Indicators / metrics as a framework for setting EH&S performance and continuous improvement objectives.
  • Fulfilling legal requirements and other relevant requirements to ensure an adequately trained, equipped, and engaged workforce.
  • Reducing EHS risk through workplace hazard identification and assessments, to ensure appropriate control, elimination, or prevention through the hierarchy of controls.
  • Continuously improve our EH&S management system through evaluation and review.
  • Committing to engaging our workers in consultation and participation opportunities, and where appropriate, worker representatives.
  • Collaboration with other organizations at multiemployer duty locations and client sites.

Our efforts to promote environmental stewardship and sustainment include pollution prevention efforts through wastewater neutralization, minimization of hazardous chemical usage, and collaboration of best practices to reduce overall risk and environmental impact.

Manage through presence. Question uncertainty. Empower success. Continually improve.

Quality Policy

MSR-FSR exists because of our customers.  To attract them, we develop highly innovative engineering services that create product or productivity opportunities.  To keep them, we are committed to the continuous improvement of quality in everything we do, so that we always meet or exceed our customers’ expectations.

To fulfill these commitments, MSR-FSR will establish clear, measurable quality objectives across the business, ensure they are communicated to all employees, and demonstrate progress toward meeting these objectives.


        Industry News


Frequently Asked Questions

What is the cleaning process of semiconductors?

The cleaning process of semiconductors involves several steps to remove contaminants like dust, organic residues, and metallic particles, which are crucial for the performance and reliability of semiconductor devices. Key steps include:

  1. Solvent Cleaning: Removes organic contaminants using chemicals like acetone and isopropyl alcohol.
  2. Acid and Base Cleaning: Utilizes solutions like the RCA clean method to eliminate ionic contaminants and particles.
  3. Rinsing and Drying: Involves thorough rinsing with deionized water followed by drying to remove any leftover chemicals.
  4. Megasonic/Ultrasonic Cleaning: Applies high-frequency sound waves to dislodge particles from the wafer surface.
  5. Advanced Techniques: Additional methods like plasma, ozone, or UV cleaning may be employed for specific needs.

What are the components of semiconductor equipment?

Semiconductor equipment is quite diverse and complex, as it comprises various machines used in different steps of semiconductor manufacturing. The components of semiconductor equipment vary significantly depending on their specific use, such as photolithography, deposition, etching, ion implantation, cleaning, and inspection. However, we can categorize the components into a few general groups for a broad understanding:

  1. Chamber Components: These are parts of the equipment where the actual semiconductor processing occurs. They can be vacuum chambers, reaction chambers, etching chambers, deposition chambers, etc. Each chamber is designed to create specific conditions necessary for a particular manufacturing step.
  2. Wafer Handling Systems: These systems are responsible for transporting semiconductor wafers through the equipment during the manufacturing process. They include robotic arms, end effectors, aligners, and wafer loaders/unloaders, ensuring minimal contact with the wafers to avoid contamination.
  3. Control Systems: These are sophisticated computer systems that manage the equipment's operation. They control process parameters like temperature, pressure, gas flow, and timing, ensuring that the manufacturing processes are executed precisely and consistently.
  4. Power Supplies and Distribution Systems: Semiconductor equipment often requires precise and variable power supplies, especially for processes like plasma generation, heating elements, and motors. These systems must provide stable and controllable power to various components of the equipment.
  5. Gas Delivery Systems: Many semiconductor processes, like deposition and etching, require precise delivery of gases. These systems include gas cylinders, mass flow controllers, valves, and piping, all designed to deliver specific gases in controlled amounts to the process chambers.
  6. Vacuum Systems: Vacuum systems are critical for processes that need to be carried out in a controlled atmosphere or vacuum. These include vacuum pumps, vacuum chambers, valves, and gauges, enabling the creation and maintenance of the required vacuum levels.
  7. Cooling and Heating Systems: Temperature control is crucial in semiconductor processes. Equipment components include heaters, chillers, heat exchangers, and cooling plates, ensuring that the process temperatures are maintained within the required ranges.
  8. Sensors and Monitoring Equipment: These components include various sensors and detectors that monitor process conditions such as temperature, pressure, gas concentrations, and plasma conditions, providing feedback to the control systems to adjust the process parameters as needed.
  9. Cleaning and Maintenance Tools: These are tools and systems designed for the cleaning and maintenance of semiconductor equipment, ensuring that the components are free from contaminants and are operating correctly.

What is wafer cleaning process?

The wafer cleaning process in semiconductor manufacturing is crucial for removing contaminants from silicon wafers before and during the various stages of chip fabrication. Even minute particles or impurities can significantly impact the performance and yield of semiconductor devices. The wafer cleaning process involves several steps, often tailored to the specific contaminants and the subsequent processes the wafer will undergo. Here's an overview of the typical wafer cleaning process:

  1. Solvent Cleaning: This initial step aims to remove organic contaminants such as grease, oils, and photoresist residues from the wafer surface. Solvents like acetone, isopropyl alcohol, or methanol are commonly used. Wafers are immersed in these solvents and may be subjected to ultrasonic agitation to enhance contaminant removal.
  2. Aqueous Cleaning: After solvent cleaning, wafers are typically cleaned with deionized (DI) water to remove particulate matter and ionic contaminants. This step may involve multiple rinses or the use of megasonic cleaning, which uses high-frequency sound waves to dislodge particles from the wafer surface.
  3. Chemical Cleaning: This involves the use of specific chemical solutions to target different types of contaminants:
    • RCA Clean: A standard procedure that includes two main steps:
      • SC-1 (Standard Clean 1): A mixture of ammonium hydroxide (NH₄OH), hydrogen peroxide (H₂O₂), and water is used to remove organic residues and particles.
      • SC-2 (Standard Clean 2): A mixture of hydrochloric acid (HCl), hydrogen peroxide (H₂O₂), and water targets metallic contaminants and some ionic impurities.
    • HF Dip: Hydrofluoric acid (HF) is used to remove native silicon dioxide from the wafer surface, which can trap contaminants and impede further processing steps.
  4. Rinse and Dry: Following chemical cleaning, wafers are thoroughly rinsed with DI water to remove any residual chemicals. They are then dried using methods like spin drying or nitrogen blow drying, which prevent water spots and ensure that no contaminants are reintroduced.
  5. Advanced Cleaning Techniques: For certain applications, especially in advanced semiconductor nodes, additional cleaning steps may be employed, such as plasma cleaning, UV-ozone cleaning, or megasonic cleaning, to achieve the required level of cleanliness at the atomic level.

what is SPC Tracking?

SPC (Statistical Process Control) tracking is a method used in manufacturing, including semiconductor manufacturing, to monitor, control, and optimize processes through statistical methods. It is a core component of quality control that helps ensure manufacturing processes produce products within the desired specifications consistently. Here's a breakdown of what SPC tracking involves:

    1. Data Collection: The first step in SPC tracking is the systematic collection of data from the manufacturing process. This data typically includes measurements of product characteristics, process parameters, or other key quality indicators. For instance, in semiconductor manufacturing, this could involve measurements of layer thickness, line widths, or electrical properties.
    2. Statistical Analysis: The collected data is analyzed using statistical methods to identify patterns, trends, and variations. This analysis often involves calculating mean values, variances, and other statistical parameters to understand the process behavior over time.
    3. Control Charts: A fundamental tool in SPC tracking is the control chart, which is used to plot data points over time, comparing them against predetermined control limits (upper and lower) and a central line (average). These charts help in visualizing the stability of the process and identifying any signs of unusual variations that could indicate potential problems.
    4. Process Monitoring: Continuous monitoring of the process through SPC helps identify when the process is deviating from its intended operating conditions. By detecting these changes early, it's possible to intervene before defects occur or the process produces outputs outside the acceptable range.
    5. Identifying Variations: SPC tracking helps distinguish between common cause variation (natural variation inherent in the process) and special cause variation (due to specific, identifiable sources). Understanding these variations is crucial for effective process control and improvement.
    6. Improvement Actions: When SPC tracking identifies a process that is not under control or could be improved, corrective actions are taken to address the underlying causes of variation. This might involve adjusting the process, performing equipment maintenance, or changing materials.
    7. Continuous Improvement: SPC tracking is an ongoing process that contributes to continuous improvement in manufacturing. By regularly analyzing process data, manufacturers can make informed decisions to enhance quality, reduce waste, increase efficiency, and meet customer satisfaction.

What is cleaning sequence?

The cleaning sequence in semiconductor manufacturing refers to the ordered series of steps undertaken to remove contaminants from the surface of semiconductor wafers. This sequence is crucial for ensuring the wafers are free from particles, organic residues, and metallic impurities, which could otherwise lead to defects in the semiconductor devices. While specific cleaning sequences can vary depending on the exact manufacturing requirements, a general cleaning sequence typically includes the following steps:

  1. Pre-cleaning: This step might involve rinsing the wafers with deionized water to remove loose particles and surface contaminants. It serves as a preliminary step before more intensive cleaning processes.
  2. Solvent Cleaning: This involves using organic solvents such as acetone, isopropyl alcohol (IPA), or methanol to remove organic contaminants from the wafer surface. Wafers may be immersed in these solvents and possibly subjected to ultrasonic agitation to enhance cleaning effectiveness.
  3. Aqueous Cleaning: After solvent cleaning, the wafers are often cleaned with deionized water or aqueous solutions to remove residual particles and ionic contaminants. This step may include the use of megasonic or ultrasonic cleaning to further dislodge particles.
  4. Chemical Cleaning: This is a critical phase where specific chemical solutions are used to target various types of contaminants:
    • RCA Clean: The RCA cleaning process, developed by the Radio Corporation of America, is widely used in the semiconductor industry. It usually involves two main sub-steps:
      • SC-1 (Standard Clean 1): A mixture of ammonia (NH₄OH), hydrogen peroxide (H₂O₂), and water is used at elevated temperatures to remove organic residues and particles.
      • SC-2 (Standard Clean 2): This involves a mixture of hydrochloric acid (HCl), hydrogen peroxide (H₂O₂), and water to remove metallic contaminants and some ionic impurities.
  5. Rinse and Dry: After the chemical treatments, the wafers are thoroughly rinsed with deionized water to remove any remaining chemicals. Finally, the wafers are dried using methods such as spin drying or nitrogen blow drying to prevent water spots and recontamination.
  6. Advanced Cleaning Steps: Depending on the process requirements, additional cleaning steps like HF (hydrofluoric acid) dips to remove native oxides or specialized treatments like ozone or plasma cleaning may be included to ensure the wafer surface is prepared for subsequent processing steps.