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Plasma ashing

Plasma ashing, also known as plasma stripping or dry ashing, is a dry etching process used in semiconductor manufacturing and microfabrication to remove organic materials, such as photoresist residues, from silicon wafers or other substrates following lithographic patterning and etching steps. Developed in the late 1960s, it was among the first plasma-based techniques adopted for photoresist removal in integrated circuit fabrication. The process involves placing the in a where oxygen gas is introduced and ionized using radiofrequency (RF) or energy to generate a reactive containing oxygen radicals. These radicals oxidize the organic layers into volatile compounds like , , and , which are then evacuated by a , leaving a clean surface without the need for liquid chemicals. This technique is essential in fabrication for its precision, as it selectively removes organics while minimizing damage to underlying inorganic layers like , enabling high-yield production of microelectronic devices. Compared to wet chemical stripping, plasma ashing offers environmental advantages by reducing and is particularly effective for cleaning complex three-dimensional structures in advanced nodes. Downstream plasma systems are commonly used to dissociate gases away from the , preventing ion bombardment damage.

Introduction

Definition and purpose

Plasma ashing is a technique employed in to remove organic materials, such as , from substrates by exposing them to ionized gas, or , which generates reactive species that chemically react with the organics. This process converts carbon-based polymers in the photoresist into volatile compounds, including (CO), (CO₂), and (H₂O), which are then evacuated from the chamber, leaving a clean surface without physical or liquid residues. Commonly, oxygen is utilized, where monatomic oxygen serves as the primary reactive species to facilitate oxidation. The primary purpose of plasma ashing is to perform post-etching cleanup in semiconductor manufacturing, stripping away masks that have protected underlying layers during patterning or steps, thereby enabling precise subsequent without or to delicate structures. This technique is particularly valuable for its selectivity and minimal impact on inorganic substrates, preserving features like metal interconnects or layers that could be harmed by wet chemical alternatives. While most prevalent on wafers, plasma ashing is also applicable to other substrates such as or metals, where the goal remains the efficient removal of residues to maintain surface integrity for further fabrication or . generation typically involves or excitation of the gas to produce the necessary reactive environment.

Historical development

Plasma ashing emerged in the late 1960s alongside the development of plasma etching techniques for integrated circuit fabrication, offering a dry method to strip photoresists as a cleaner alternative to wet chemical processes that generated significant liquid waste. Barrel reactors were among the initial commercial implementations, introduced by International Plasma Corporation (later Branson/IPC) in the late 1960s, which utilized oxygen plasma to remove photoresist layers efficiently while minimizing chemical residue. This innovation was driven by the growing complexity of semiconductor devices, where precise and contamination-free resist removal became essential for yield improvement. During the 1970s, plasma ashing saw widespread adoption in the , with oxygen-based systems becoming standard for stripping in lines. Early RF-powered reactors for ashing were patented around this period, enabling scalable ; for instance, foundational designs filed in 1976 laid the groundwork for controlled generation in applications. Companies such as International Plasma Corporation played a key role in commercializing these systems between the late and 1975, transitioning from experimental setups to production tools that supported the rapid growth of fabrication. Advancements in the focused on reducing substrate damage, leading to the introduction of downstream plasma configurations where the plasma is generated remotely from the to limit ion bombardment while delivering reactive for ashing. These designs were documented in proceedings such as the 1987 International Symposium on Chemistry, highlighting improved uniformity and selectivity for delicate structures. By the , plasma ashing integrated with sub-10 process nodes, incorporating additives such as CF4 to oxygen plasmas for effective removal of hardened resists used in , ensuring compatibility with high-aspect-ratio features without excessive undercutting. This evolution maintained plasma ashing's critical role in advanced semiconductor manufacturing, adapting to increasingly stringent requirements for and minimal damage.

Process description

Mechanism of ashing

Plasma ashing operates through the of a process gas, primarily oxygen (O₂), in a environment to generate reactive that facilitate the removal of organic materials like . The plasma is created by applying (RF) energy, typically at 13.56 MHz, or power to the gas, resulting in a . This discharge ionizes the oxygen molecules, producing a complex mixture of high-energy electrons, positive ions (such as O₂⁺), and neutral reactive , including monatomic oxygen atoms (O) and oxygen radicals. These radicals are the key agents in the ashing process, as their high reactivity stems from unpaired electrons that enable bond breaking in organic polymers. The core chemical mechanism involves the oxidation of hydrocarbon-based materials, which are typically composed of , , and oxygen in form (CₓHᵧ). Monatomic oxygen radicals diffuse to the surface and react with these hydrocarbons, breaking C-H and C-C bonds to form volatile gaseous byproducts. A representative is CₓHᵧ + 2(x + y/4)O → xCO₂ + (y/2)H₂O, where the and are readily evacuated by the vacuum system, leaving no solid residue. This oxidative process is highly selective for organic materials and proceeds efficiently due to the abundance and high reactivity of oxygen in the . Physically, plasma ashing emphasizes neutral species interactions over effects, distinguishing it from directional processes. Ion bombardment from positively charged species is minimal, as the primary removal occurs via isotropic of neutral s to the surface, ensuring uniform material stripping without significant damage or anisotropic profiles. Process parameters critically influence the efficacy: vacuum pressures of 0.1–10 control plasma density and radical lifetime, RF power levels from 100–2000 W determine rates and radical generation, and temperatures ( to 200°C) affect reaction kinetics and byproduct volatility. In downstream plasma configurations, the separation of plasma generation from the substrate area leads to recombination of charged and ions en route to the , delivering primarily radicals. This recombination mitigates exposure to energetic ions and electrons, thereby preventing electrostatic charging of the that could damage underlying structures in sensitive devices.

Equipment and setup

Plasma ashing equipment typically consists of a , where the substrates such as wafers are placed for processing, a gas delivery system for introducing reactive gases like oxygen (O₂) or tetrafluoromethane (CF₄) through mass flow controllers, a radio-frequency (RF) or to generate the (often at 13.56 MHz with power levels up to 500 W or more), and an exhaust system to maintain low pressure and remove gaseous byproducts like and . Chamber configurations vary based on production needs: barrel reactors, which are cylindrical and allow of multiple wafers (up to 25 or more) in a vertical , are common for lower-volume or research applications due to their simplicity and isotropic processing; in contrast, single-wafer tools process one at a time in a horizontal parallel-plate setup, enabling better uniformity and integration into automated high-volume lines. Safety and control features include interlocks that prevent plasma ignition if vacuum integrity is compromised, such as detecting leaks or improper chamber sealing, and end-point detection systems using optical emission spectroscopy (OES) to monitor plasma emission lines (e.g., from or NO species) for reaction completion, ensuring over-ashing is avoided and process yield is maximized. The operational setup begins with loading wafers or substrates into the chamber, followed by evacuating the system to a base pressure below 10⁻⁶ using a turbomolecular or roughing to minimize contaminants; gases are then introduced at rates of 50–500 standard cubic centimeters per minute (sccm) to achieve operating pressures of 0.5–2 , after which the is ignited by applying RF power for a typical duration of 1–10 minutes per , depending on resist thickness and desired removal rate. Modern plasma ashing tools from vendors such as and are often integrated into platforms, where ashing modules connect via load locks to etching or deposition chambers, allowing sequential processing without atmospheric exposure to enhance throughput and reduce contamination in fabrication.

Types of plasma ashing

Downstream plasma ashing

Downstream ashing employs a remote configuration where the is generated in a separate tube or chamber, away from the , allowing reactive —primarily radicals—to be transported via piping or tubing to the main chamber containing the . In this setup, charged particles such as ions and electrons recombine before reaching the , ensuring that only long-lived interact with the surface. This separation is typically achieved using an or between the generation zone and the chamber, which controls the flux of radicals entering the area. The primary advantages of downstream plasma ashing stem from its low-damage profile, making it suitable for sensitive devices. By eliminating direct exposure to ions, it minimizes charging effects that can lead to or nonuniform , and reduces (UV) radiation damage that might degrade thin films or alter material properties. This configuration is particularly beneficial for processing low-k dielectrics, which are prone to damage from high-energy species, enabling safer ashing without compromising device integrity. Although the process may require longer times compared to direct methods due to the gentler radical-based reaction, it prioritizes yield and reliability in advanced fabrication. Process specifics often involve excitation at 2.45 GHz to generate the remote , with power levels up to 1200 , using gases like oxygen (O₂) or mixtures such as O₂/N₂ to produce oxygen radicals for efficient organic removal. The is typically placed on a heated platen (up to 300°C) to accelerate the , and radical is modulated by adjusting the size or gas flow rates (e.g., O₂ at 5000 sccm). Ashing rates can reach 4.4 µm/min for positive photoresists, with process durations up to 150 seconds, depending on thickness and desired cleanliness. This technique is preferred for advanced semiconductors featuring thin films and delicate structures, such as those in high-density integrated circuits, where preserving material integrity is critical. It excels in stripping post-, surface descumming, and activation without introducing defects. Downstream ashing was developed to mitigate damage issues encountered in earlier direct methods, and it remains common in tools like the March Plasma Systems PX-500 series, which support of wafers up to 200 mm.

Direct plasma ashing

In direct plasma ashing, the substrate, such as a semiconductor wafer, is positioned directly within the glow region of the plasma chamber, subjecting it to simultaneous exposure from ions, electrons, and reactive radicals generated in the discharge. This in-situ configuration, often implemented using parallel-plate or barrel reactors, employs radio frequency (RF) power to sustain a uniform plasma, enabling efficient interaction between the plasma species and the photoresist material. Barrel reactors, in particular, are commonly used for batch processing of multiple wafers, as they allow for vertical stacking and circumferential plasma exposure to achieve consistent ashing across substrates. A key characteristic of direct plasma ashing is its significantly higher etch rates compared to downstream methods, attributable to the enhanced chemical reactivity augmented by physical ion bombardment. Process gases typically include oxygen (O₂) mixed with (N₂), where the N₂ addition helps control residues by modulating the chemistry and improving ashing uniformity, particularly for complex resist structures. This method originated in the early as one of the first plasma-based techniques for stripping in fabrication, evolving from initial applications to dedicated ashing systems. Despite its speed, direct plasma ashing carries risks of substrate damage due to energetic ion bombardment and ultraviolet radiation, which can induce charging, lattice defects, or thin-film degradation in sensitive devices. These effects are mitigated through strategies such as operating at lower RF power levels to reduce ion energy or employing pulsed plasma modes, which limit cumulative exposure and minimize charge buildup while preserving high etch efficiency. Consequently, this approach remains widely adopted for applications requiring rapid processing, such as ashing thick photoresists or descum operations in (RIE) systems, where robustness outweighs the need for minimal damage.

Applications

In semiconductor manufacturing

In semiconductor manufacturing, plasma ashing is integrated into the fabrication workflow immediately following and steps, where it removes the patterned layer from the surface to enable subsequent metal deposition, , or additional processes. This dry stripping method replaces traditional wet chemical processes, providing a cleaner, more alternative that minimizes residue and supports high-volume production cycles involving 10–25 iterations per device. Specific applications include complete stripping after or formation, ensuring residue-free interfaces for reliable electrical connections in structures. For interconnect layers, plasma ashing performs descum operations to eliminate thin residual in vias and trenches post-development, preventing defects that could impede metal filling and . These uses are compatible with both positive-acting and negative-acting , as the chemistry effectively volatilizes polymers regardless of characteristics. The process is particularly essential for advanced three-dimensional architectures such as 3D and FinFET transistors, where precise, damage-free removal from high-aspect-ratio features and fin structures is required to maintain structural integrity and enable multilayer stacking or conformal doping. In production environments, downstream plasma ashing systems achieve throughputs of up to 100 wafers per hour, balancing speed with uniformity to support efficient operations. By delivering residue-free surfaces, plasma ashing enhances overall by reducing contamination-related defects in downstream steps like metallization. In sub-7 nm nodes, it plays a critical role in handling (EUV) photoresists, which are thinner and softer than traditional 193 nm resists, requiring low-damage conditions to minimize line edge roughness, sidewall damage, and pattern collapse during stripping.

Other industrial uses

Plasma ashing plays a key role in the fabrication of and sensors by removing organic residues from microstructures after processing, ensuring device reliability in applications such as accelerometers and deployment sensors. This cleaning step eliminates contaminants that could impair functionality in automotive, aviation, and products. In () manufacturing, plasma ashing is employed to remove residues and other organic contaminants during rework processes and , facilitating inspection and repair without damaging underlying traces. This technique provides a residue-free surface preparation, enhancing the accuracy of defect identification in assembled boards. For biomedical devices, plasma ashing prepares surfaces in items like catheters and implants by cleaning organic residues, thereby improving adhesion for subsequent coatings and promoting . in this context activates the surface without altering bulk properties, supporting graft and sterilization in one step. In research and analytical applications, plasma ashing is utilized for in scanning electron microscopy (SEM) and (TEM) by selectively removing contaminants, preserving inorganic features while minimizing artifacts in imaging. Downstream plasma systems effectively clean TEM grids and holders, reducing layers to enhance and analytical accuracy. Plasma ashing finds application in the industry for cleaning composite materials, where it removes organic contaminants to improve bonding and structural integrity in high-performance components. Additionally, since the , it has emerged in flexible electronics production for displays, aiding in the removal of and residues on flexible substrates to enable high-yield of curved and foldable screens.

Advantages and limitations

Advantages

Plasma ashing offers significant environmental benefits as a dry process that eliminates the use of wet chemicals, such as , N-methyl-2-pyrrolidone (NMP), or (DMSO), thereby avoiding the generation of hazardous liquid waste requiring costly disposal. Instead, it produces primarily (CO₂) and (H₂O) as byproducts, making it a more eco-friendly alternative to traditional wet stripping methods. This approach drastically reduces chemical consumption in semiconductor fabrication, aligning with industry efforts to minimize environmental impact. In terms of , plasma ashing enables controlled, anisotropic removal of organic layers with minimal undercutting and high selectivity toward inorganic substrates, such as (Si), (SiO₂), and (Si₃N₄). The dry nature of the process prevents issues like pattern collapse or swelling that can occur with liquid-based techniques, ensuring the integrity of delicate microstructures. Downstream plasma ashing configurations further enhance by reducing potential from ions and radiation through remote generation. Plasma ashing provides high efficiency, with single-wafer systems capable of processing in under 60 seconds and seamless into vacuum-based fabrication lines, eliminating the need for post-process steps. Its versatility allows scalability from laboratory-scale small chambers to high-volume production environments, while operating at low temperatures suitable for heat-sensitive materials. This compatibility with diverse substrates and structures supports its widespread adoption in advanced workflows.

Limitations and challenges

One significant limitation of plasma ashing is its reduced speed when processing thick photoresists or those implanted with , where radical recombination at higher pressures diminishes the density of reactive available for removal. To mitigate this, processes often require elevated temperatures up to 250°C to thermally activate the ash rate, with activation energies around 5 kcal/mol for photoresists. For implanted resists, high-dose exposure (≥10¹⁵ atoms/cm²) forms a crust that further slows ashing rates, sometimes necessitating rates around 30 nm/min in older systems, with modern optimizations achieving up to 1–2 μm/min. Damage risks are particularly pronounced in direct plasma ashing, where ion bombardment induces charging effects and localized heating on the , potentially degrading underlying gate oxides or ultra-shallow junctions through loss and redistribution. In unoptimized conditions, incomplete volatilization can lead to re-deposition on the surface, exacerbating and requiring downstream configurations to minimize exposure while relying on radicals. High capital and operational costs arise from the need for vacuum-based , including pumps and chambers that demand significant upfront and for maintaining low-pressure environments. Maintenance challenges include frequent replacement due to from reactive in RF-powered systems, which can degrade performance and increase downtime if not addressed through regular inspections. Selectivity issues emerge with metal-contaminated photoresists following , where embedded dopants or impurities reduce the efficiency of oxygen-based ashing, leading to incomplete removal and residue formation that can attack sensitive structures like metal gates. In such cases, plasma ashing alone often fails to achieve high selectivity over underlying or oxides, prompting hybrid wet-dry approaches—such as plasma pretreatment followed by activated or sulfuric-peroxide mixtures—to disrupt the crust and minimize material loss.

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