Wavelength Dependence of Photon-Induced Interface Defects in Hydrogenated Silicon Nitride/Si Structure during Plasma Etching Processes

The effect of ion flux on the formation of a damaged layer in a Si substrate was investigated in detail. An inductively coupled plasma source was used to control the flux (Γ ion ) and energy (E ion ) of incident ions. The progressive behavior of the total damaged layer thickness (d dam ) estimated by spectroscopic ellipsometry primarily depends on the total ion dose (D ion = Γ ion ' t pr , where t pr is the process time) and E ion . The evolution of d dam then saturates and becomes independent of D ion . The characteristic total ion dose (D dam ) is defined, which distinguishes the progressive and saturation phases. Experimental results suggest that D dam is estimated to be in the range from 1 ' 10 16 to 3 ' 10 16 cm %2 , regardless of Ar and He plasmas in the present study. This D ion -dependent behavior was also confirmed by transmission electron microscopy and capacitance-voltage measurements. The interface thickness d IL of the damaged layer was found to be independent of D ion . This result confirms that d IL can be used as a measure of the E ion -dependent plasma-induced damage (PID) for in-line monitoring. The present D ion dependence can be implemented in the conventional PID range theory, particularly, in the designs of high-density plasma sources.

Section: Introductionmentioning

confidence: 99%

Incident ion dose evolution of damaged layer thickness in Si substrate exposed to Ar and He plasmas

Hamano

Eriguchi

2018

“…27) In conjunction with an introduction of the so-called low-k films, the dielectric constant change after plasma exposure was discussed in many literatures. [59][60][61][62][63][64][65] This explored the extensive research of the PRD mechanism. Device structure-dependent, i.e.…”

Section: Brief History Of Pid Researchmentioning

confidence: 99%

Characterization techniques of ion bombardment damage on electronic devices during plasma processing—plasma process-induced damage

Eriguchi

2021

Plasma processing plays an important role in manufacturing leading-edge electronic devices such as ULSI circuits. Reactive ion etching achieves fine patterns with anisotropic features in metal-oxide-semiconductor field-effect transistors (MOSFETs). In contrast, it has been pointed out over the last four decades that plasma processes not only modify the surface morphology of materials but also degrade the performance and reliability of MOSFETs as a result of defect generation in materials such as crystalline Si substrate and dielectric films. This negative aspect of plasma processing is defined as plasma (process)-induced damage (PID) which is categorized mainly into three mechanisms, i.e. physical, electrical, and photon-irradiation interactions. This article briefly discusses the modeling of PID and provides historical overviews of the characterization techniques of PID, in particular, by the physical interactions, i.e. ion bombardment damage.

“…The change in residual stress due to etching was reportedly caused by irradiation of ions, 16) vacuum ultraviolet (VUV) light, 15) and neutral species 17,18) delivered from plasma. They have been reported to degrade the irradiated surface [16][17][18][19][20][21][22][23] and generate residual stress on the surface (surface stress) in some cases. [16][17][18] Here, we discussed on the basis of a schematic view shown in Fig.…”

Section: Measurement Of Internal Residual Stressmentioning

confidence: 99%

Mechanism of wiggling enhancement due to HBr gas addition during amorphous carbon etching

Kofuji

Ishimura

Kobayashi

et al. 2015

The effect of gas chemistry during etching of an amorphous carbon layer (ACL) on wiggling has been investigated, focusing especially on the changes in residual stress. Although the HBr gas addition reduces critical dimension loss, it enhances the surface stress and therefore increases wiggling. Attenuated total reflectance Fourier transform infrared spectroscopy revealed that the increase in surface stress was caused by hydrogenation of the ACL surface with hydrogen radicals. Three-dimensional (3D) nonlinear finite element method analysis confirmed that the increase in surface stress is large enough to cause the wiggling. These results also suggest that etching with hydrogen compound gases using an ACL mask has high potential to cause the wiggling.