Characterization of surface damage in dry-etched InP

Iber, H.; Mo, S.; Peiner, Erwin; Vollrath, G.; Schlachetzki, A.; Fiedler, Fritz

doi:10.1088/0268-1242/12/6/019

Cited by 17 publications

(11 citation statements)

References 26 publications

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“…5,6 A great effort has been made to reduce the ion irradiation damage during dry etching of compound semiconductors and other related processes. 3,[21][22][23] Using deep level transient spectroscopy to detect defect states, Yu et al, 20 investigated defect formation on GaAs induced by an exposure of the sample to an argon plasma with a sample biasing voltage to facilitate ion irradiation. They concluded that damage-free ion beam processing is possible with an ion energy of less than 20 eV.…”

Section: Introductionmentioning

confidence: 99%

Damage of InP (110) induced by low energy Ar+ and He+ bombardment

Zhao¹,

Kwok²,

Lau³

2000

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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Plasma-induced surface damage of a III-V compound semiconductor, a problem associated with many device fabrication processes, is clarified with careful measurements of surface defect density induced by low energy ion bombardment of InP. In the study, n-and p-InP ͑110͒ surfaces were prepared by cleavage of InP in ultrahigh vacuum, and then bombarded as a function of ion type (He ϩ and Ar ϩ ͒, energy ͑5-100 eV͒, and fluence (10 12 -10 17 ions/cm 2 ). The dynamic process of surface Fermi level shifting induced by such bombardment was determined by in situ high-resolution x-ray photoelectron spectroscopy, and the data were then converted to information on surface defect formation. It was found that both He ϩ and Ar ϩ bombardment with the above conditions moved the Fermi levels of both n-and p-InP ͑110͒ surfaces towards 0.95 eV above the valence band maximum of InP. As expected, for the same bombardment energy, Ar ϩ caused more damage than He ϩ , and for the same ion type, the bombardment induced a surface defect density increasing with both ion energy and fluence. It was also found that the threshold condition for defect formation was a combined function of the impact energy of the incoming ion and the energy released during its neutralization.

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Section: Introductionmentioning

confidence: 99%

Damage of InP (110) induced by low energy Ar+ and He+ bombardment

Zhao¹,

Kwok²,

Lau³

2000

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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“…The surface of an etched material is admitted to increase the probability of non-radiative electron-hole recombination (as it can be explained by the increase of the SRV). This is due to the damage induced on the surface by the etching together with the point defects created at the surface neighbourhood by the ion bombardment [3]. The lower CL intensity on the ridge can arise from the strong increasing of the SRV at the side walls; the carriers generated inside the ridges have a non-negligible probability of reaching the sidewalls and to recombine therein non-radiatively; this probability should depend on the ridge width, the narrower the ridge the higher the probability of minority carriers to reach the ridge sidewalls recombining non-radiatively.…”

Section: Resultsmentioning

confidence: 99%

“…The studies carried out for the optimisation of the etching procedures have been mainly focused on the morphological analysis, e.g. the verticality of the engraved walls, and the residual roughness [3,4]. These studies are currently carried out by morphology inspection techniques, as scanning electron microscopy (SEM) and atomic force microscopy (AFM).…”

Section: Introductionmentioning

confidence: 99%

Cathodoluminescence study of inductively coupled plasma (ICP) etched InP waveguide structures: Influence of the ridge dimension and dielectric capping

Avella¹,

Jiménez²,

Pommereau

et al. 2008

Materials Science and Engineering: B

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“…The curve is related to the DX centres filled with electrons in the λ region. Curves (2) and (3) are thermal scans for the samples under zero-bias corresponding to initial conditions at 80 K of empty DX centres. Initial condition (3) was obtained by cooling the samples from 300 to 80 K with -9 V. At 80 K the bias was returned to 0 V. Condition (2) was obtained by cooling the samples with zero bias and then emptying the DX centres by recombination of the electrons with injected holes under forward bias (+2 V/ 5 min).…”

Section: Resultsmentioning

confidence: 99%

“…Due to anisotropic properties and consequently good linewidth control, "dry etching" is useful in pattering semiconductor properties including etching sub-micron features both in Si and III-V semiconductors [1][2][3]. For instance, dry etching is used for the fabrication of advanced optoelectronic components like quantum wires and quantum dots [4].…”

Section: Introductionmentioning

confidence: 99%

Deep‐level defects induced by Ar‐ion beam etching in n‐type Al_xGa_1‐xAs grown by MBE

Kaniewska

Bozek

2003

Cryst. Res. Technol.

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Results of the electrical study of the damage caused by Ar-ion beam etching in MBE grown Al x Ga 1-x As : Si laser diode material are reported. This study has involved measurements of capacitance as a function of voltage and temperature as well as deep level transient spectroscopy measurements on Schottky-barriers diodes. The Schottky contacts were fabricated conventionally by depositing Au in a vacuum onto the etched AlGaAs surface. For a reference the Schottky diodes of the best quality were produced in-situ by evaporation of Al on the top of the epi-layer at the end of the MBE growth run. On the basis of the results of a comparative study deep-level defects related to the subsurface damaged layer have been recognised. Emission signatures as well as depth profiles of the defect concentration have been studied and analysed. Moreover, DLTS spectra revealed the presence of a well-known DX(Si) centre and M-type defect related level attributed to a vacancy and impurity complex. The presence of an additional deep-level defect located in the lower half of the energy gap that was induced by dry etching is also suggested. An extra defect considered has the high enough concentration to disturb carrier spatial profiles and DX centre characteristics. It is suggested that it may be responsible for degradation effects in GaAs/AlGaAs heterostructure lasers, which fabricating involves dry etching.

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Characterization of surface damage in dry-etched InP

Cited by 17 publications

References 26 publications

Damage of InP (110) induced by low energy Ar+ and He+ bombardment

Damage of InP (110) induced by low energy Ar+ and He+ bombardment

Cathodoluminescence study of inductively coupled plasma (ICP) etched InP waveguide structures: Influence of the ridge dimension and dielectric capping

Deep‐level defects induced by Ar‐ion beam etching in n‐type Al_xGa_1‐xAs grown by MBE

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Characterization of surface damage in dry-etched InP

Cited by 17 publications

References 26 publications

Damage of InP (110) induced by low energy Ar+ and He+ bombardment

Damage of InP (110) induced by low energy Ar+ and He+ bombardment

Cathodoluminescence study of inductively coupled plasma (ICP) etched InP waveguide structures: Influence of the ridge dimension and dielectric capping

Deep‐level defects induced by Ar‐ion beam etching in n‐type AlxGa1‐xAs grown by MBE

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Product

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Deep‐level defects induced by Ar‐ion beam etching in n‐type Al_xGa_1‐xAs grown by MBE