Electrical isolation of <i>p</i>-type GaAs layers by ion irradiation

Boudinov, H.; Coelho, Artur Vicente Pfeifer; Souza, J. P. de

doi:10.1063/1.1469693

Cited by 13 publications

(14 citation statements)

References 14 publications

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“…The sheet resistance reaches a narrow plateau when the concentration of deep levels is of the same magnitude as the free hole concentration, and is determined by the sheet resistance of the underlying SI GaAs substrate. 1,2,[7][8][9][10]15,16 Any further increase in dose beyond this plateau results in the monotonic decrease in R s ͑closed circles͒ because of hopping conduction of holes between closely spaced defect potential wells. 18 Following Ref.…”

Section: Methodsmentioning

confidence: 99%

“…This is because the vacancies are precursors for the creation of antisite defects. The choice of the total number of replacements stems partially from the recent discussion of Boudinov et al 16 that the defect responsible for the isolation in p-type GaAs is the double-donor arsenic-antisite, As Ga , and the results discussed below. By including the data point for 0.1 MeV H ions in Fig.…”

Section: A Effect Of Ion Speciesmentioning

confidence: 99%

“…14 -16 In some investigations the conductive p-type layers were formed in semiinsulating GaAs substrates by C or Mg ion implantation followed by annealing to activate the dopant atoms and to remove implantation-induced damage. 15,16 Since ion implan-tation produces a nonuniform doping profile, 15,16 and because practical devices are manufactured by epitaxial growth, it may be more reasonable to investigate implant isolation processes in uniformly doped p-type epilayers. 14 The results reported in Refs.…”

Section: Introductionmentioning

confidence: 99%

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Implant isolation of Zn-doped GaAs epilayers: Effects of ion species, doping concentration, and implantation temperature

Deenapanray

Gao

Jagadish

2003

Journal of Applied Physics

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The electrical isolation of Zn-doped GaAs layers grown by metalorganic chemical vapor deposition was studied using H, Li, C, and O ion implantation. The ion mass did not play a significant role in the stability of isolation, and a similar activation energy of ϳ(0.63Ϯ0.03 eV) was obtained for isolation using either H or O ions. Furthermore, the isolation was stable against isochronal annealing up to 550°C as long as the ion dose was 2-3.5 times the threshold dose for complete isolation, D th , for the respective ion species. By studying the thermal stability and the temperature dependence of isolation, we have demonstrated the various stages leading to the production of stable isolation with the increasing dose of 2 MeV C ions. For ion doses less than 0.5D th , point defects which are stable below 250°C are responsible for the degradation of hole mobility and hole trapping. The stability of isolation is increased to ϳ400°C for a dose D th due to the creation of defect pairs. Furthermore, the hopping conduction mechanism is already present in the damaged epilayer implanted to D th . Higher order defect clusters or complexes, such as the arsenic antisite, As Ga , are responsible for the thermal stability of implantation isolation at 550°C. The substrate temperature ͑Ϫ196 -200°C͒ does not have an effect on the isolation process further revealing that the stability of isolation is related to defect clusters and not point-like defects. An average number of eight carbon ions with energy of 2 MeV are required to compensate 100 holes, which provides a general guideline for choosing the ion dose required for the isolation of a GaAs layer doped with a known Zn concentration. A discussion of the results on the implantation isolation of p-GaAs previously reported in the literature is also included.

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Section: Methodsmentioning

confidence: 99%

Section: A Effect Of Ion Speciesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Implant isolation of Zn-doped GaAs epilayers: Effects of ion species, doping concentration, and implantation temperature

Deenapanray

Gao

Jagadish

2003

Journal of Applied Physics

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“…Going from the recoil stop to the eletric conductivity it must be taken into account that the resistivity increases strongly non-linearly with the defect distribution, as discussed before, thus giving a strongly non-linear dependence of etching rate and proton fluence. The experimental values of the correlation between defect concentration and resistivity measured by Boudinov et al [20] may be directly mapped to the values shown in Fig. 2 by taking into account the material's original resistivity and the proton fluence, thus yielding conductivity distributions as shown in Fig.…”

Section: Conductivity Mapsmentioning

confidence: 99%

“…Many studies have been carried out in order to understand the nature of such defects leading to insulating GaAs and their influence on the electrical properties of irradiated GaAs substrates [8], [14], [16]- [19]. The decrease in conductivity, and in our particular electrochemical etching case the decrease in hole conduction, has been shown to be due to trapping of holes at specific trap centers [18], [20]. Such traps are created due to nuclear energy loss and it is thus obvious to relate the experimental defect production rate to the one calculated with e. g. SRIM [21], as shown in the past.…”

Section: Introductionmentioning

confidence: 99%

Modeling Electrochemical Etching of Proton Irradiated p-GaAs for the Design of MEMS Building Blocks

Koppe

Rothfuchs

Schulte-Borchers

et al. 2014

J. Microelectromech. Syst.

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We model the electrochemical etching rates of p-type GaAs after proton irradiation using a finite element simulation with input from Monte Carlo simulations of the recoil distribution together with defect to conductivity mapping of implantation isolation data taken from literature. The simulations will allow for the design of advanced microelectromechanical systems through proton beam writing and subsequent electrochemical etching using multiple ion fluences as the novel technique for three-dimensional microstructuring. [2013-0356] Index Terms-Proton beam writing, finite elements, GaAs, electrochemical etching, MEMS. 1057-7157

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The Baylis—Hillman Reaction with Chiral α‐Amino Aldehydes under Racemization‐Free Conditions.

et al. 2006

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Electrical isolation of p-type GaAs layers by ion irradiation

Cited by 13 publications

References 14 publications

Implant isolation of Zn-doped GaAs epilayers: Effects of ion species, doping concentration, and implantation temperature

Implant isolation of Zn-doped GaAs epilayers: Effects of ion species, doping concentration, and implantation temperature

Modeling Electrochemical Etching of Proton Irradiated p-GaAs for the Design of MEMS Building Blocks

The Baylis—Hillman Reaction with Chiral α‐Amino Aldehydes under Racemization‐Free Conditions.

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