Electromagnetic Modeling of the Propagation Characteristics of Satellite Communications Through Composite Precipitation Layers


Science and Technology, 7 (2002) 303-310 
© 2002 Sultan Qaboos University 
 

Surface Preparation of InAs (110) Using Atomic 
Hydrogen 

 T.D. Veal*, C.F. McConville* and S.H. Al-Harthi**   

*Department of Physics, University of Warwick, CV4 7AL, United Kingdom,**Department 
of Physics, College of Science, Sultan Qaboos University, P.O.Box 36, Al khod 123, 
Muscat, Sultanate of Oman, **Email: Salim1@squ.edu.om.  

  باستخدام التنظيف الهيدروجيني  InAs)110(تجهيز سطح مادة 

 تيموثي فيل، كريستوفر مكنفيل و سالم بن حمود الحارثي

 خالية من شوائب الجو كالكربون واألكسجين       InAs (110)يختص هذا البحث بدراسة كيفية إنتاج سطوح نظيفة لمادة           :خالصة
 خالية من أي    يلعملية والنظرية توضح أن األسطح الناتجة من التنظيف الهيدروجين        النتائج  ا  . بإستخدام التنظيف الهيدروجيني    

 . تلف في خصائصها اإللكترونية والتركيبية
 

ABSTRACT: Atomic hydrogen cleaning has been used to produce structurally and electronically 
damage-free InAs(110) surfaces.  X-ray photoelectron spectroscopy (XPS) was used to obtain 
chemical composition and chemical state information about the surface, before and after the removal 
of the atmospheric contamination. Low energy electron diffraction (LEED) and high-resolution 
electron-energy-loss spectroscopy (HREELS) were also used, respectively, to determine the surface 
reconstruction and degree of surface ordering, and to probe the adsorbed contaminant vibrational 
modes and the collective excitations of the clean surface. Clean, ordered and stoichiometric  
InAs(110)-(1×1) surfaces were obtained by exposure to thermally generated atomic hydrogen at a 
substrate temperature as low as 400ºC.  Semi-classical dielectric theory analysis of HREEL spectra 
of the phonon and plasmon excitations of the clean surface indicate that no electronic damage or 
dopant passivation were induced by the surface preparation method. 
 
KEYWORDS:   InAs(110), Hydrogen Cleaning, Plasmon Excitations, HREEL, XPS  

1. Introduction 

The preparation of clean, ordered and stoichiometric III-V semiconductor surfaces is generally problematic without the extensive facilities available with molecular beam epitaxy (MBE).  
Even in an MBE-chamber, the thermal desorption of oxides in the presence of an arsenic partial 
pressure to prepare the surface of InAs is made difficult by the need for precise control of substrate 
temperature because the oxide and arsenic desorption temperatures are very close together (Schäfer 
et al 2000). When MBE facilities are unavailable, the standard method of in situ cleaning of polar 
InAs surfaces is cycles of low energy ion bombardment and annealing. However, this has been 
shown to cause severe structural damage, resulting in the introduction of defects, enhanced carrier 
concentrations and reduced mobilities within the outermost 1000 Å of the material (Magnée et al 
1995, Bell et al 1996a, Bell et al 1996b). Traditionally, the non-polar (110) surfaces of III-V 
materials have been produced by cleaving in vacuum, as this is the fracture plane of these zinc-
blende materials. However, from cleave to cleave large variations in the surface step densities 
result.  These steps have been observed using scanning tunnelling microscopy where (111), (112) 
and (110)-type steps have all been identified on InAs(110) (Liang et al 1993).  The consequent 
modification of the surface, where the reactivity is likely to be dominated by the step density 
profile, will result in significant non-uniformity in the surface properties with each cleave.  This is 

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T.D.VEAL, C.F. MCCONVILLE and S.H. AL-HARTHI 

evident from photoemission studies, where the expected flat-band condition, with no electron 
accumulation, is rarely achieved for InAs(110). The surface electronic structure is extremely 
sensitive to the presence of cleave-induced steps, which result in downward band bending and 
accumulation layer formation (Karlsson et al 1998). An alternative surface preparation technique, 
atomic hydrogen cleaning (AHC), offers an effective way of obtaining clean, undamaged 
InAs(110) surfaces with uniform step densities. This method has previously been shown to be an 
efficient, relatively low temperature technique for obtaining clean, ordered and damage-free 
GaAs(001) and InP(001) surfaces (Kikawa et al 1994, Petit and Houzay 1992, Petit and Houzay 
1994, Goto et al 1995). 

AHC of the polar (100) and (111) surfaces of InAs has previously been studied using Auger 
electron spectroscopy (AES), high-resolution electron-energy-loss spectroscopy (HREELS) and 
low energy electron diffraction (LEED) (Bell et al 1997, Bell et al 1998).  Whilst the removal of 
contamination by AHC was confirmed by AES, no chemical state information was available to 
indicate the reaction mechanisms that occur during AHC.  Here, the use of x-ray photoelectron 
spectroscopy (XPS) before and after AHC, with some complementary use of HREELS as an 
adsorbate vibrational spectroscopy, permits the investigation of the processes by which AHC of 
InAs(110) proceeds.  LEED was used to monitor the surface ordering before and after the cleaning 
process.  HREELS was used to study the surface vibrational modes of the contaminants on the as-
loaded surfaces and collective excitations of the clean surface. 

2. Experimental Details 

Samples from S-doped InAs(110) wafers (n ~ 4 × 1018 cm-3) were individually loaded into the 
HREELS spectrometer (base pressure < 5 × 10-10 mbar) without any ex situ treatment.  Molecular 
hydrogen was thermally cracked in an atomic hydrogen source (EPI Europe) as it passed over the 
W-filament held at ~ 2100ºC (as measured by an infrared pyrometer) with an estimated H2 → H* 
conversion efficiency of about 6-7% for the conditions used (Sutoh et al 1995). Hydrogen doses 
were measured in terms of molecular hydrogen exposures in kilo-Langmuirs (kL) (1 kL = 10-3 
torr.s).  During AHC, the chamber pressure was typically 3 × 10-5 mbar.  The distance between the 
sample and the atomic hydrogen source was approximately 5 cm.  Each sample was degassed for 
one hour to 360ºC prior to AHC, and annealed to 400ºC during AHC by a combination of the 
atomic hydrogen source filament and the sample filament mounted behind.  HREEL spectra were 
recorded using a range of incident electron energies between 7 and 100 eV with a resolution of 10 
meV full width at half maximum (FWHM).  XPS spectra were collected to obtain chemical 
composition and chemical state information before and after AHC, using unmonochromated Al Kα 
radiation and a 150º spherical sector analyser, with an overall system resolution of ∼1.4 eV for the 
settings used. 

3.  Results and Discussion 

XPS spectra from the as-loaded InAs(110) surface are shown in Figure 1 (dotted lines). The 
main contribution to the C 1s XPS spectrum indicates the presence of hydrocarbons on the surface.  
The shoulder on the high binding energy side may be due to the presence of alcohols, carbonates 
formed after the adsorption of atmospheric CO2, and bicarbonates (Wolan et al 1997). The 
presence of In-oxide and As2O3 is indicated by reference to the binding energies of peaks in the In 
3d, As 2p and 3d, and O 1s XPS spectra (Moulder et al 1992).  The precise nature of the In-oxide 
could not be identified by XPS because the different oxides are indistinguishable because of the 
small chemical shifts of the In 3d lines - the peak positions are consistent with the presence of 
In2O3, the most common In-oxide, and sub-oxides such as In2O.  As there is no component of the 
As 3d spectrum at ~ 46 eV, the presence of the other common As-oxide, As2O5, above the XPS 
detection limit is ruled out.  This oxide has previously been reported to be unstable in ultra-high 
vacuum, decomposing into As2O3 and oxygen within a few hours of formation (Schäfer et al 2000). 

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SURFACE PREPARATION OF InAn(110) USING ATOMIC HYDROGEN 

280 284 288 528 532 536

O 1sC 1s

As2O3
InAs

(CH)n

Binding Energy  (eV)

40 44 1324 1328

As 2p3/2As 3d As2O3InAs

Binding Energy (eV)

444 448 452 456 460

 as-loaded
 H-cleaned

In 3d
In2O3In2O3InAs InAs

Binding Energy (eV)

Figure 1. In 3d, As 3d, As 2p3/2, C 1s and O 1s XPS spectra from as-loaded InAs(110) (dotted 
lines) and from clean InAs(110) prepared by an AHC dose of 120 kL with a sample temperature of 
400ºC (dashed lines).  All y-axes are in arbitrary units. 

 
An approximate surface composition was determined from the relative intensities of various 

photoelectron peaks by applying the appropriate atomic sensitivity factor (ASF) for each core level.  
Errors in determining the surface atomic composition result from the fact that photoelectron lines 
for the different elements present occur at different binding energies. Consequently, the 
photoelectrons analysed have different kinetic energies and mean free paths. This means that 
information contained in the XPS spectra is integrated over different depths for the different 
elements and makes the assessment of uncertainty in the binding energies difficult. However, from 
straightforwardly applying the ASF values and using the As 3d line for As because its associated 
mean free path is closer to that of the In 3d, O 1s and C 1s photoelectrons than that of the 2p3/2 line, 
the elemental surface composition before cleaning is 47 % O, 37 % C, 9 % In, and 7 % As.  

An estimate of the thickness of the oxide layer was obtained by virtue of the attenuation of the 
substrate signal by the oxide overlayer. The As 3d spectrum is suitable for this analysis as the 
chemical shift between substrate and oxide peaks is large, allowing the substrate signal alone to be 

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T.D.VEAL, C.F. MCCONVILLE and S.H. AL-HARTHI 

examined before and after oxide layer removal. The attenuated signal from the substrate beneath 
the oxide layer Is is given by 

Is = Is0 exp(-z/λ)                     (1) 
  

where Is0 is the unattenuated clean surface signal obtained after AHC, z is the thickness of the oxide 
layer, and λ is the inelastic mean free path of the As 3d photoelectrons 27.5 Å  (Schaefer et al 
1990).  Allowing for the error associated with determining the peak areas, this gives an oxide layer 
thickness of 30 ± 5 Å.  This is qualitatively consistent with the information given by comparing the 
as-loaded spectra of the As 3d and As 2p3/2 photoelectrons and considering their different inelastic 
mean free paths.  The lower kinetic energy (higher binding energy) As 2p3/2 electrons have a mean 
free path of ~ 7.5 Å (Schaefer et al 1990), compared with the ~ 27.5 Å of the higher kinetic energy 
(lower binding energy) As 3d electrons.  Because of the exponential attenuation, over 98 % of each 
signal comes from within four mean free path lengths of the surface. The fact that no As 2p3/2 
signal from the InAs substrate is visible in the as-loaded spectrum indicates that the oxide layer is 
at least 30 Å (4 × 7.5 Å) thick.   

0 100 200 300 400

(a)

(b)

ν(C-H)

δ(C-H)
ν(As-O)

ν(In-O)

Electron Energy Loss (meV)

Figure 2. Specular HREEL spectra, recorded at 15 eV, with an instrumental broadening of 10 meV 
FWHM, from (a) an as-loaded InAs(110) sample; (b) after annealing for one hour at 360ºC and a 
total of 120kL of atomic hydrogen cleaning at a sample temperature of 400ºC.  The dotted line of 
spectrum (b) depicts the experimental points and the solid line is the simulated spectrum calculated 
using semi-classical dielectric theory. 

 
The as-loaded samples gave a very weak and broad specular elastic peak in HREELS, with an 

angular spread of 15º full width at half maximum (FWHM); they exhibited no ordered LEED 
pattern.  Figure 2 (a) shows a specular HREEL spectrum from an as-loaded sample and features a 
peak at 106 meV - almost twice the width of the elastic peak.  This is attributed to a combination of 
In-O and As-O vibrational modes.  These are known to be at ~ 87 and ~ 118 meV respectively 
(Ibach and Mills et al 1982).  However, it is apparent that the broad peak at 106 meV in spectrum 
(a) of Figure 2 cannot be solely due to the combination of two symmetric peaks centred at 87 and 
118 meV.  However, when the character of an intramolecular bond changes, relatively large 
frequency shifts can occur (Ibach and Mills et al 1982).  It is therefore suggested that the origin of 
the low loss energy side of this peak is In-O vibrational modes of several different frequencies in 

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SURFACE PREPARATION OF InAn(110) USING ATOMIC HYDROGEN 

the range 87 to ~ 100 meV resulting from the various intramolecular bonds present in the different 
In-oxides likely to exist in the native oxide, including In2O3 and suboxides such as In2O. The peak 
centred at ~ 170 meV on the HREEL spectrum recorded from the as-loaded InAs (100) surface is 
due to the combined hydrocarbon deformation modes, δ(C-H) (Aquino et al 1995), whilst the peak 
at 360 meV is attributed to the well known hydrocarbon stretching mode, ν(C-H) (Ibach and Mills 
et al 1982). The as-laoded spectrum is quite noisy and has low resolution because of the disordered 
nature of the atmospheric contamination present.  As a result, the presence of alcohols and 
carbonates suggested by the C 1s XPS spectrum cannot be unambiguously confirmed because their 
vibrational modes occur at around the same part of the spectrum as the δ(C-H) modes (Jones et al 
1989). The intensity of all the peaks in the as-loaded spectrum of Figure 2 decreased as the incident 
electron energy was increased, confirming that they are due to vibrational modes and not collective 
excitations. 

A clean surface was obtained after a total of 120 kL of AHC.  The XPS spectra recorded from 
the c

curs by the 
form

As2O3 + 2InAs + 12H* → In2O3 + 4AsH3 ↑, 
 

here H* represents thermally excited hydrogen atoms and ↑ indicates the desorption of the 

In2O3 + 4H* → In2O ↑ + 2H2O ↑. 
 

The clean surface exhibited the clear, sharp (1×1) LEED patterns shown in Figure 3 with the 
recta

lean surface are shown in Figure 1 (dotted lines). As shown in this figure, the C 1s and O 1s 
signals were below the detection limit of XPS. The binding energy of the In 3d lines has shifted 
down by 1 eV, indicative of the removal of In oxide and the presence of InAs at the surface.  The 
As2O3 peaks in the As 3d and As 2p3/2 spectral regions disappeared, with the InAs peak becoming 
stronger in the As 3d spectrum and appearing for the first time in the As 2p3/2 region.  Bearing in 
mind the caveats mentioned earlier with regard to determination of surface atomic composition 
using photoemission results, these XPS spectra suggest that the clean surface consists of 53 % In 
and 47 % As, close to the 1:1 stoichiometry expected for the non-polar (110) surface.  

In the case of GaAs(100), it has been proposed that the removal of As2O3 oc
ation and desorption of AsH3, whilst the oxygen generated in this process reacts with surface 

gallium to form more Ga2O3 (Mikhailov et al 1992).  A similar mechanism is proposed here with 
the formation of more In2O3 which is corroborated by vibrational spectroscopy results (Veal and 
McConville, 2000).  The proposed reaction for As2O3 removal and creation of additional In2O3 is 
 

w
reaction product.  Upon further AHC treatment, it is suggested that the In2O3 is eventually 
removed, by analogy with the case of Ga2O3 (Mikhailov et al 1992, Yamada et al 1993), according 
to the reaction  
 

ngular spacing of diffraction spots characteristic of the (110) surface. Increased surface 
ordering was also apparent from the more intense specular elastic peak in HREELS, with a much 
reduced angular spread (3º FWHM).  An HREEL spectrum recorded from the clean surface is 
shown in Figure 2.  Whilst the clean surface spectrum shown does not extend to the loss energies of 
all the contaminant vibrational modes, it was independently confirmed that their intensities had 
been reduced to below the detection limit.  A series of normalised specular HREEL spectra were 
recorded with a range of incident electron energies from a clean InAs(110) surface prepared by 
annealing at 360ºC followed by a 120 kL dose of AHC with a sample temperature of 400ºC.  The 
peak at ~ 90 meV in all the spectra is due to the conduction-band electron plasmon excitation.  The 
width of this feature decreases at higher incident electron energies, whilst its intensity increases 
relative to the elastic peak.  As the incidence energy is reduced, the plasmon peak becomes more 
asymmetric and less well defined on the high loss energy side; a small shift towards higher loss 
energy also occurs.  The shoulder on the elastic peak at ~ 29 meV is assigned to Fuchs-Kliewer 
surface optical phonon excitations (Mönch et al 1993): this feature does not change in loss energy, 

 307



T.D.VEAL, C.F. MCCONVILLE and S.H. AL-HARTHI 

but its intensity decays rapidly with increasing incidence energy, disappearing completely above 60 
eV.   

 

 
 
Figure 3. (1×1) LEED patterns (left) recorded using beam energies of (a) 31 eV and (b) 49 eV 
from InAs(110) prepared by an AHC dose of 120 kL with a sample temperature of 400ºC.  The 
inverted images (centre) and schematic diagrams (right) are also shown. The diffraction spots 
obscured by the electron gun are shown unshaded in the schematic pattern. 
 

The HREEL spectra of the atomic hydrogen cleaned surface were analysed using the semi-
classical dielectric theory of HREELS (Lambin et al 1990). The plasma dielectric function was 
based on the hydrodynamic model, with the plasma frequencies, plasmon lifetimes, and spatial 
dispersion coefficients as parameters (Bell et al 1996b).  A three-layer model was used to simulate 
the experimental spectra across the entire incident-electron energy range, consisting of a plasmon-
free surface "dead" layer, accumulation layer, and a semi-infinite bulk.  Below the 35 Å dead layer, 
the 55 Å accumulation layer had a carrier concentration of 6.7 × 1018 cm-3, above a semi-infinite 
bulk with a carrier concentration of 3.9 × 1018 cm-3: that is, unchanged from the nominal bulk 
doping value given by the sample manufacturer.  The band bending was estimated to be 115 meV, 
with a triangular potential well width of 140 Å, giving a surface charge density of 6.3 ± 2.0 × 1011 
cm-2.  This is in agreement with the values of 1011-1012 cm-2 found on other faces of InAs (Olsson 
et al 1996, Bell et al 1997) and on hydrogen terminated InAs(110) (Chen et al 1989). 

The spatial dispersion coefficient for the simulations was calculated using the Thomas-Fermi 
model (TFM), giving a value of 0.43 × 106 ms-1, which successfully reproduced the observed 
plasmon peak dispersion in the experimental spectra.  This indicates that the hydrogen cleaning 
treatment does not cause subsurface damage: for ion bombarded and annealed samples spatial 
dispersion coefficients are significantly lower than those predicted by the TFM because of 
additional defect scattering (Bell et al 1996b). The carrier mobility of AHC InAs(110) deduced 
from the plasmon lifetimes used in the simulations is five times higher than for samples from the 
same wafer subjected to grazing incidence 500eV IBA (Veal and McConville 2001), providing 
further evidence in favour of AHC as a surface preparation technique. 

An accumulation layer has also been observed on InAs(110) cleavage surfaces after good 
mirror-like cleavages, as seen by visual inspection and LEED (Karlsson et al 1998). Whilst an 
"ideal" cleavage gives a flat band condition on the InAs(110) surface with no electron 
accumulation, the surface electronic structure is extremely sensitive to the presence of 
contamination and defects, resulting in downward band bending and accumulation layer formation. 

 308



SURFACE PREPARATION OF InAn(110) USING ATOMIC HYDROGEN 

From cleave to cleave large changes in step densities, and consequently adsorption properties and 
defect densities occur, resulting in significant variations in surface properties. Atomic hydrogen 
cleaning is an effective alternative method of obtaining clean, undamaged InAs(110) surfaces prior 
to further in situ processing. 

In conclusion, it has been demonstrated that clean, ordered InAs(110) surfaces can be obtained 
by exposing the atmospherically contaminated substrates to atomic hydrogen at 400ºC with a 
molecular hydrogen dose of 120 kL. During atomic hydrogen cleaning, the As2O3, In-oxides and 
hydrocarbons are removed completely. Furthermore, this process produces no detectable damage:  
dielectric theory simulations of the plasmon excitations in the HREEL spectra indicate carrier 
mobilities and spatial dispersion coefficients significantly higher than those of samples prepared by 
IBA; and below the accumulation layer the carrier concentration was found to be that of the 
nominal S-doping. 

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Received   25 December 2001   
Accepted   29 December 2002      
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 310


	Surface Preparation of InAs (110) Using Atomic Hydrogen
	T.D. Veal*, C.F. McConville* and S.H. Al-Harthi**
	
	
	
	
	*Department of Physics, University of Warwick, CV4 7AL, United Kingdom,**Department of Physics, College of Science, Sultan Qaboos University, P.O.Box 36, Al khod 123, Muscat, Sultanate of Oman, **Email: Salim1@squ.edu.om.





	Experimental Details
	Results and Discussion