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Preparation of Clean III-V Semiconductor Surfaces for
NEA PhotocathodesYun Sun1, 2, Zhi Liu3, Francisco Machuca3, Piero Pianetta1
and William E. Spicer1
1 Stanford Synchrotron Radiation Lab, Stanford, CA
2 Department of Chemistry, Stanford University, CA
3 Center for Integrated Systems, Stanford University, CA
Work is funded by Intevac, and is carried out at Stanford Synchrotron Radiation Lab (Department of Energy, Office of Basic Energy Sciences)
Importance of InP Cleaning
• InP(100) based Negative Electron Affinity (NEA) photocathode– Surface cleanness critical for the
performance– Chemical cleaning of InP(100) not well
understood
• Other applications– Critical for MBE and CVD growth, etc.
Analysis Technique:Photoelectron Spectroscopy using
Synchrotron Radiation
• A systematic study by SR-PES– hv: 60 - 600eV, P2p, In4d, F1s, VB
– High resolution --> resolve chemical shift
– Short escape depth(~5Å) --> high surface sensitivity
• A controlled etching environment– Ar purged glove bag around load lock
1. 2.
3.
4.
5.
6.
7.
1. Argon/Nitrogen purged glove box
2. Connected Loadlock
3. XYZ-theta Stage with integrated heater in UHV chamber
4. Beam line (Radiation)
5. Hemispherical Energy Analyzer, Energy Resolution, 0.2eV.
6. Leak Valve for Gases
7. Alkali Metal doser
4.
Typical One Step Cleaning Methods
• Hydrogen Peroxide based solutions*:
– H2SO4 : H2O2 : H2O (4:1:100)
– H2SO4 : H2O2 : H2O (4:1:1)
– NH3 : H2O2 : H2O (10:2:100)
– etc.
• Other: Br-CH3OH, HF, etc.
*H2SO4: 98%, H2O2 30%, NH3 30%
One Step Chemical Cleaning
CHEMICALETCHING
VACUUMANNEAL
INERT(Ar) ATMOSPHERE UHV
• Not effective for InP(100) !
H2SO4 : H2O2 : H2O (4:1:100)
One Step Chemical Cleaning H2SO4 : H2O2 : H2O (4:1:100)
K. E. / eV
Inte
nsi
ty
Oxide~0.5ML
K. E. / eV
Oxide
Inte
nsi
ty52504846444236343230282624
Etched
Etch +360oC
Etched
Etch +360oC
P2phv = 165eV
In4dhv = 70eV
One Step Chemical Cleaning
In oxide
Kinetic Energy / eV
10
8
6
4
2
0
x10
3
5250484644
In4d for bulk InP
Inte
nsit
y
In4dhv = 70eV
525048464442
In in InP
One Step Chemical Cleaning Not Enough
• Surface is left with oxide, which can not be removed completely by vacuum heating
• Add another step to remove the oxide– 36% HCl : H2O (1:3)
– HF (1%)
Two Step Chemical Cleaning
CHEMICALETCHING
VACUUMANNEAL
OXIDE REMOVAL
INERT(Ar) ATMOSPHERE UHV
H2SO4:H2O2:H2O4:1:100
HCl(36%): H2O 1:3HF 1%
HCl Solution as Second Step
Surface is Hydrophobic
HCl Clean
Inte
nsi
ty /
a.u
.
3634323028262422
K.E. / eV
P2phv = 165eV
r.t.
230oC
290oC
330oC
360oC
Inte
ns
ity
/ a
.u.
3634323028262422
Kinetic Energy / eV
P2phv = 165eV
"Elemental" P
Inte
ns
ity
/ a
.u.
3634323028262422
Kinetic Energy / eV
P2phv = 165eV
oxide gone
r.t.
360oC
P in InP
~0.42ML
HCl Clean
Inte
ns
ity
/ a
.u.
525048464442
K.E. / eV
In4dhv = 70eV
r.t.
230oC
290oC
330oC
360oC
new component
Inte
ns
ity
525048464442Kinetic Energy (eV)
In4dhv = 70 eV
Surface Shift
Inte
nsit
y
525048464442Kinetic Energy (eV)
In4dhv = 70eV
r.t.
360oC
One Step
Two Step
+330 oC
K.E. / eV K.E. / eV
One Step
Two Step
+330 oC< 0.1ML
C1s O1s
565452504846 70686664626058
C1s And O1s Spectra at different stagesIn
ten
sity
Inte
nsi
ty
hv = 340eV hv = 600eV
HF Solution as Second Step
Surface is Hydrophilic
HF CleanIn
tens
ity
36343230282624Kinetic Energy (eV)
r.t.
180oC
230oC
360oC
P2phv = 165eV
oxide
Inte
nsity
525048464442Kinetic Energy (eV)
In4dhv = 70eV
r.t.
120oC
180oC
230oC
360oC
In-F
In4d Fit after HF CleanIn
ten
sit
y
525048464442Kinetic Energy (eV)
In4dhv = 70eV
In-F
Inte
ns
ity
525048464442Kinetic Energy (eV)
In4dhv = 70eV
In-F
Inte
nsit
y
525048464442Kinetic Energy (eV)
In4dhv = 70eV
In-F
Inte
ns
ity
525048464442Kinetic Energy (eV)
In4dhv = 70eV
In-O
SurfaceShift
r.t. 120oC.
180oC. 230oC.
In in InP
HF CleanIn
ten
sity
158156154152150
Kinetic Energy ( eV)
F1shv = 800eV
r.t.
180oC
230oC
Inte
nsity
65605550Kinetic Energy (eV)
VBhv = 70eV
r.t.
120oC
180oC
230oC
360oC
F2p
In-F and F Coverage
Temperature(oC)
In-F Coverage(monolayer)
F coverage(monolayer)
r.t. (~27oC) 0.44 0.48
120oC 0.38 --
180oC 0.30 0.31
230oC 0 0
HCl Clean v.s. HF Clean
HCl Clean HF Clean
Surface Property Hydrophobic Hydrophilic
SurfaceTermination
“Elemental” P~0.42ML
F terminate In sites~0.48ML
Vacuum Anneal “Elemental” Premoval at 330oC
F removal at 230oC
Clean Resultafter Heating
Clean, no oxide Almost clean,~0.05ML oxide
GaAs(100) Cleaning recipe
H2SO4:H2O2:H2O *
4:1:100
+
Vacuum annealing at 500C
*H2SO4 98%; H2O2 30%; NH3 30%
After chemical clean
Peak found on sample after chemical clean
Inte
nsi
ty [A
rbitr
ary
Un
its]
166164162160158156
Kinetic Energy
Ga(As) Bulk
Elemental As
Oxide
As 3d
Inte
nsi
ty [A
rbitr
ary
Un
its]
188186184182180178
X-Axis Value
Ga 3d
(Ga)As Bulk
GaOx
After thermal annealing
Peak found on sample after annealing
Inte
nsi
ty [A
rbitr
ary
Un
its]
166164162160158156
Kinetic Energy
Ga(As) Bulk
As 3d
Inte
nsi
ty [A
rbitr
ary
Un
its]
188186184182180178
Kinetic Energy
(Ga)As Bulk
Ga 3d
C 1s and O 1s
Inte
nsity
[Arb
itrar
y U
nits
]
7570656055
Kinetic Energy
O 1s
Sample as received
After chemical Clean
After annealing
Kinetic Energy
Inte
nsity
[Arb
itrar
y U
nits
]
6058565452504846
C 1s
After annealing
After chemical clean
Sample as received
Result of chemical cleaning
GaAs(100) InP(100)
Step 1:H2SO4:H2O2:H2O4:1:100
> 2ML Elemental As < 0.2ML suboxide > 0.5ML C
~0.5ML oxide > 0.5ML C
Step2:HCl: H2O1:3
--------------------- ~0.4ML
Elemental P ~0.2ML C
Vacuum Anneal(30 min)
No oxide< 0.1ML C
No oxide< 0.1ML C
Chemical Cleaning (Ex situ)
• Optimize the sulfuric acid cleaning used for other III-V’s for GaN --> 4:1 H2SO4:H2O2 (~90oC)
Annealing Ambient (In situ)
• Testing the use of ammonia back pressure in comparison tovacuum annealing --> Anneal in vacuum better
Annealing Temperature (In situ)
• Find an effective temperature --> 700oC
9.
45x103
40
35
30
25
20
Nor
mal
ized
Inte
nsity
[cou
nts/
sec]
60565248
Kinetic Energy (eV)
Carbon 1shv=340eV
After H2SO4
/H2O2
700C Vacuum Anneal
No Clean
6x103
5
4
3N
orm
aliz
ed In
tens
ity [c
ount
s/se
c]
7570656055
Kinetic Energy (eV)
Oxygen 1shv=600eV
After H2SO4
/H2O2
700C VacuumAnneal
No Clean
10.
35x103
30
25
20
15
10
5
Nor
mal
ized
Inte
nsity
[cou
nts/
sec]
188186184182180178
Kinetic Energy (eV)
Gallium 3dhv=200eV
After H2SO4
/H2O2
700C Vacuum Anneal
No Clean
25x103
20
15
10N
orm
aliz
ed In
tens
ity [c
ount
s/se
c]
64605652
Kinetic Energy (eV)
Nitrogen 1shv=460eV
AfterH2SO4
/H2O2
700CVacuumAnneal
No Clean
H2SO4/H2O2
H
C
H H
C
H H H
CGaN GaN
O
C
O O
C
O O O
C
Anneal
GaN
• Carbons 1s spectroscopy shows a conversion of hydrocarbons to more volatile oxides of carbon.
• Carbon contamination reduced to 1% and Oxygen 8% of a monolayer.
12.
I. A sulfuric acid/hydrogen peroxide treatment followed by a vacuum anneal at 700C reduces carbon and oxygen concentrations to a few percent of a monolayer.
II. An ammonia annealing ambient is worse than a vacuum ambient for the thermal desorption of carbon and oxygen at temperatures at or below 740C.
III. The chemical state is predominantly a volatile oxide of carbon.
IV. We have a reproducible and clean GaN surface for our photocathode research achieved by a non-destructive sulfuric acid cleaning technique.
13.
More on GaN
• Quantum yield• 20-30 % by Cs• 40-50 % by Cs+O
• Works in Transmission Mode with Sapphire/AlN/GaN
• Looking for collaboration: [email protected]
• Electron Gun Test Column• Current density and brightness measurement• Energy spread measurement
VB after HCl Cleanof InP(100)
Inte
ns
ity
/ a
.u.
686664626058565452
K.E. / eV
VBhv = 70eV
r.t.
230oC
290oC
330oC
360oC
Valence Band after Two Step cleaning and Annealing for InP(100)
Inte
ns
ity
686664626058565452 Kinetic Energy / eV
VBhv = 70eV
O2p
One Step
Two Step
Two Step
+330oC
Surface Etching(2)
H2O2
In POO
OHO
3/2
InP
H+
In3+
POOH
OHOH
SO42-H+ H+ H+H2O2
Grow oxide:
InP + H2O2 + H+ In(HPO4)3/2
Etch oxide:In(HPO4)3/2 + H+ In3+ + H3PO4
In POO
OHO
3/2
Oxide Removal
In POO
OHO
3/2
InP
H+
In3+
POOH
OHOH
SO42-
H+
Oxide Removal:In(HPO4)3/2 + H+ In3+ + H3PO4
H+
H+
InP
P
Elemental P Generation:H3PO4 + InP + H+ In3+ + P
In3+
Hydrophilic Surface after HF Clean
In In In In In In In
F F F F F F F
H H H H O O O OH H H H
HydrogenBonds
InP
GaAs(100) Valence Band
Inte
nsi
ty [A
rbitr
ary
Un
its]
8075706560
Kinetic Energy
VB
After annealing
After chemical clean
