Surface modification of metal and metal oxide substrates by organic monolayers
Hubert Mutin ICGM mutin@univ-montp2.fr
Surface modification
Inorganic surface
•metal
•oxide
•hydroxide
•carbonate
•phosphate
•nitride
•sulfide
Coupling Agent:
R
Organic
•alkyl
•functional group
•polymer
•metal complex
•proteine
•enzyme
• DNA
-R
T
Coupling agent
•thiol
•organoalkoxysilane •carboxylic acid •phosphonic acid
stable bonds with both organic and inorganic moieties
R   R   R   R   R R
Route to hybrid materials, complementary to Sol-Gel
monolayer
Surfaces
Composition: silicium, metal (Au, Ti...), oxide, hydroxide, carbonate, phosphate, nitrure, sulfure
Amorphous, microcrystalline, monocrystalline
R R
R R
Flat (Nano)particles Porous
Monolayer or self-assembled monolayer?
Monolayer:
surface modification (chemical bonds with the surface) no lateral interaction between coupling agent molecules low or medium density, disordered
Self-Assembled Monolayer = SAM
surface modification + intermolecular interactions
Usually : long alkyl chains (10 to 20 CH2 groups): intermolecular van der Waals forces between methylene groups: ordered chains, high grafting density (4-4.5 /nm2)
Thiol and disulfide coupling agents
Alkylthiols, dialkyl disulfides
Organic: stable S-C bonds Surfaces:
SAMs on Au(111), Pt, Ag, Cu, Hg, Fe, y-Fe203, GaAs, ZnSe, InP
Coupling: M-S-C bonds
R-S-H + Au°-> R-SAu+ + V2 H2
R-S-S-R + Au°-> 2 R-SAu+
S-H
Deposition of Alkylthiol SAMs on Au
•Preferred crystal face for alkanethiolate SAM preparation Au (111)
- single crystal substrates: evaporation of thin Au films (200-400 nm) on flat supports
(glass or silicon)
• Thiol concentrations: 1-2 mM, most common solvent ethanol.
• Time: a self-assembled monolayer forms very rapidly on the substrate, but it is necessary to use adsorption times of 15 h or more to obtain well-ordered, defect-free SAMs. Multilayers do not form, and adsorption times of two to three days are optimal in forming highest-quality monolayers.
Structure
Figure 9. Hexagonal coverage scheme for alkanethiolates    substrates (showing tilt angles of 12T and 27°, respectively), on Au(l 11). The open circles are gold atoms and the shaded circles are sulfur atoms.
2-D packing Tilt:
•to increase VdW contact alkyl chains of alkanethiol SAMs) surfactants are often tilted
•Depends on the metal (distance between M atoms)
Caracterization of density / ordering in alkyl SAMs
IR :CH stretching vib. very sensitive to packing density and gauche defects as CH2stretching vibration (d) :
2916 or 2917 cm1 for SAMs of exceptional quality or cooled below RT 2918 cm1 : normal value for a high-quality SAM, -2926 cnr1 heavily disordered, "spaghetti-like" SAM.
0.005
0
IRAS spectrum of a hexadecanethiolate SAM.
d+ and d- are the s and as CH2 stretches; r+ and r- s and as CH3 stretches
3050
3000
2950
2900
2850
2800
2750
Wavenumber (cm1)
Mixed SAMs: two-component molecular gradients
Liedberg and Tengvall {LangmuirJlJl (1995), 3821).
Cross-diffusion of two different thiols through an ethanol-soaked polysaccharide gel: formation of a continuous gradient of 10-20 mm length may be formed.
\ X X X
X x
X o o
oo 0
o o
Preparation of two-component alkanethiolate gradients.
(a) The two different thiols, represented by X and
O, are injected into glass filters.
(b) They diffuse slowly through the polysaccharide gel and attach to the gold substrate.
(c) Top view showing the placement of the gold substrate between the filters.
(d) Schematic illustration of a fully assembled gradient.
Post-modification
OSO3H
0
L*^\ HO-
O"
\
/
Epichlorohydrin
(CF3C0)2O
CISO3H
I
OH
R
0 II
O—P—OH
1
OH
POCI3
4
OH
(CH2)3
NH
o o=C
R-N=C=S
\
1.Cg02Clg °~\ O   2. R-NH2 * o
<CH2)3 /
CigH37SiCl3
C1 eH37(CH3)2SiC I3
Q1BH37
C18H37
-O—SI—O-        HaC—SJ~CH3
\ V
0
0
Surface reactions of co-hydroxyalkanethiolate monolayers on Au(lll).
Monolayers on Au nanoparticles
MPCs (monolayer-protected clusters) = 3D analogs of 2D SAMs
Figure 3, Schematics for the capping of a nanopaitkle by a 1 kane thiol molecules {i.e.. the formation of MPCs).
monolayers on spherical nanoparticle substrate surfaces instead of monolayers on flat substrate surfaces
capping agents (citrate ions, thiol ligands) on gold nanoparticle surfaces can be exchanged by thiol ligand
•chemical functionalization of the nanoparticles
• transfer from solvent to solvent, storage in the dried state
• organization (and self-organization) into 2D arrays or 3D networks on solid substrates
Silane coupling agents
R-SiX3   X = CI, OEt... easy nucleophilic attack at Si
Hydrolysis: H20 + Si-X    Si-OH + HX
Heterocondensation:   M-OH + Si-X   Si-O-M + HX Si-O-M bonds M-OH + Si-OH -» Si-O-M + H20
Homocondensation: Si-OH +Si-OH Si-O-Si + H20 Si-O-Si Si-OH + Si-X -> Si-O-Si + HX
Competition heterocondensation / homocondensation
Surface modification by trialkoxysilanes
Competition heterocondensation / homocondensation
Depends on the amount of water (adsorbed, in the solvent...)
R
EtO-Si-OEt OEt
no H20
R
6   OH OHO7 x0 OH
R
EtO-Si-OEt
M   M  M M   M M
only Si-O-M, Partial monolayer
OH OH OHOH OH OH
n
sH20
J_L
M   M  M M   M M
HoO
R       R lj?
o-Si-0—Si-o-Si
6 oh 6 oh6xo
_j_i_i_i   i i
M   M  M M   M M
Si-O-M + Si-O-Si Dense monolayer
R ~   ,R xSi-
HO-Si-0 °^Si
6   OHOHO7 \) OH
J_   _l_ _l__l_ _L_
M  M M   M M
M
VI
few Si-O-M, multilayer
Carboxylic acids
•RCOOH
saturated fatty acids :CnH2n+1COOH
Surfaces:
• oxides (Al203, AgO)
• oxidized metals(Ag, Au...)
• carbonates (CaC03)
Coupling: ionic bonds
Formation of a « surface salt » RC(0)0" M+
Bonding mode: mono- or bidentate
Carboxylic acids
AgO CuO; Al203
Carboxylic acids
Ex.: PP/ CaC03/ stearic acid system
Surface CaC03 not compatible with PP
melt of PP + CaC03: extremely high viscosity, extremely difficult mixing, -> poor dispersion of CaC03 filler
Surface modification of CaC03 by stearic acid (C17H35COOH): —» alkyl chains at the surface of particles
—» hydrophobic particles, good wettability by melt PP, incorporation and dispersion easier Compatibilizer
—» Improved mechanical properties (shock resistance)
Organotitanates
Titanium alcoxides (also Zr, Al), modified by carboxylic acids or chelating groups (p-dicetones, cetoesters, glycols, hydroxyacides, phosphates).
o
o
CH3-(CH2)16-C-Ox /O-C—(CH2)16-CH3
Ti
H    / V H3C—C-0 0-C-(CH2)16-CH3
O O ?H3
II II I
CH3-(CH2)16—C-O^    O-C—C=CH2
Ti
H /\ H3C—C—O     O—C—C=CHo
CH
II
O
CH-
Non reactif (dispersant)
Reactif
• Commercial, goods results with CaC03 or oxide fillers
• 1300 patents + 400 technical articles
• Mecanism? M-OH + Ti-OR -> M-O-Ti ? source of carboxylic acid?
• Real composition and structure ?????
Titanium oxoalcoxydes
Ti(OR)4	
[Ti3O](OR)10	
[Ti7O4](OR)20	(a)                „ (jta.
[Ti10O8](OR)24	
[Ti^O^KOR)^	a. Xv,-M >   '4?/"is f .... V~~L^ "      \         W ,,        It?r. ^C2',
[Ti16016](OR)32	
[Ti^O^KOR)^	
[Ti16016](OR)32	'■7h rl   V         - 1 9
Ti02	
Fig. 1. Formulas of structurally -characterized titanium(IV) polyoxo-alkoxides [TixOy](OR)4x_2y arranged in order of their degrees of condensation relative to Ti(OR)4 and TiOo.
6
[Ti30](OMe)(OiPr)9
Sulfonates coupling agents / SiQ2 H-bonding jacs 1999,121,5961
ocn co +Rh
Ph2P Ph2Px PPh2
H
I
o
H
I
o
'Si02: pretreated at 300°C
'Rh complex: dissolved in CH2CI2
•Washing with CH2CI2no loss of Rh
• Washing with MeOH: Rh complex dissolved
• Catalysis: hydrogenation and hydroformylation of alkenes, recyclable, Rh en solution < 1 ppm
Sulfonates / Si02: FTIR
I-i-1-r
4000     3900     3800     3700     3600     3500     3400 3300
Conditions:
Si02: 370 m2/g
Pellets dried at 300°C/105 mm Hg, 16h
dried Si0o + sulfonate
dried Si02 difference spectrum
•decrease of free OH •increase bonded OH => H-bonding
Wavenumber (cm"1)
c
o-
?FS 0
-s—o
Sulfonates / SiOo H-bonds + electrostatic bonds
Chem. Comm. 2000, 1797
Grafting onto MCM-41
Catalysis: hydrogénation of enamides
[
H    H    H    H H
I      I      I     I I O    O    O   O O J_I_I_I_L
Si    Si   Si   Si 1
R
>=
R'
,C02R N(H)Ac
NaB[C6H3(CF3)2]4
PF3 x e
o:
m© Na
cf3 q -s—o
Characterization 31 P. 19F NMR
Organophosphorus coupling agents
Nucleophilic attack at P: difficult:
R QEt 6NHCI      R 0H
• Hydrolysis of P-OC : harsh conditions r\~L^      15 hrs _ n=o^
°~^OEt 100oC' O-P^OH
• No homocondensation of P-OH: P-OH + P-OH £ P-O-P + H20
Possible coupling agents : organophosphorus acids (or salts)
X R-O-P^OH X
R    OH OH       R-0X OH
phosphonic       phosphinic Mono- or di- esters of
acids
acids phosphoric acid
Phosphonic acids coupling agents
P-C^H^P-OH £ P-O-P + H20   =>no homocondensation
Heterocondensation P-OhUM-OH    P-O-M + HoO
Acids stable in water:
surface modification in water
Great affinity for metal oxides : Ti02, Zr02, Al203, Fe203 etc.
Ex.: metal phosphonates
R R R
\ \ \
Zr;      /Zr^     ^Zr ^Zr O P^u    O p"u    O p"u
\       \ \
R R R
R R R
\ \ \
\ /0/KP /0/KQ /0/KP x
Zr;      ^Zr'     ^Zr ^Zr
O P"u    O P'u 0>p"u
\ \ \
R R R
Growth of C18H37P03H2 SAMs on titanium
in situ multireflexion ATR FTIR
Substrate: 20 nm Ti on a silicon ATR crystal
1 mM C18H37P03H2in CD3CD2OD, 15 °C
VasCHs,		vsCH2
1 week j		
1 day J		
1 y\^J		
1 min r i	i	i
3000      2900 2800 Wavenumber (cm1)
Water contact angle /
12      24 36
Time / h
• No need to control the water content, simple and reproducible!
Surface modification of Ti02 particles
TiO, + PhPO,H
3' '2
H,0
31PMAS-NMR
120°C /
especes greffeejs P-O-P
100°C
Tj(PhP03)2
20°C: no P-O-P =^> monolayer
100°C: no P-O-P, but dissolution/precipitation
F^h F^h F^h
x .cTP9 ^cTP9 /0/PQ ^
Ji ^Ti JTi JTi
0~P'U   0~P'U 0~P'U
\ \ \
Ph Ph Ph
F^h F^h F^h
\ /0"P Q /0"P Q o'pQ
T\        ^Ti        ^Ti ^Ti 0~p'u    0~p'u 0~p'u
\       \ \
Ph Ph Ph
100      50        0        -50     -100       Chem. Mater. 2001, 13,4367-4373
8 (ppm)
170 NMR of phosphonate monolayers
collaboration F. Babonneau, C. Gervais (UPMC) Binding of phosphonic acids to oxide surfaces: evidencing P-O-M bonds
170-enriched C12H25P03H2 monolayer on Ti02
• phosphonic acids 17Q MAS-NMR
i
Chem. Mater. 2008
Surface modification by phosphonate esters
o=
P^OEt
0-H
I
H
/C0Et
T
Ti Ti
l/OH
CHoCIo
Ti02 + PhPO(OEt)2 ——^
40 °C
R
I^OEt
A
or o
J_L
31P MAS-NMR
100     50      0      -50 -100
8 (ppm)
- EtOH
Ti   Ti J   Surface catalyzed condensation
Controlled bifunctionalization
1-step: Orthogonal Self-Assembly (Gardner et al, JACS 1995)
ITO
Au
	1 1	
I		
	Si3N4	
		
		i Fe
		
RP03H2 + RSH
->
MeOH/CHCL
R    R R
R R
HO
1
R
PqOOqOOqQ ^_	__1
1	
	
I Fe	
	
V	
RP03H2/RSH : 0.1 mM in MeOH/CHCI3 (1:3) RCOOH/RSH : 0.1 mM in EtOH/hexane (1:20)
in
Selectivity >60
Hydrolytic stability of M-O-P
Basic conditions : stability of Ti-O-P , Zr-O-P » Ti-O-Si, Si-O-Si
but Si-O-P + H20 —> Si-OH + P-OH
31P MAS NMR
Si02 + C12H25P03H2
MeOH/H20 1~d "
Si02 + C12H25P03H2
Toluene. 1 d
_1_i_I_i_I_i_I_i_I_i_I_i_1_
80   60   40   20    0   -20 -40 5 (ppm)
selective surface modification
Selective surface modification
TiO.
C-12H25
Si02
substrate prepared by microlithography
Repartition of organic groups controlled by the inorganic support
HoO
Chem. Mater. 2004, 16, 5670-5675
100
o c o
o
o
E o
5 10 15 Distance (pm)
Controlled bifunctionalization
2-step
TiO
RP03H2 Me,SiCI
S\0.
H,0
Toluene
R R R • a k a
i     i     i      Me MeBj p    p    p MeN| xMeMes| ^.Me
• patterning substrates made by microlithography
• selective bifunctionalization of mesoporous Si02-Ti02 mixed oxides prepared by sol-gel
Chem. Mater. 2004 16, 5670
Grafting oxide NPs in aqueous colloidal solutions
collaboration J. Oberdisse, C. Genix L2C
Silica colloids: used In ceramics, composite materials, cements, catalysts,
polishing pastes, paper, textile...
Levasil® 200S/30: "cationic silica sol" = alumina-coated silica NPs
oh
Modification of the NPs in the aqueous sol :
©  I Sl°
©
© ©
OPA
>
.o
EPA
o=p:
oh
x)h
o=p:
P R
o
.oh t>h
OPA ; hydrophobic R group DEPA ; hydrophilic R group
Tuning interactions between nanoparticles in aqueous solutions
Grafting oxide NPs in aqueous colloidal solutions
OH
u Í^OH
0=P.
"OH
DEPA
OPA
Zeta potential
Grafting density / P nm
0,3 P/nm2
0,5 P/nm2
3,2 P/nm2
Rapp (DLS)
Grafting density / P nm
• OPA, DEPA: slight decrease of ZP
• OPA: aggregation increases with grafting density ^hydrophobic interactions
Phase transfer of Ti02 particles
• Oxide nanoparticles: cheap, "green" syntheses in aqueous media,
sols stabilized by electrostatic repulsion
• Inks, paints, nanocomposites: need for organosoluble nanoparticles
• Simultaneous grafting / phase transfer (FTIR, NMR) Langmuir 2015, 31,10966-10974
Phase transfer of Ti02 particles
Parameters influencing the transfer
• Alkylphosphonic acids with chain > 5 Carbons
• ca 4-5 P/nm2
• Works even for high sol concentration
Langmuir 2015, 31,10966-10974
Phase transfer of Ti02 particles Transfer of aggregated nanoparticles
Deaggregation during phase transfer / surface modification
R(DLS) organic phase R(DLS) aq
600 -
400 -
200 -
0
pH 2
pH 4
pH 5
600
400
Ol
P
200
0
R(DLS) organic phase R(DLS) aq
0
Na#4content (wt%)
6
Applications
Photovoltaic cells
l~°
TiO I \
Complex absorbs visible light. Injection of      2 -o-p
é" in the conduction band of the metal
hO
/
•Heterogeneous catalysis
Reduction of aromatic ketones
Me^O
H2 40 bars
H20 21h OMe    rdt: 99%
Me. .OH
OMe
0
0-P-(CH2)3<
O
/
0
TiO
r°
K)-P-(CH2)3^
Ir-Cl
■O'
O
Immobilization of Catalyts on Metal Oxides
OEt
Ph2R   /\    Si-OEt
\A/
ř
OEt
©Si02 ©Ti02
í
trans-PdCI2L2.CH2Cl2
40°C
// \ °'OEt
Ph2P—<      V— PN
OEt
= L
31P MAS-NMR
22 i	
PPh2	12
	
33 i	
	
80      40       0 -40
S (ppm)
-80
Modification of Si02 fillers in Water
No change in morphology, 1-4 P/nm2, hydrophobic
Fr. Patent 2005 Rhodia-CNRS
C18H37P03H2 SAMs as boundary layer lubricants
Long alkyl chains :
intermolecular forces between methylene groups formation of Self-Assembled Monolayers
Application: lubrication
Substrates: 20 nm Ti on Si
grafting with C18H37P03H2
in EtOH, 2d.
Friction: stainless steel ball D = 2 mm, 260 HV, normal force up to 60 N
MRS Symp. Proc. 2004
p     p     p     p     p p p'ob o'ob o'&o o'6xo o'ob o'&o
Ti' ti Ti Ti   Ti TiTi' Ti TiTi   Ti TiTi  ti TiTi   Ti Ti
1 m ;
I' rim
30 N
Ti/Si untreated
Contact angle 11° Friction coeff. 0.6
ODPA/Ti/Si
Contact angle 102° Friction coeff. 0.1
Antibacterial Monolayers for Biomaterials
Prevention of orthopedic implant infections:
Current approach: hinder bacterial adhesion and biofilm formation using "thick" antibacterial coatings : cationic polymers, polyelectrolyte multilayers, silver-releasing sol-gel coatings...
Interest of phosphonates:
• high affinity for all these materials
• good thermal and hydrolytic stability
Inorganic implant materials:
• metals, metal oxides, phosphates...
Monolayers ?
steel, Cr/Co or zirconia
Hip prosthesis
Antibacterial monolayers
Proof of principle: silver release
SH
SH SH
AgS AgS
OH OH OH OH l'      1 ^
HO
0 0 0 0 0 OH
1 j_i_i _
AgNO,
0 0 O 0 0 OH
j_i_i_i _
Biofilm assay:
samples immersed 3d at 37 °C in a culture of E. Coll GFP -j
■
=> growth of the biofilm at the air- of liquid interface.
Decrease of ca 97 % of biofilm density
6000
4000-
2000-
C12SH C12S-Ag
Fluorescence microscopy (E. coli gfp)
Immersion 3 days at 37 C
Decrease of 95 % of biofilm density
Bis-phosphonate multilayers
o       o 0H
bis-phosphonic acids (BPA) nfL JpC
HO'  ^(ch2)n OH
Controlled deposition of multilayers
• Ex.: BPA/Zr Mallouket al., JACS 1993
o o
;P-(CH2)n-P-OH O 0NOH
^P-(CH2)n-P-OH
\
o
oh
;p-(ch2)n»p-oh oh
1)ZrOCI2 -*
2) BPA
;p-(ch2)r
;p-(ch2)r
;p-(ch2)r
■p<ox /°;p-(ch2)n-px-oh
Wrc° qnoh
o
o
■pv-o. x°;P-(CH2)n-p'-OH
P<K ,0;P-(CH2)n-P-OH
o
/
Microcontact printing
Chemical patterning of surfaces and high-resolution lithographies
•alkanethiols on gold •stamps made from polydimethylsiloxane (PDMS)
Microcontact printing
3 uni
Scanning electron micrograph of a gold structures on silicon fabricated by |iCP and a subsequent etch. Hydrophobic SAM protects the modified surface from etching
High-resolution |jCP:
(a) SEM of a stamp with 60 nm dots.
(b) gold dots fabricated by printing and etching were slightly broadened due to ink diffusion and substrate roughness.
http://www.zurich.ibm.com/
■
Microcontact printing
Universal Ink for Microcontact Printing
Burdinski et al. Angew. Chem. 2006, 45, 4355 Surfaces routinely used in |jCP: Au, Ag, Cu, Pd, SiOx, AIOx
Patterning of metal as well as metal oxide surfaces with a single ink composition: octadecanethiol (ODT) + octadecylphosponic acid (ODPA) (PDMS stamps)
Conditions optimum: ODT (2 mm) and ODPA (10 mm)
[ODPA] sur le tampon PDMS « [ODPA] dans I'encre (hydrophilie)
Temps de contact: 15 s (Au), 300 s (Al)
XPS:
surAu: 3.6 S/nm2 0.8 P/nm2 surAI:    0 S/nm2 4.6 P/nm2
Microcontact printing
Universal Ink for Microcontact Printing
b) 1.0-,
Concentrations of ODT (a) and ODPA (b) in PDMS stamps after inking as a
function of their concentration in:
• pure ODT or ODPA solutions in ethanol
V: csoln(ODT)=2.0 mm and csoln(ODPA)=10 mm,
□ : csoln(ODT)=0.8 mm and csoln(ODPA)=15 mm).
Microcontact printing
Universal Ink for Microcontact Printing
Optical micrographs of gold (a) and aluminum substrates (b) after |jCP with a solution of ODT (2 mm) and ODPA (10 mm) in ethanol followed by wet chemical etching.
Etching bath:
Al : alkaline hydrogen peroxide Au : alkaline thiosulfate
45
Microcontact printing
Universal Ink for Microcontact Printing
Tapping mode AFM micrographs and height profiles of
gold (b, 10 nm Au) and aluminum substrates (d, 50 nm Al)
patterned by |jCP with mixed ODT/ODPA inks and subsequent wet etching.
Bifunctional coupling agents
OMe Me(X I
MeO'
:si
SH
o
HONi| P.
HO'
(CH2)n-
O
M.OH OH
HS^,nu. \ ^SH
O II
O.
HO'
(CH2)n-
SH
O
HOJI P.
HO'
(CH2)n-
SH
O O HON N M
HO' ^(CH2)i^ vOH
Inorganic-inorganic assemblies, interface modification
Bifunctional coupling agents
Tetraoctylammonium bromide-stabilized gold nanoparticles in toluene of ca. 5-8 nm diameter
+ dilute solution of 1,9-nonanedithiol in toluene (0.5 ml_)
Transmission electron micrographs of solution-stable spherical assemblies formed at a molar ratio of 1,9-nonanedithiol to gold particles of 100.
Bifunctional coupling agents
OMe Me(X I
MeO'
:si
SH
o
HONi| P.
HO'
(CH2)n-
O
M.OH OH
HS^,nu. \ ^SH
O II
O.
HO'
(CH2)n-
SH
O
HOJI P.
HO'
(CH2)n-
SH
O O HON N M
HO' ^(CH2)i^ vOH
Assemblies inorganic-inorganic
Agents de couplage bi-fonctionnels
Tetraoctylammonium bromide-stabilized gold nanoparticles in toluene of ca. 5-8 nm diameter
+ dilute solution of 1,9-nonanedithiol in toluene (0.5 ml_)
Transmission electron micrographs of solution-stable spherical assemblies formed at a molar ratio of 1,9-nonanedithiol to gold particles of 100.
Dielectric / metal interfaces
collaboration Prof. Ramanath RPI Tuning mechanical and thermal properties
MDPA
HO
OH
cm
E 150-
8 100H
c S
o
o o
75 E g3
50-
0
Au/TiO.
Au/MDPA/Ti02
í
0       12       3 4 Interfacial toughness / J m'
Modification of the interface by a MDPA monolayer:
• interfacial toughness: x3
• thermal conductance: x3
Nature Mater. 2013
Dielectric / metal interfaces
Dummy-Si
Epoxy
Ti
_Au
t~.—:—;—;—;—:—:———r
1——
TiO-
SiO,
t t
40 30
- (a)
MDPA-treated
-o
03 o
20 -
10 -
PMDPA= 16.3 N
c
Displacement (a.u.)
S2p
XPS of delaminated surfaces
-//-
_ h ■
Au/MDPA/TiO,
Titania
UUUUUMDPA
Au
As deposited MDPA
Titania
P2p
' i ' ' ' ' i ' ' ' ' i • ' ' '.....yy t   t   ú   t  t.......i   i   ú   t ú
170 165 160 155 140    135 130
Binding energy (eV)
Scission of Au-S bonds
Appl. Phys. Lett 2013
Conclusions Organic monolayers :
Different anchoring groups: SH, COOH, SiCI3, P03H2... =^> complementary
>Modification/functionalization of inorganic surfaces ^Interface modification / assemblies
• organic-inorganic
• inorganic-inorganic