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Surface free energies of hydroxyapatite, fluorapatite and calcium fluoride
Mutrrials Chemistry
and Physics,
SURFACE
FREE
CALCIUM
FLUORIDE
ENERGIES
H.P.
H.J. BUSSCHER,
17 (1987)
OF
553-558
553
FLUORAPATITE
HYDROXYAPATITE,
DE JONG AND
AND
J. ARENDS
Laboratory for Materia Technica, Antonius Deusinglaan 1, 9713 AV Groningen (The Netherlands) Received January 30,
accepted March 12, 1987
1987;
ABSTRACT
Surface free energies of hydroxyapatite, fluorapatite and fluoride have been determined from contact angle calcium and compared with available literature data. measurements Surface free energies Y of the above materials against vacuum are all rather high is the range between 72 and 95 mJ.m-2, of the materials in the whereas surface free energies Y presence of saturated vapor areSFairly low between 28 and 48 mJ.mv2. It is discussed that this difference is due to the from the liquid presence of an adsorbed film originating droplets employed in the measuring procedure. Literature data on the surface free energies of the above materials obtained by independent techniques and theories show an extremely large variation but nevertheless confirm the results on hydroxyapatite and fluorapatite.
INTRODUCTION Surface calcium
interaction growth
free
energies
fluoride [2]
of
biological
of hydroxyapatite, fluorapatite and to
many
tissues
phenomena with
as
e.g.
the
bone
[l] or crystal and are therefore extremely important to determine.
The determination energetic,
relate
ionic
of the
surface
surfaces
free
energy of these highly by classical methods, as summarized
e.g.
by Wu C31 is troublesome. Contact angle measurements, a technique often employed to estimate the surface free energy of low
energetic
in this
respect.
0254-0584/87/$3.50
surfaces 141 have been discarded The main
reason
for not employing
for a long time this
approach
0 ElsevierSequoia/Printed inThe Netherlands
on these surfaces has been the fact that adsorption of liquid or molecules
vapor region
from
droplet or the three phase boundary
yields a large reduction in the surface free energies of materials.
these
the
spreading
This
pressure
reduction,
known
as' the
equilibrium
is frequently neglected in surface free
"e
energy determinations from contact angles [3]. Recently surface
free
contact
angle
caLculationa
be
simultaneously determined from
provided
measurements,
the
proper liquids and
techniques are used [6].
the
it
appropriate
seemed
surface
such
crystals
can
energies
Therefore determine
showed [5] that spreading pressures as well as
we
as
free
energy
to
of
apply this method to
highly
energetic, ionic and calcium fluorapatite
hydroxyapatite,
fluoride.
EXPERIMENTAL Advancing the
sessile
mixtures
type contact angles have been measured at 25°C by drop
and
hydroxyapatite fluoride planes
water, on
II water/n-propanol single
crystalline (Zillerthal), fluorapatite (Durango) and calcium
the
Both
the
basal
as well as the prismatic
apatites have been used, whereas in the case of
fluoride only the < 1 1 1 > planes were measured. Prior
the
carefully and
with
cc-bromonaphthalene
(Harshaw). of
calcium to
technique
contact
angle
polished
in
measurement
the
surfaces
have
been
0.05 pm A1203 slurry in distilled water
after thorough rinsing in water allowed to dry overnight at
25°C in a dust free surrouding. The
surface
measured polar
Yy
tensions
Y1 of the liquids employed have been
with a tensiometer. Subsequently the dispersion Y: and components of Y1 have been calculated from measured
contact angles on paraffin by
cos
8 = -1 + z.(Y; . Yf)S
.
Y-i
assuming that for paraffin Ys = Yz = 25.5 mJ.m-' [73.
(1)
surface
The
energies
free
Y
S
the
of
and their
solids
and polar Yg components have been calculated by YZ square fitting the measured contact angle data to the
dispersion least
geometric mean equation [S]
cos
8
=
-1 + 2.(Yt . Yf)% * Y-t + 2.(YE
.
P4
Y1)
.
Y
-1 1
-
lr,.
Y;l (2)
in
which
is the equilibrium spreading pressure, defined as
xe
[91: “e
=
Ys - Ysv
where
is
Ys
the
solid surface free energy against vacuum and
surface free energy in the presence of is sv saturated vapor. Surface free energies Ys and Y,, have both been the
Y
solid
calculated from the experimental data accounting for
separately
neglecting respectively the spreading pressure term in eqn.
and (2).
RESULTS AND DISCUSSION In
Table
spreading
I surface free energies Ys as well as Ysv and the
pressures
Ile are
summarized,
as
calculated
from
measured contact angles. Whereas the
the
surface
free energies Ys are all fairly high,
surface free energies Ysv are all reasonably low due to the
presence
interesting have
adsorbed
of
to
note
vapor in
molecules
on
the surface. It is
this respect that although Ys and Ysv
been separately calculated, their difference approximately
equals
the calculated spreading pressure i(,, in accordance with
thermodynamic definitions. The reduction in surface free energy observed during contact angle
measurements
mixed
water/n-propanol
surfaces [5].
should be attributed to the adsorption of a film, as recently discussed for polymer
556
-2 I. Surface free energies and spreading pressures [mJ.m ]
Table for
(PAP) and calcium (HAP), fluorapatite (CAF). f denotes the standard deviation obtained for 7
hydroxyapatite
fluoride
independent series of contact angle measurements.
material
Y,”
YE
HAP, basal plane
3814
51f20
89f24
39fll
48f14
HAP, prismatic plane
33fl
47f 9
80f 9
30f 3
45f 5
PAP, basal plane
34fl
38f 6
72f 7
28f 3
40f 5
FAP, prismatic plane
33fl
62.t 9
952 8
48f 7
48.t 3
CAF, plane
34fl
49f 4
83i 4
36f 4
45f 5
The
main
actually water
reason for employing water/n-propanol mixtures is
the
fact
that
n-propanol
and
on
a wide variety of solid substrates
exhibit
similar spreading pressures. By
ellipsometric determination of adsorption isotherms of water and n-propanol
[lOI
for 45
this
yielding
fluoride,
fact
was
spreading
also
established for calcium
pressures Ee of 48 and 53 mJ.m -2
water and n-propanol respectively, comparing well with xe = -2 derived mJ.m from contact angle measurements reported in
this study. Stasczuk
et
al.
1111
discussed
the
reduction of quartz, another highly energetic
surface free energy material
due to the
presence of adsorbed water films and showed that the presence of 2
statistical
dispersion study
monolayers
surface
free
of
water
energy
yields a reduction of the
from 76 to 25 mJ.m-'. In this
we observe a similar reduction of the surface free energy
of ionic crystals (see Table I). Very energy
few
data
exist in the literature on the surface free
of HAP, FAP and CAF. In Table II the few data that could
be collected are summarized. Some
comments
dislocation
core
should
be made on the data in Table II. The
data on hydroxyapatite
are
obtained in vacuum
and might be interpreted as Ys values, whereas in the solubility on HAP adsorbed water layers are undoubtedly experiments present, indicating that results from these methods should be
557
Table
for
values
Literature
II.
the surface free energies Y
[mJ.m -2] of HAP, FAP and CAF2. reference
Y
material
plane
method
HAP
not specified
dislocation
HAP
not specified
solubility data
47f 2
1 21
FAP
basal
slow cleavage
95f25
[I31
FAP
prismatic
slow cleavage
480f30
Cl31
CAF2
slow cleavage
140-510
[14,151
theoretical
540-1019
[16]
1121
100
core data
CAF2
identified
as
Ysv
hydroxyapatite
values.
from
conclusion
that
the
correspond
with
available
theoretically
A
Table
comparison
I
and
results
objections
Table
from be
the results for thus
yields the
contact angle measurements
literature, can
of II
despite
the fact that
raised against employing the
contact angle method on ionic crystals. Derivation
of
surface
free
energies
from
slow cleavage
experiments as done for fluorapatite and calcium fluoride may in principle
only
cleavage
be
planes
carried
and
out
for the real crystallographic
therefore not for the prismatic planes of
fluorapatites.
The result presented in Table II for the prisplane of fluorapatite from Aning et al. [13] is therefore
matic
probably authors plane
erroneously [13].
for
with
those
that
also
fluorapatite presented for
measurements conclusion
high,
Discarding
predominantly literature data.
and comparing the results from Table I in
Table II again yields the conclusion
fluorapatite
are can
as also correctly stated by the the literature data on the prismatic
in be
the
results of the contact angle
correspondence drawn
because
of
with
the
literature. No
on the results for calcium fluoride, the
large
variation
in
reported
CONCLUSION It
can
objections,
be
stated
contact
that,
angle
despite
measurements
possible
theoretical
on ionic crystals can
yield valuable information on their surface free energy and that the
data
obtained are in correspondence with the few available
literature data on this subject.
REFERENCES 1
C.A. van Blitterswijk, J.J. Grote, W. Kuypers, C.J.G. Blokvan Hoek and W.Th. Daems, Biomaterials, 6 (1985) 243.
2
J. Christoffersen and Growth, 49 (1980) 29.
3
s. wu, 1982.
Polymer
4. D.K. Owens 1741.
M.R.
Christoffersen,
J.
Crystal
Interface and Adhesion, Marcel Dekker Inc.
and R.C. Wendt, J. Applied Pal. Sci., 13 (1969)
J. 5. H.J. Busscher, G.A.M. Kip, A. van Silfhout and J. Arends, Colloid Interface Sci., 114 (1986) 307. 6. H.J. Busscher, A.W.J. van Pelt, H.P. de Jong and J. Arends, J. Colloid Interface Sci., 95 (1983) 23. 7
F.M. Fowkes, Industrial and Engineering Chemistry, 56 (1964) 12.
8
S. Wu, J. Adhesion, 5 (1973) 39.
9
to the and D.A. Haydon, An introduction R. Aveyard principles of surface chemistry, Cambridge University Press, 1973.
10
G.A.M. Kip, unpublished data.
11
P. Staszczuk, B. Janszuk Phys., 12 (1985) 469.
12
J. Arends 186.
13
M. Aning. D.D. Welch and B.S.H. Royce, Physics Letters, 37A (1971) 253.
14
V.D. Kusnetsov and P.P. Teterin, Surf. Eng. Sol., (1957) 39.
15
J.J. Gilman, J. Appl. Phys., 31 (1960) 2208.
16
B. Klobe, Handbuch 1933, p. 764..
and
and
E. Chibowski, Mater. Chem.
W.L. Jongebloed, Caries Research, 11 (1977)
der Physlk, Verlag van Julius Springer
and Physics,
SURFACE
FREE
CALCIUM
FLUORIDE
ENERGIES
H.P.
H.J. BUSSCHER,
17 (1987)
OF
553-558
553
FLUORAPATITE
HYDROXYAPATITE,
DE JONG AND
AND
J. ARENDS
Laboratory for Materia Technica, Antonius Deusinglaan 1, 9713 AV Groningen (The Netherlands) Received January 30,
accepted March 12, 1987
1987;
ABSTRACT
Surface free energies of hydroxyapatite, fluorapatite and fluoride have been determined from contact angle calcium and compared with available literature data. measurements Surface free energies Y of the above materials against vacuum are all rather high is the range between 72 and 95 mJ.m-2, of the materials in the whereas surface free energies Y presence of saturated vapor areSFairly low between 28 and 48 mJ.mv2. It is discussed that this difference is due to the from the liquid presence of an adsorbed film originating droplets employed in the measuring procedure. Literature data on the surface free energies of the above materials obtained by independent techniques and theories show an extremely large variation but nevertheless confirm the results on hydroxyapatite and fluorapatite.
INTRODUCTION Surface calcium
interaction growth
free
energies
fluoride [2]
of
biological
of hydroxyapatite, fluorapatite and to
many
tissues
phenomena with
as
e.g.
the
bone
[l] or crystal and are therefore extremely important to determine.
The determination energetic,
relate
ionic
of the
surface
surfaces
free
energy of these highly by classical methods, as summarized
e.g.
by Wu C31 is troublesome. Contact angle measurements, a technique often employed to estimate the surface free energy of low
energetic
in this
respect.
0254-0584/87/$3.50
surfaces 141 have been discarded The main
reason
for not employing
for a long time this
approach
0 ElsevierSequoia/Printed inThe Netherlands
on these surfaces has been the fact that adsorption of liquid or molecules
vapor region
from
droplet or the three phase boundary
yields a large reduction in the surface free energies of materials.
these
the
spreading
This
pressure
reduction,
known
as' the
equilibrium
is frequently neglected in surface free
"e
energy determinations from contact angles [3]. Recently surface
free
contact
angle
caLculationa
be
simultaneously determined from
provided
measurements,
the
proper liquids and
techniques are used [6].
the
it
appropriate
seemed
surface
such
crystals
can
energies
Therefore determine
showed [5] that spreading pressures as well as
we
as
free
energy
to
of
apply this method to
highly
energetic, ionic and calcium fluorapatite
hydroxyapatite,
fluoride.
EXPERIMENTAL Advancing the
sessile
mixtures
type contact angles have been measured at 25°C by drop
and
hydroxyapatite fluoride planes
water, on
II water/n-propanol single
crystalline (Zillerthal), fluorapatite (Durango) and calcium
the
Both
the
basal
as well as the prismatic
apatites have been used, whereas in the case of
fluoride only the < 1 1 1 > planes were measured. Prior
the
carefully and
with
cc-bromonaphthalene
(Harshaw). of
calcium to
technique
contact
angle
polished
in
measurement
the
surfaces
have
been
0.05 pm A1203 slurry in distilled water
after thorough rinsing in water allowed to dry overnight at
25°C in a dust free surrouding. The
surface
measured polar
Yy
tensions
Y1 of the liquids employed have been
with a tensiometer. Subsequently the dispersion Y: and components of Y1 have been calculated from measured
contact angles on paraffin by
cos
8 = -1 + z.(Y; . Yf)S
.
Y-i
assuming that for paraffin Ys = Yz = 25.5 mJ.m-' [73.
(1)
surface
The
energies
free
Y
S
the
of
and their
solids
and polar Yg components have been calculated by YZ square fitting the measured contact angle data to the
dispersion least
geometric mean equation [S]
cos
8
=
-1 + 2.(Yt . Yf)% * Y-t + 2.(YE
.
P4
Y1)
.
Y
-1 1
-
lr,.
Y;l (2)
in
which
is the equilibrium spreading pressure, defined as
xe
[91: “e
=
Ys - Ysv
where
is
Ys
the
solid surface free energy against vacuum and
surface free energy in the presence of is sv saturated vapor. Surface free energies Ys and Y,, have both been the
Y
solid
calculated from the experimental data accounting for
separately
neglecting respectively the spreading pressure term in eqn.
and (2).
RESULTS AND DISCUSSION In
Table
spreading
I surface free energies Ys as well as Ysv and the
pressures
Ile are
summarized,
as
calculated
from
measured contact angles. Whereas the
the
surface
free energies Ys are all fairly high,
surface free energies Ysv are all reasonably low due to the
presence
interesting have
adsorbed
of
to
note
vapor in
molecules
on
the surface. It is
this respect that although Ys and Ysv
been separately calculated, their difference approximately
equals
the calculated spreading pressure i(,, in accordance with
thermodynamic definitions. The reduction in surface free energy observed during contact angle
measurements
mixed
water/n-propanol
surfaces [5].
should be attributed to the adsorption of a film, as recently discussed for polymer
556
-2 I. Surface free energies and spreading pressures [mJ.m ]
Table for
(PAP) and calcium (HAP), fluorapatite (CAF). f denotes the standard deviation obtained for 7
hydroxyapatite
fluoride
independent series of contact angle measurements.
material
Y,”
YE
HAP, basal plane
3814
51f20
89f24
39fll
48f14
HAP, prismatic plane
33fl
47f 9
80f 9
30f 3
45f 5
PAP, basal plane
34fl
38f 6
72f 7
28f 3
40f 5
FAP, prismatic plane
33fl
62.t 9
952 8
48f 7
48.t 3
CAF,
34fl
49f 4
83i 4
36f 4
45f 5
The
main
actually water
reason for employing water/n-propanol mixtures is
the
fact
that
n-propanol
and
on
a wide variety of solid substrates
exhibit
similar spreading pressures. By
ellipsometric determination of adsorption isotherms of water and n-propanol
[lOI
for 45
this
yielding
fluoride,
fact
was
spreading
also
established for calcium
pressures Ee of 48 and 53 mJ.m -2
water and n-propanol respectively, comparing well with xe = -2 derived mJ.m from contact angle measurements reported in
this study. Stasczuk
et
al.
1111
discussed
the
reduction of quartz, another highly energetic
surface free energy material
due to the
presence of adsorbed water films and showed that the presence of 2
statistical
dispersion study
monolayers
surface
free
of
water
energy
yields a reduction of the
from 76 to 25 mJ.m-'. In this
we observe a similar reduction of the surface free energy
of ionic crystals (see Table I). Very energy
few
data
exist in the literature on the surface free
of HAP, FAP and CAF. In Table II the few data that could
be collected are summarized. Some
comments
dislocation
core
should
be made on the data in Table II. The
data on hydroxyapatite
are
obtained in vacuum
and might be interpreted as Ys values, whereas in the solubility on HAP adsorbed water layers are undoubtedly experiments present, indicating that results from these methods should be
557
Table
for
values
Literature
II.
the surface free energies Y
[mJ.m -2] of HAP, FAP and CAF2. reference
Y
material
plane
method
HAP
not specified
dislocation
HAP
not specified
solubility data
47f 2
1 21
FAP
basal
slow cleavage
95f25
[I31
FAP
prismatic
slow cleavage
480f30
Cl31
CAF2
slow cleavage
140-510
[14,151
theoretical
540-1019
[16]
1121
100
core data
CAF2
identified
as
Ysv
hydroxyapatite
values.
from
conclusion
that
the
correspond
with
available
theoretically
A
Table
comparison
I
and
results
objections
Table
from be
the results for thus
yields the
contact angle measurements
literature, can
of II
despite
the fact that
raised against employing the
contact angle method on ionic crystals. Derivation
of
surface
free
energies
from
slow cleavage
experiments as done for fluorapatite and calcium fluoride may in principle
only
cleavage
be
planes
carried
and
out
for the real crystallographic
therefore not for the prismatic planes of
fluorapatites.
The result presented in Table II for the prisplane of fluorapatite from Aning et al. [13] is therefore
matic
probably authors plane
erroneously [13].
for
with
those
that
also
fluorapatite presented for
measurements conclusion
high,
Discarding
predominantly literature data.
and comparing the results from Table I in
Table II again yields the conclusion
fluorapatite
are can
as also correctly stated by the the literature data on the prismatic
in be
the
results of the contact angle
correspondence drawn
because
of
with
the
literature. No
on the results for calcium fluoride, the
large
variation
in
reported
CONCLUSION It
can
objections,
be
stated
contact
that,
angle
despite
measurements
possible
theoretical
on ionic crystals can
yield valuable information on their surface free energy and that the
data
obtained are in correspondence with the few available
literature data on this subject.
REFERENCES 1
C.A. van Blitterswijk, J.J. Grote, W. Kuypers, C.J.G. Blokvan Hoek and W.Th. Daems, Biomaterials, 6 (1985) 243.
2
J. Christoffersen and Growth, 49 (1980) 29.
3
s. wu, 1982.
Polymer
4. D.K. Owens 1741.
M.R.
Christoffersen,
J.
Crystal
Interface and Adhesion, Marcel Dekker Inc.
and R.C. Wendt, J. Applied Pal. Sci., 13 (1969)
J. 5. H.J. Busscher, G.A.M. Kip, A. van Silfhout and J. Arends, Colloid Interface Sci., 114 (1986) 307. 6. H.J. Busscher, A.W.J. van Pelt, H.P. de Jong and J. Arends, J. Colloid Interface Sci., 95 (1983) 23. 7
F.M. Fowkes, Industrial and Engineering Chemistry, 56 (1964) 12.
8
S. Wu, J. Adhesion, 5 (1973) 39.
9
to the and D.A. Haydon, An introduction R. Aveyard principles of surface chemistry, Cambridge University Press, 1973.
10
G.A.M. Kip, unpublished data.
11
P. Staszczuk, B. Janszuk Phys., 12 (1985) 469.
12
J. Arends 186.
13
M. Aning. D.D. Welch and B.S.H. Royce, Physics Letters, 37A (1971) 253.
14
V.D. Kusnetsov and P.P. Teterin, Surf. Eng. Sol., (1957) 39.
15
J.J. Gilman, J. Appl. Phys., 31 (1960) 2208.
16
B. Klobe, Handbuch 1933, p. 764..
and
and
E. Chibowski, Mater. Chem.
W.L. Jongebloed, Caries Research, 11 (1977)
der Physlk, Verlag van Julius Springer