SiO.sub.2 aerogels containing carbon particles and their preparation

SiO.sub.2 aerogels containing carbon particles are obtainable by heating PA1 a) organically modified SiO.sub.2 aerogels in the presence of at least one pyrolyzable hydrocarbon gas and/or at least one inert gas or PA1 b) organically unmodified SiO.sub.2 aerogels in the presence of at least one pyrolyzable hydrocarbon gas and in the presence or absence of inert gases to 600.degree.-1300.degree. C.

The present invention relates to SiO.sub.2 aerogels containing carbon 
particles and processes for their preparation, in particular to SiO.sub.2 
aerogels which contain carbon particles and are obtainable by thermal 
after-treatment of unmodified or organically modified SiO.sub.2 aerogels 
in a specific gas atmosphere. 
In order to achieve optimum heat insulation properties of SiO.sub.2 
aerogels, the latter must have a high specific absorbance in the infrared 
range. For this purpose, finely divided carbon blacks (predominantly 
crystalline carbon) are, as a rule, introduced into the SiO.sub.2 aerogels 
by adding carbon black during the sol/gel process or by physical admixing 
of carbon black with SiO.sub.2 aerogel powders. 
However, agglomeration of the carbon black particles frequently occurs in 
this procedure, so that both the homogeneous distribution thereof in the 
aerogel and the particle size required for optimum absorbance are not 
ensured. The desired specific absorbance in the infrared range can 
therefore be obtained only to a very limited extent. 
Moreover, the addition of carbon black results in soiling of the production 
plant in important parts so that every changeover to the production of 
non-opacified, transparent SiO.sub.2 aerogel entails very expensive 
cleaning. 
It is an object of the present invention to provide SiO.sub.2 aerogels 
which contain carbon particles and no longer have these disadvantages. 
We have found that this object is achieved, surprisingly, by SiO.sub.2 
aerogels which contain carbon particles and are obtainable by a specific 
thermal treatment of unmodified or organically modified SiO.sub.2 
aerogels. 
The present invention therefore relates to SiO.sub.2 aerogels containing 
carbon particles and obtainable by heating 
a) organically modified SiO.sub.2 aerogels in the presence of at least one 
pyrolyzable hydrocarbon gas and/or at least one inert gas or 
b) organically unmodified SiO.sub.2 aerogels in the presence of at least 
one pyrolyzable hydrocarbon gas and in the presence or absence of inert 
gases 
to 600.degree.-1300.degree. C. 
The present invention also relates to SiO.sub.2 aerogels containing carbon 
particles, having a density of less than 250 kg/m.sup.3 and obtainable by 
heating 
a) organically modified SiO.sub.2 aerogels having a density of less than 
250 kg/m.sup.3 in the presence of at least one pyrolyzable hydrocarbon gas 
and/or at least one inert gas or 
b) organically unmodified SiO.sub.2 aerogels having a density of less than 
250 kg/m.sup.3 in the presence of at least one pyrolyzable hydrocarbon gas 
and in the presence or absence of inert gases 
to 350.degree.-700.degree. C. 
The present invention furthermore relates to a process for the production 
of carbon particles in SiO.sub.2 aerogels, wherein 
a) organically modified SiO.sub.2 aerogels are heated in the presence of at 
least one pyrolyzable hydrocarbon gas and/or at least one inert gas or 
b) organically unmodified SiO.sub.2 aerogels are heated in the presence of 
at least one pyrolyzable hydrocarbon gas and in the presence or absence of 
inert gases 
to 600.degree.-1300.degree. C. 
The present invention furthermore relates to a process for the production 
of carbon particles in SiO.sub.2 aerogels having a density of less than 
250 kg/m.sup.3, which comprises heating to 350.degree.-700.degree. C. 
a) organically modified SiO.sub.2 aerogels having a density of less than 
250 kg/m.sup.3 in the presence of at least one pyrolyzable hydrocarbon gas 
and/or at least one inert gas or 
b) organically unmodified SiO.sub.2 aerogels having a density of less than 
250 kg/m.sup.3 in the presence of at least one pyrolyzable hydrocarbon gas 
and in the presence or absence of inert gases. 
The novel process is also referred to below as pyrolysis. 
The organically modified SiO.sub.2 aerogels used according to the invention 
generally contain organic radicals R directly bonded to silicon atoms or 
bonded via oxygen atoms. Preferred organically modified SiO.sub.2 aerogels 
contain at least some organic radicals R bonded directly to silicon atoms. 
Examples of suitable organic radicals R are alkyl, alkenyl, alkynyl and 
aryl. The organic radical is preferably alkyl or aryl. Particularly 
preferred alkyl radicals are methyl and propyl. A preferably used aryl 
radical is phenyl. 
For the purposes of the present invention, organically modified SiO.sub.2 
aerogels include the SiO.sub.2 aerogels already containing carbon 
particles, as can be obtained by heating 
a) organically modified SiO.sub.2 aerogels in the presence of at least one 
pyrolyzable hydrocarbon gas and/or at least one inert gas or 
b) organically unmodified SiO.sub.2 aerogels in the presence of at least 
one pyrolyzable hydrocarbon gas and in the presence or absence of inert 
gases 
to 600.degree.-1300.degree. C. 
Organically modified SiO.sub.2 aerogels can be prepared, for example, in a 
known manner via the sol-gel process using organo(trimethoxy)silanes 
RSi(OMe).sub.3 having nonhydrolyzable organic radicals R. For 
MeSi(OMe).sub.3, this is already described in Hydrophobic Aerogels from 
Si(OMe).sub.4 /MeSi(OMe).sub.3 Mixtures by F. Schwertfeger, W. Glaubitt 
and V. Schubert, published in Journal of Non-Crystalline Solids, 145 
(1992), 85-89. 
Organo-substituted alkogels can be obtained by base-catalyzed hydrolysis 
and condensation, for example of mixtures of tetramethoxysilane, 
Si(OMe).sub.4, and organo(trimethoxy)silanes, RSi(OMe).sub.3, and the 
corresponding SiO.sub.2 aerogels can be obtained therefrom by subsequent 
super-critical drying, for example with methanol: 
##STR1## 
For example, RSi(OR').sub.3 (R=alkyl, alkenyl, alkynyl or aryl, preferably 
methyl, propyl or phenyl) and Si(OR').sub.4 (R'=alkyl or aryl, preferably 
methyl or ethyl) are mixed in various ratios (x mol of RSi(OR').sub.3 and 
y mol of Si(OR').sub.4). Any ratio of x to y is possible, but the ratio is 
preferably from 0:1 to 2:3 for achieving the desired combination of 
properties. To obtain a predetermined density of the SiO.sub.2 aerogel, 
the alkoxysilanes are dissolved in a specific amount of particular 
alcohols R'OH. The relationship between the desired density d and the 
amount of solvent V required for this purpose (V.sub.MeOH in the case of 
methanol) is: 
##EQU1## 
where .sup.M RSiO.sub.3/2 and .sup.M SiO.sub.2 are the molecular weights 
of the oxidic components obtained from RSi(OR').sub.3 and Si(OR').sub.4, 
respectively. 
In an embodiment of the novel process, (3x+4y) mol of water, in the form of 
an aqueous 0.01 N ammonia solution, is added to the solution. 
After mixing, the batch is allowed to stand in a closed vessel at from 
10.degree. to 60.degree. C. preferably from 20.degree. to 30.degree. C., 
until gelling occurs. 
After the gel point has been reached, the gels are generally aged by 
storage in a closed vessel for from 2 to 20 days at from 10.degree. to 
60.degree. C., preferably for from 5 to 10 days at from 20.degree. to 
30.degree. C. The suitable aging period can be determined by continuously 
determining the H.sub.2 O/R'OH ratio in the gels, this ratio no longer 
changing after the end of the aging processes. 
After aging, the gels are subjected to super-critical drying in a 
conventional manner (cf. for example U.S. Pat. No. 4,667,417). 
Here, a chemical reaction may occur between the solvents used for the 
supercritical drying (for example methanol) and the SiO.sub.2 (aero)gel, 
so that, for example in the case of methanol, 0-methyl groups are formed. 
Alternatively, it is possible to form organically modified SiO.sub.2 
aerogels in which the organic radicals R are bonded to silicon atoms 
exclusively via oxygen atoms, the starting materials used being 
organically unmodified SiO.sub.2 aerogels which have been supercritically 
dried with the aid of suitable organic solvents (for example methanol, 
ethanol, propanol or isopropanol). 
For the purposes of the present invention, organically unmodified SiO.sub.2 
aerogels are SiO.sub.2 aerogels which have been prepared, for example, by 
means of a sol/gel process from aqueous sodium silicate and sulfuric acid, 
washing out the sodium salt, solvent exchange with, for example, carbon 
dioxide and supercritical drying. 
In an embodiment of the invention, the SiO.sub.2 aerogels containing carbon 
particles are obtained by a process in which organically unmodified 
SiO.sub.2 aerogels, as can be prepared by supercritical drying according 
to DE-A-34 29 671, are heated in the presence of at least one pyrolyzable 
hydrocarbon gas and in the presence or absence of inert gases to 
600.degree.-1300.degree. C. 
For this purpose, the SiO.sub.2 aerogels are generally kept in an 
atmosphere containing pyrolyzable hydrocarbon gases for a period of from 1 
to 10, preferably from 3 to 5, hours at from 600.degree. to 1300.degree. 
C. preferably from 700.degree. to 1200.degree. C., particularly preferably 
from 900.degree. to 1000.degree. C. A gentle stream of the pyrolyzable 
hydrocarbon gas is preferably established. For example, a stream of from 
10 to 500 cm.sup.3 /min is set in the case of from 10 to 100 cm.sup.3 of 
aerogel. 
For the purposes of the present invention, pyrolyzable hydrocarbon gases 
are preferably methane, propane or acetylene. A mixture, such as natural 
gas, may also be used. The pyrolyzable gas can, if required, be diluted 
with an inert gas, in particular nitrogen or argon. 
According to the process described above, for example, SiO.sub.2 aerogels 
containing carbon particles and having a carbon content of from 1 to 43% 
by weight are obtained starting from organically unmodified SiO.sub.2 
aerogels, in bead form (particle diameter from 2 to 6 mm) or in powder 
form (particle diameter from 0.1 to 0.3 mm) after thermal treatment for 
from 1 to 10 hours. Such SiO.sub.2 aerogels containing carbon particles 
had a specific absorbance a (in m.sup.2 /kg) of 330 at 2.5 .mu.m, 290 at 
5.0 .mu.m and 280 at 6 .mu.m, for example with a carbon content of 16% by 
weight. 
In a preferred embodiment of the invention, SiO.sub.2 aerogels containing 
carbon particles are obtained by heating organically modified SiO.sub.2 
aerogels in the presence of at least one pyrolyzable hydrocarbon gas 
and/or at least one inert gas to 600.degree.-1300.degree. C. 
For this purpose, the SiO.sub.2 aerogels are kept, for example, at from 
600.degree. to 1300.degree. C. in the atmosphere of a chemically inert 
gas. In a preferred variant of this embodiment, the SiO.sub.2 aerogels are 
heated to 250.degree.-500.degree. C., preferably 350.degree.-450.degree. 
C., in a gentle stream of the inert gas at a heating rate of from 5 to 15, 
preferably from 8 to 10, .degree. C./min For example, a stream of from 10 
to 100 cm.sup.3 /min is established in the case of from 10 to 100 cm.sup.3 
of aerogel. 
Thereafter, the SiO.sub.2 aerogels are further heated to 
800.degree.-1200.degree. C. preferably 950.degree.-1050.degree. C. under a 
stationary inert gas atmosphere at a heating rate of from 0.2 to 10, 
preferably from 0.5 to 2, .degree. C./min. 
Depending on the desired particle size of the carbon particles, ie. a 
specific IR absorbance, the SiO.sub.2 aerogel samples are kept for up to a 
further 15 hours at from 800.degree. to 1200.degree. C. preferably for 
from 4 to 10 hours at from 900.degree. to 1000.degree. C. 
SiO.sub.2 aerogels containing carbon particles and having a density of less 
than 250, preferably less than 200 kg/m.sup.3 are advantageously 
obtainable by heating 
a) organically modified SiO.sub.2 aerogels having a density of less than 
250, preferably less than 200, kg/m.sup.3 in the presence of at least one 
pyrolyzable hydrocarbon gas and/or at least one inert gas or 
b) organically unmodified SiO.sub.2 aerogels having a density of less than 
250, preferably less than 200, kg/m.sup.3 in the presence of at least one 
pyrolyzable hydrocarbon gas and in the presence or absence of inert gases 
to 400.degree.-700.degree. C. preferably 450.degree.-600.degree. C. 
The novel process can be carried out in the conventional pyrolysis 
furnaces, for example quartz tubular furnaces. 
The properties of the SiO.sub.2 aerogels containing carbon particles can be 
varied within wide ranges, for example via the pyrolysis temperature. At 
from 750.degree. to 950.degree. C. for example where R is methyl, carbon 
particles are present in addition to undecomposed methyl groups and 
carbon-containing species having a C:H ratio of less than 3. With 
increasing temperature, the C:H ratio decreases At 1000.degree. C. 
virtually no more hydrogen is present and the carbon is in elemental form. 
During the pyrolysis, the volume of the SiO.sub.2 aerogels changes slightly 
due to shrinkage. Furthermore, as a result of removal of organic 
components, the mass of the samples decreases. This results in a small 
change in the density of the samples. 
However, the volume and density changes are as a rule in a range which is 
not critical for applications. 
The specific surface area of the SiO.sub.2 aerogels generally decreases 
during the pyrolysis (for example at 1000.degree. C.). A holding time at 
1000.degree. C. beyond the time required for complete pyrolysis leads to a 
further reduction in the surface area. In order to obtain a very high 
specific surface area, the pyrolysis time should therefore be as short as 
possible. On the other hand, a longer pyrolysis time permits controlled 
reduction of the specific surface area, which is advantageous with regard 
to a reduction in the moisture absorption. 
The STEM photographs taken of the pyrolyzed SiO.sub.2 aerogels show 
essentially the same characteristic aerogel structure as the nonpyrolyzed 
starting materials. The size of the carbon particles homogeneously 
distributed in the aerogel sample is in the lower nanometer range. The 
aerogel structure is therefore not decisively influenced by the pyrolytic 
production of the carbon particles. 
Raman measurements carried out on individual SiO.sub.2 aerogels show that 
the carbon particles present have both crystalline and noncrystalline 
regions. The proportion of crystalline regions (carbon black) is highest 
in the case of the pyrolysis of phenyl-substituted SiO.sub.2 aerogels. The 
holding time at 1000.degree. C. has no influence on the proportion of 
crystalline carbon. 
Investigations by means of IR spectroscopy show that the specific 
absorbance a in the wavelength range from 2.3 to 10 .mu.m, for example for 
pyrolysis up to 1000.degree. C., is from 10 to 100 m.sup.2 /kg, depending 
on the pyrolyzed organic group. At the same initial concentration of the 
organo-substituted alkoxysilane, the specific absorbance (after pyrolysis) 
increases for R=methyl&lt;propyl &lt;vinyl&lt;&lt;phenyl. 
The specific absorbance can be substantially increased by a longer holding 
time. At 1000.degree. C., for example, a can be increased to about 200 
m.sup.2 /kg at a wavelength of 2.3 .mu.m. 
If already pyrolyzed aerogels are reheated to 600.degree.-1300.degree. C. 
in the presence of a pyrolyzable gas, the specific absorbance a in the 
wavelength range from 2.3 to 10 .mu.m can be increased to at least 800 
m.sup.2 /kg. 
In a particularly preferred embodiment of the invention, organically 
modified SiO.sub.2 aerogels are therefore heated to 
600.degree.-1300.degree. C. in the presence of at least one pyrolyzable 
hydrocarbon gas which can be diluted by inert gases. 
The novel SiO.sub.2 aerogels containing carbon particles and the novel 
process have many advantages. 
The novel SiO.sub.2 aerogels contain particularly homogeneously distributed 
unagglomerated carbon particles having sizes of a few nanometers. 
The desired specific absorbance can be adjusted by optimization of the 
particle size and structure while specifying a specific pyrolysis time and 
temperature and, if required, by the choice of the corresponding organic 
radicals R. 
Moreover, by further pyrolysis in the presence of pyrolyzable gases, it is 
possible in a controlled manner both to incorporate additional carbon 
particles into the SiO.sub.2 aerogels and to increase the particle size, 
with the result that the specific absorbance values are further increased. 
The fact that no substantial structural changes in the SiO.sub.2 aerogels 
used occur as a result of the novel process is particularly advantageous. 
Surprisingly, higher specific absorbance values are achieved with the same 
mass fraction of carbon. 
The novel process also has the advantage that the reaction vessels used in 
the preparation of the aerogels and the autoclave system remain free of 
carbon black.

EXAMPLES 1 TO 9 
Preparation of the organically modified SiO.sub.2 aerogels 
100 ml of organically modified SiO.sub.2 aerogels in which the organic 
radical R on the Si atom was varied were in each case prepared according 
to the following general method. The radicals R used were methyl, vinyl, 
propyl and phenyl. 
RSi(OR').sub.3 (R=methyl, vinyl, propyl, phenyl) and Si(OR').sub.4 
(R'=methyl) were mixed in various ratios (x mol of RSi(OR').sub.3, y mol 
of Si(OR').sub.4) and dissolved in a specific amount of methanol (cf. 
Table 1). 
A calculated amount of aqueous 0.01 N ammonia solution corresponding to 
(3x+4y) mol of water, was added to the solution. After mixing, the batch 
was allowed to stand in a closed vessel at room temperature until gelling 
occurred. 
After the gel point had been reached, the gels were aged by storage in a 
closed vessel for 7 days at 30.degree. C. 
After the aging, the gels were subjected to supercritical drying with 
methanol as described in DE-A-18 11 353. 
Table 1 shows the amounts used for the preparation and the reaction times 
until gelling occurred. 
The organically modified SiO.sub.2 aerogels of Examples 1 to 9 were heated 
to 400.degree. C. at a heating rate of 10.degree. C./min in an argon 
stream (from 50 to 100 cm.sup.3 /min)Heating to 1000.degree. C. (Example 
8: 500.degree. C.) was then carried out at a heating rate of 1.degree. 
C./min in a stationary argon atmosphere. The thermal treatment was 
terminated in Examples 1 to 6 after reaching 1000.degree. C. and in 
Example 8 after reaching 500.degree. C. The SiO.sub.2 aerogel sample was 
kept at 1000.degree. C. in a CH.sub.4 stream of 0.5 cm.sup.3 /min for a 
further 3 hours in Example 7 and for 1 hour in Example 9. 
The organically modified SiO.sub.2 aerogels were characterized before and 
after carrying out the novel process. 
The content of organic carbon which is present in the form of R and RO 
groups was determined in the organically modified SiO.sub.2 aerogels 
before carrying out the novel process but after the supercritical drying 
with methanol. After the novel process had been carried out, the content 
of elemental carbon was determined. The determinations were effected in 
each case by elemental analysis. 
In addition, the shrinkage due to the pyrolysis was determined for the 
SiO.sub.2 aerogel samples. For this purpose, the percentage decrease in 
the diameter of cylindrical SiO.sub.2 aerogel samples was determined. 
The densities (in kg/m.sup.3) and the specific surface area (in m.sup.2 /g, 
measured according to the BET method) were measured for the SiO.sub.2 
aerogel samples before the pyrolysis (after the supercritical drying) and 
after the pyrolysis. 
Furthermore, the specific absorbance (in m.sup.2/kg) at 3, 5 and 10 .mu.m 
was determined by IR spectroscopy for the pyrolyzed SiO.sub.2 aerogel 
samples. 
Data for the preparation and characterization of the organically modified 
SiO.sub.2 aerogels are shown in Table 1 and data for the characterization 
of the pyrolyzed SiO.sub.2 aerogels in Table 2. 
The thermal conductivity .lambda. of the pyrolyzed SiO.sub.2 aerogel 
samples of Examples 8 and 9 was measured in each case by the hot wire 
method. 
In the hot wire method, a thin wire (for example of platinum) is supplied, 
from a certain time, with an electric power which is constant as a 
function of time. This results in heating of the wire, the wire heating up 
more slowly in media having high thermal conductivity than in those having 
a low thermal conductivity. The extent of heating of the wire and hence 
indirectly the thermal conductivity of the medium surrounding the wire can 
then be determined via the resistance of the wire, which increases with 
increasing temperature (cf. H.-P. Ebert, V. Bock, O. Nilsson and J. 
Fricke, The Hot-Wire Method applied to porous materials with low thermal 
conductivity, 13th European Conference on Thermophysical Properties, 
Lisbon, Portugal, August/September, 1993, accepted for publication in High 
Temperatures--High Pressures; and DIN 51046, Part 1). 
By means of the hot wire method at 300 K under air at atmospheric pressure, 
a conductivity of 0.012 W/m K was determined for the sample from Example 8 
and a conductivity of the 0.015 W/m K for the sample from Example 9. 
TABLE 1 
__________________________________________________________________________ 
Preparation and characterization of the organically modified SiO.sub.2 
aerogels 
0.01 N 
Reaction Carbon Specific 
Exam- RSi(OMe).sub.3 
Si(OMe).sub.4 
MeOH 
NH.sub.3 aq. 
time to 
Density 
content 
surface 
ple R g (mmol) 
g (mmol) 
g g gelling, min 
kg/m.sup.3 
mmol/100 g 
area m.sup.2 /g 
__________________________________________________________________________ 
1 -- -- 50.72(333) 
21.14 
23.99 
20 267 444 469 
2 Methyl 
8.99 (66) 
40.19(264) 
21.20 
22.57 
25 256 615 566 
3 Methyl 
18.12(133) 
30.44(200) 
22.44 
21.58 
30 210 818 610 
4 Vinyl 
9.78(66) 
40.19(264) 
22.38 
22.57 
55 267 832 590 
5 Propyl 
10.84(66) 
40.19(264) 
21.24 
22.57 
90 230 885 505 
6 Phenyl 
13.09(66) 
40.19(264) 
20.63 
22.57 
&gt;90 288 1605 450 
7 (Identical to Example 2) 
8 Methyl 
20.44(150) 
91.34(600) 
109.50 
51.30 
90 -- 375 -- 
9 Phenyl 
19.83(100) 
60.88(400) 
148.65 
34.20 
360 -- -- -- 
__________________________________________________________________________ 
TABLE 2 
__________________________________________________________________________ 
Characterization of the novel SiO.sub.2 aerogels 
Specific abosrbance 
Density Carbon content 
Spec. surface 
Shrinkage 
m.sup.2 /kg 
Example 
kg/m.sup.3 
mmol/100 g 
area m.sup.2 /g 
% 3 .mu.m 
5 .mu.m 
10 .mu.m 
__________________________________________________________________________ 
1 281 160 412 5.4 1 1 1 
2 276 216 444 6.6 8 10 100 
3 239 515 394 11.7 12 10 100 
4 395 310 403 37.4 40 20 100 
5 274 750 331 18.1 15 10 100 
6 340 1218 320 14.3 60 40 100 
7 n.d. 2323 487 n.d. 800 
800 
800 
8 170 375 -- -- 5 4 100 
9 178 -- -- 12 -- -- -- 
__________________________________________________________________________ 
n.d. = not determined