Local view for "http://purl.org/linkedpolitics/eu/plenary/2006-09-28-Speech-4-013"

Predicate	Value (sorted: default)
rdf:type	lpv_eu:Speech2
dcterms:Date	"2006-09-28"^^xsd:date2
dcterms:Is Part Of	lp_eu:Nanosciences and nanotechnology (debate)2
dcterms:Language	"pl"^^xsd:language2
lpv:document identification number	"en.20060928.4.4-013"2
lpv:hasSubsequent	lp_eu:2006-09-28-Speech-4-0142
lpv:speaker	lp:Adam Gierek2
lpv:spokenAs	member; PES (2004-07-20--2009-07-13)3 member; Delegation to the EU-Kazakhstan, EU-Kyrgyzstan and EU-Uzbekistan Parliamentary Cooperation Committees, and for relations with Tajikistan, Turkmenistan and Mongolia (2004-09-15--2007-03-14)3 unknown; Unia Pracy (2004-07-20--2009-07-13)3 member; ITRE (2004-07-21--2007-01-14)3 substitute; Delegation to the ACP-EU Joint Parliamentary Assembly (2004-09-15--2009-07-13)3 substitute; CULT (2004-07-21--2007-01-14)3
lpv:translated text	". Mr President, nanoscience deals with phenomena in solid state material at nano level, namely at the scale of 10-9 of a metre. Nanotechnology is based on this research. It is a particularly promising area of technology and represents a potentially positive trend that may dramatically increase the likelihood of progress in many areas of our lives. Amongst others, the automotive and aviation industries could benefit. One of these benefits could be the manufacture of smooth abrasion-proof coatings containing nano particles. There could also be benefits for our health, in the form of medicinal products or cosmetics. In addition, there may be useful spin-offs for the energy sector, in the form of fuel cells or nano-porous hydrogen absorbers and efficient solar batteries. I could also mention ICT technologies exploiting optical and spin states that facilitate further compression of information to be read with blue lasers, and to biotechnology, including DNA research and bioinformatic systems. To these examples one could add sensory or construction materials such as nano-composites or fibres and fabrics whose surfaces are activated by electron compounds. At the same time, unfortunately, permanent damage to the environment may be caused, and the atmosphere may be polluted by the long term presence of aerosol gases that are difficult to monitor. There are two kinds of nanotechnology. The first is known as ‘top down’ technology. Amongst other things it involves the transition from the macro to the nano state, for instance by the grinding of powders, and the development and activation of their surfaces through increased potential. Nano-diamond coating materials are one example of such technology. The second group is known as ‘bottom up’ technology and allows the molecular level to be set. The creation of highly integrated spintronic devices is one example of this. Unfortunately, we have few technologies available that use tunnel microscopy or self-organising phenomena. Biological information systems form part of this group. In conclusion, it should be stated that scienctific policy in the field of nanoscience and nanotechnology should first take account of the fact that, as it stands, the development of ‘top down’ technology in the European Union allows for the creation of at least a few and perhaps more than a dozen technological platforms. Secondly, ‘bottom up’ technology requires further intensive cutting edge research in the area of basic science. And thirdly, a method of researching current pollution levels should be devised as a mater of urgency. I am referring to the current pollution of the atmosphere with nano particles that is not a result of nano technology. This is something more than PM 2.5, which passes easily into our bodies through cell membranes and whose catalytic action can be harmful to health. Who knows, perhaps the cancer epidemic may be linked to the permanent presence of nano-aerosols in our environment. It is a presence that is difficult to define, may be growing and has a range of sources."@en1

Named graphs describing this resource:

The resource appears as object in 2 triples

Context graph