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You may have noticed
that I'm wearing two different shoes.
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It probably looks funny --
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it definitely feels funny --
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but I wanted to make a point.
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Let's say my left shoe corresponds
to a sustainable footprint,
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meaning we humans consume
less natural resources
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than our planet can regenerate,
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and emit less carbon dioxide
than our forests and oceans can reabsorb.
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That's a stable and healthy condition.
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Today's situation
is more [like] my other shoe.
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It's way oversized.
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At the second of August in 2017,
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we had already consumed all resources
our planet can regenerate this year.
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This is like spending all your money
until the 18th of a month
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and then needing a credit
from the bank for the rest of the time.
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For sure, you can do this
for some months in a row,
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but if you don't change your behavior,
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sooner or later,
you will run into big problems.
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We all know the devastating effects
of this excessive exploitation:
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global warming,
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rising of the sea levels,
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melting of the glaciers and polar ice,
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increasingly extreme
climate patterns and more.
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The enormity of this problem
really frustrates me.
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What frustrates me even more
is that there are solutions to this,
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but we keep doing things
like we always did.
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Today I want to share with you
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how a new solar technology can contribute
to a sustainable future of buildings.
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Buildings consume about 40 percent
of our total energy demand,
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so tackling this consumption
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would significantly reduce
our climate emissions.
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A building designed
along sustainable principles
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can produce all the power
it needs by itself.
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To achieve this,
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you first have to reduce
the consumption as much as possible,
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by using well-insulated walls
or windows, for instance.
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These technologies
are commercially available.
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Then you need energy
for warm water and heating.
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You can get this
in a renewable way from the sun
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through solar-thermal installations
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or from the ground and air,
with heat pumps.
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All of these technologies are available.
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Then you are left
with the need for electricity.
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In principle, there are several ways
to get renewable electricity,
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but how many buildings do you know
which have a windmill on the roof,
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or a water power plant in the garden?
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Probably not so many, because usually,
it doesn't make sense.
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But the sun provides abundant energy
to our roofs and facades.
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The potential to harvest this energy
at our buildings' surfaces is enormous.
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Let's take Europe as an example.
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If you would utilize all areas
which have a nice orientation to the sun
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and they're not overly shaded,
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the power generated by photovoltaics
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would correspond to about 30 percent
of our total energy demand.
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But today's photovoltaics
have some issues.
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They do offer a good
cost-performance ratio,
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but they aren't really flexible
in terms of their design,
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and this makes aesthetics a challenge.
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People often imagine pictures like this
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when thinking about
solar cells on buildings.
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This may work for solar farms,
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but when you think of buildings,
of streets, of architecture,
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aesthetics does matter.
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This is the reason why we don't see
many solar cells on buildings today.
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They just don't match.
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Our team is working on a totally
different solar-cell technology,
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which is called
organic photovoltaics or OPV.
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The term organic describes
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that the material used
for light absorption and charge transport
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are mainly based on the element carbon,
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and not on metals.
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We utilize the mixture of a polymer
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which is set up by different
repeating units,
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like the pearls in a pearl chain,
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and a small molecule
which has the shape of a football
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and is called fullerene.
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These two compounds are mixed
and dissolved to become an ink.
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And like ink,
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they can be printed with simple
printing techniques like slot-die coating
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in a continuous roll-to-roll process
on flexible substrates.
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The resulting thin layer
is the active layer,
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absorbing the energy of the sun.
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This active layer is extremely effective.
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You only need a layer thickness
of 0.2 micrometers
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to absorb the energy of the sun.
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This is 100 times thinner
than a human hair.
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To give you another example,
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take one kilogram of the basic polymer
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and use it to formulate the active ink.
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With this amount of ink,
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you can print a solar cell
the size of a complete football field.
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So OPV is extremely material efficient,
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which I think is a crucial thing
when talking about sustainability.
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After the printing process,
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you can have a solar module
which could look like this ...
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It looks a bit like a plastic foil,
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and actually has many of its features.
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It's lightweight ...
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it's bendable ...
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and it's semitransparent.
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But it can harvest the energy
of the sun outdoors
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and also of this indoor light,
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as you can see with this small,
illuminated LED.
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You can use it in its plastic form
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and take advantage of its low weight
and its bendability.
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The first is important when thinking
about buildings in warmer regions.
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Here, the roofs are not designed
to bear additionally heavy loads.
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They aren't designed
for snow in winter, for instance,
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so heavy silicon solar cells
cannot be used for light harvesting,
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but these lightweight solar foils
are very well suited.
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The bendability is important
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if you want to combine the solar cell
with membrane architecture.
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Imagine the sails
of the Sydney Opera as power plants.
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Alternatively, you can
combine the solar foils
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with conventional construction
materials like glass.
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Many glass facade elements
contain a foil anyway,
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to create laminated safety glass.
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It's not a big deal to add
a second foil in the production process,
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but then the facade element
contains the solar cell
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and can produce electricity.
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Besides looking nice,
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these integrated solar cells come along
with two more important benefits.
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Do you remember the solar cell
attached to a roof I showed before?
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In this case, we install the roof first,
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and as a second layer, the solar cell.
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This is adding on the installation costs.
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In the case of integrated solar cells,
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at the site of construction,
only one element is installed,
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being at the same time
the envelope of the building
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and the solar cell.
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Besides saving on the installation costs,
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this also saves resources,
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because the two functions
are combined into one element.
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Earlier, I've talked about optics.
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I really like this solar panel --
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maybe you have different taste
or different design needs ...
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No problem.
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With the printing process,
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the solar cell can change
its shape and design very easily.
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This will give the flexibility
to architects,
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to planners and building owners,
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to integrate this electricity-producing
technology as they wish.
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I want to stress that this is not
just happening in the labs.
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It will take seven more years
to get to mass adoption,
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but we are at the edge
of commercialization,
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meaning there are several companies
out there with production lines.
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They are scaling up their capacities,
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and so are we, with the inks.
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(Shoe drops)
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This smaller footprint
is much more comfortable.
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(Laughter)
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It is the right size, the right scale.
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We have to come back to the right scale
when it comes to energy consumption.
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And making buildings carbon-neutral
is an important part here.
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In Europe,
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we have the goal to decarbonize
our building stock until 2050.
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I hope organic photovoltaics
will be a big part of this.
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Here are a couple of examples.
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This is the first commercial installation
of fully printed organic solar cells.
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"Commercial" means that the solar cells
were printed on industrial equipment.
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The so-called "solar trees"
were part of the German pavilion
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at the World Expo in Milan in 2015.
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They provided shading during the day
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and electricity
for the lighting in the evening.
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You may wonder why this hexagonal shape
was chosen for the solar cells.
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Easy answer:
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the architects wanted to have
a specific shading pattern on the floor
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and asked for it,
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and then it was printed as requested.
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Being far from a real product,
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this free-form installation hooked
the imagination of the visiting architects
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much more than we expected.
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This other application
is closer to the projects
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and applications we are targeting.
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In an office building
in São Paulo, Brazil,
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semitransparent OPV panels
are integrated into the glass facade,
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serving different needs.
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First, they provided shading
for the meeting rooms behind.
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Second, the logo of the company
is displayed in an innovative way.
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And of course, electricity is produced,
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reducing the energy footprint
of the building.
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This is pointing towards a future
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where buildings are no longer
energy consumers,
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but energy providers.
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I want to see solar cells
seamlessly integrated
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into our building shells
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to be both resource-efficient
and a pleasure to look at.
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For roofs, silicon solar cells
will often continue to be a good solution.
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But to exploit the potential
of all facades and other areas,
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such as semitransparent areas,
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curved surfaces and shadings,
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I believe organic photovoltaics
can offer a significant contribution,
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and they can be made in any form
architects and planners will want them to.
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Thank you.
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(Applause)
closed TED
