<div dir="ltr"><br>
<p style="margin-bottom:0cm" align="JUSTIFY"><font face="Arial, serif"><font size="2"><span lang="en-US"><u>Title:</u></span></font></font><span lang="en-US"><br></span><font face="Calibri, serif"><span lang="en-US"><b>Units
of electricity: their realization and their role in the </b></span></font><font face="Calibri, serif"><span lang="en-US"><i><b>New
SI</b></i></span></font></p>
<p style="margin-bottom:0cm" align="JUSTIFY"><span lang="en-US"><br></span><font face="Calibri, serif"><span lang="en-US"><u>Abstract:</u></span></font><span lang="en-US">
<br></span><font face="Calibri, serif"><span lang="en-US">Quantum
Standards allow to reproduce the key units of electricity with a
precision exceeding that of any classical method by orders of
magnitude. These effects, the Josephson and the quantum Hall effect,
expose the normally unobservable quantum nature of a solid state
system in a measurement of macroscopic observables, voltage in case
of the Josephson- and resistance in case of the quantum Hall effect.
For the scheduled revision of the SI, the availability of precise
links between the macroscopic and the quantum world has been an
important trigger, even more so as this allows to also reproduce the
unit of mass, kilogram. However, the linking quantity between
electrical and mechanical units is the unit of electrical current,
ampere, which ironically is most precisely represented only
indirectly via voltage and capacitance or resistance. Single electron
transport (SET) allows the obvious and conceptually simplest
representation of a current according to the relation </span></font><font face="Calibri, serif"><span lang="en-US"><i>I
= ef</i></span></font><font face="Calibri, serif"><span lang="en-US">,
although it does not constitute a macroscopic quantum effect in a
strict sense.</span></font></p>
<p style="margin-bottom:0cm" align="JUSTIFY"><font face="Calibri, serif"><span lang="en-US">After
a brief overview of the history of electrical units I will summarize
the basic physics and applications of the two macroscopic quantum
effects. The main part of the talk will highlight the recent
developments in the field of SET and will introduce the concept of
error accounting as a way to deal with the shortcomings of SET
devices operated at high drive frequencies </span></font><font face="Calibri, serif"><span lang="en-US"><i>f.</i></span></font><font face="Calibri, serif"><span lang="en-US">
The talk will close with an outlook on the scheduled redefinition of
the SI.</span></font></p>
<p style="margin-bottom:0cm" lang="en-US"><br>
</p>
<p style="margin-bottom:0cm"><font face="Arial, serif"><font size="2"><span lang="en-US"><u>Oraror:</u></span></font></font></p>
<p style="margin-bottom:0cm;line-height:100%"><span lang="en-US">Dr.
</span><a href="mailto:franz.ahlers@ptb.de"><font color="#00000a"><span lang="en-US"><span style="text-decoration:none">Franz
J. Ahlers</span></span></font></a><span lang="en-US"><br>Head of
Department </span><span lang="en-US"><br></span><span lang="en-US">"Electrical
Quantum Metrology" </span>
</p>
<p style="margin-bottom:0cm"><a href="http://www.ptb.de/index.html"><font color="#00000a"><span lang="en-US"><span style="text-decoration:none">PTB</span></span></font></a><span lang="en-US">
- Braunschweig<br></span><br>
</p>
<p style="margin-bottom:0cm"><font face="Calibri, serif"><u>Lugar:</u></font><font face="Calibri, serif">
Auditorio – INTI – PTM</font></p>
<p style="margin-bottom:0cm"><font face="Calibri, serif"><u>Fecha:</u></font><font face="Calibri, serif">
22 de septiembre de 2015</font></p>
<p style="margin-bottom:0cm"><a name="_GoBack"></a><font face="Calibri, serif"><u>Hora:</u></font><font face="Calibri, serif">
14:00 h.</font></p>
<p style="margin-bottom:0cm">
</p>
<p style="margin-bottom:0cm;line-height:100%"><br><br>
</p>
</div>