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  <title>Quantum Simulator Could Explain Energy Transport in Biological Systems</title>
  <link>https://www.physics.ucr.edu/news/2018/03/22/quantum-simulator-could-explain-energy-transport-biological-systems</link>
  <description>&lt;span&gt;Quantum Simulator Could Explain Energy Transport in Biological Systems&lt;/span&gt;
&lt;span&gt;&lt;span&gt;Anonymous (not verified)&lt;/span&gt;&lt;/span&gt;
&lt;span&gt;&lt;time datetime="2018-03-22T14:32:15-07:00" title="Thursday, March 22, 2018 - 14:32"&gt;Thu, 03/22/2018 - 14:32&lt;/time&gt;
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            &lt;a href="https://www.physics.ucr.edu/news"&gt;More News&lt;/a&gt;
    
            Iqbal Pittalwala    
            &lt;time datetime="2018-03-22T12:00:00Z"&gt;March 22, 2018&lt;/time&gt;
    
            Riverside, Ca    
            &lt;p&gt;Even powerful supercomputers have difficulty simulating quantum phenomena.&amp;nbsp; But now a UC Berkeley-led research team reports in&amp;nbsp;&lt;em&gt;Physical Review X&lt;/em&gt;, a peer-reviewed open-access journal published by the American Physical Society, on the realization of a quantum simulator (assembly of qubits) that can potentially give new insights into complex biological quantum systems in the future.&lt;/p&gt;

&lt;p&gt;“This is a proof-of-principle experiment which simulates an aspect of a transport phenomenon that occurs in some biological systems,” said team member Börge&amp;nbsp;Hemmerling, an assistant professor of physics and astronomy who joined UCR last year. “In photosynthesis, for example, light excites a molecule and this excitation or energy packet is transported towards a ‘place’ in the plant where it is stored in a more permanent, durable way – it’s as if the plant was charging its batteries. What’s interesting is that this transport happens in the real biological system with almost no losses, and that the environment – in the case of plants other molecules present in leaves – can aid the transport process.”&lt;/p&gt;

&lt;p&gt;The Berkeley simulation demonstrates this aspect of an environment aiding an energy transport process in a simple system. The system consists of two trapped calcium ions; the environment is given by the motion of the ions.&lt;/p&gt;

&lt;p&gt;“We were able to show that the successful transfer of excitation between the ions can be enhanced or suppressed depending on the coupling to the environment,” said&amp;nbsp;Hemmerling, who participated in the research while he was a postdoctoral researcher UC Berkeley. “While our experiment does not yet give new insights into the real biological process, it is a promising first step towards more realistic implementations of such simulations in future experiments.”&lt;/p&gt;

&lt;p&gt;The&amp;nbsp;&lt;a href="https://journals.aps.org/prx/abstract/10.1103/PhysRevX.8.011038" onclick="javascript:_gaq.push(['_trackEvent','outbound-article','http://journals.aps.org/prx/abstract/10.1103/PhysRevX.8.011038']);"&gt;research&lt;/a&gt;&amp;nbsp;was featured on the cover of the January-March 2018 issue of the journal.&lt;/p&gt;

&lt;p&gt;–&lt;em&gt;Iqbal Pittalwala&lt;/em&gt;&lt;/p&gt;
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  <pubDate>Thu, 22 Mar 2018 21:32:15 +0000</pubDate>
    <dc:creator>Anonymous</dc:creator>
    <guid isPermaLink="false">146 at https://www.physics.ucr.edu</guid>
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