Search
Search titles only
By:
Search titles only
By:
Log in
Register
Search
Search titles only
By:
Search titles only
By:
Menu
Install the app
Install
Forums
New posts
All threads
Latest threads
New posts
Trending threads
Trending
Search forums
What's new
New posts
New ads
New profile posts
Latest activity
Free Ads
Latest reviews
Search ads
Members
Current visitors
New profile posts
Search profile posts
Contact us
Latest ads
NURSING , CAREGIVER , HOTEL & BEAUTY COURSES
IVA Para Medical Campus
Updated:
Today at 9:24 AM
Handmade Character Soft Toys Peppa Pig Family
anil1961
Updated:
Yesterday at 9:58 PM
Ad icon
Video Content Creator
pramukag
Updated:
Sunday at 6:10 AM
Ad icon
QA Engineer Intern
pramukag
Updated:
Sunday at 6:07 AM
Ad icon
Sell your Land, House on idamata.lk for FREE
sajith.xp.pk
Updated:
Jun 25, 2026
Electronics
Vehicles
Property
Search
Reply to thread
Forums
General
ElaKiri Talk!
Nobel Prize in Physics 2025
Get the App
JavaScript is disabled. For a better experience, please enable JavaScript in your browser before proceeding.
You are using an out of date browser. It may not display this or other websites correctly.
You should upgrade or use an
alternative browser
.
Message
<blockquote data-quote="imhotep" data-source="post: 31005090" data-attributes="member: 562115"><p><strong>John Clarke</strong></p><p>University of California, Berkeley, USA</p><p></p><p><strong>Michel H. Devoret</strong></p><p>Yale University, New Haven, CT and</p><p>University of California, Santa Barbara, USA</p><p></p><p><strong>John M. Martinis</strong></p><p>University of California, Santa Barbara, USA</p><p></p><p><em>“for the discovery of macroscopic quantum mechanical tunnelling and energy quantisation in an electric circuit”</em></p><p><em></em></p><p><em>A major question in physics is the maximum size of a system that can demonstrate quantum mechanical effects. This year’s Nobel Prize laureates conducted experiments with an electrical circuit in which they demonstrated both quantum mechanical tunnelling and quantised energy levels in a system big enough to be held in the hand.</em></p><p></p><p>Quantum mechanics allows a particle to move straight through a barrier, using a process called tunnelling. As soon as large numbers of particles are involved, quantum mechanical effects usually become insignificant. The laureates’ experiments demonstrated that quantum mechanical properties can be made concrete on a macroscopic scale.</p><p></p><p>In 1984 and 1985, <strong>John Clarke</strong>, <strong>Michel H. Devoret</strong> and <strong>John M. Martinis</strong> conducted a series of experiments with an electronic circuit built of superconductors, components that can conduct a current with no electrical resistance. In the circuit, the superconducting components were separated by a thin layer of non-conductive material, a setup known as a Josephson junction. By refining and measuring all the various properties of their circuit, they were able to control and explore the phenomena that arose when they passed a current through it. Together, the charged particles moving through the superconductor comprised a system that behaved as if they were a single particle that filled the entire circuit.</p><p></p><p>This macroscopic particle-like system is initially in a state in which current flows without any voltage. The system is trapped in this state, as if behind a barrier that it cannot cross. In the experiment the system shows its quantum character by managing to escape the zero-voltage state through tunnelling. The system’s changed state is detected through the appearance of a voltage.</p><p></p><p>The laureates could also demonstrate that the system behaves in the manner predicted by quantum mechanics – it is quantised, meaning that it only absorbs or emits specific amounts of energy.</p><p></p><p>“It is wonderful to be able to celebrate the way that century-old quantum mechanics continually offers new surprises. It is also enormously useful, as quantum mechanics is the foundation of all digital technology,” says Olle Eriksson, Chair of the Nobel Committee for Physics.</p><p></p><p>The transistors in computer microchips are one example of the established quantum technology that surrounds us. This year’s Nobel Prize in Physics has provided opportunities for developing the next generation of quantum technology, including quantum cryptography, quantum computers, and quantum sensors.</p></blockquote><p></p>
[QUOTE="imhotep, post: 31005090, member: 562115"] [B]John Clarke[/B] University of California, Berkeley, USA [B]Michel H. Devoret[/B] Yale University, New Haven, CT and University of California, Santa Barbara, USA [B]John M. Martinis[/B] University of California, Santa Barbara, USA [I]“for the discovery of macroscopic quantum mechanical tunnelling and energy quantisation in an electric circuit” A major question in physics is the maximum size of a system that can demonstrate quantum mechanical effects. This year’s Nobel Prize laureates conducted experiments with an electrical circuit in which they demonstrated both quantum mechanical tunnelling and quantised energy levels in a system big enough to be held in the hand.[/I] Quantum mechanics allows a particle to move straight through a barrier, using a process called tunnelling. As soon as large numbers of particles are involved, quantum mechanical effects usually become insignificant. The laureates’ experiments demonstrated that quantum mechanical properties can be made concrete on a macroscopic scale. In 1984 and 1985, [B]John Clarke[/B], [B]Michel H. Devoret[/B] and [B]John M. Martinis[/B] conducted a series of experiments with an electronic circuit built of superconductors, components that can conduct a current with no electrical resistance. In the circuit, the superconducting components were separated by a thin layer of non-conductive material, a setup known as a Josephson junction. By refining and measuring all the various properties of their circuit, they were able to control and explore the phenomena that arose when they passed a current through it. Together, the charged particles moving through the superconductor comprised a system that behaved as if they were a single particle that filled the entire circuit. This macroscopic particle-like system is initially in a state in which current flows without any voltage. The system is trapped in this state, as if behind a barrier that it cannot cross. In the experiment the system shows its quantum character by managing to escape the zero-voltage state through tunnelling. The system’s changed state is detected through the appearance of a voltage. The laureates could also demonstrate that the system behaves in the manner predicted by quantum mechanics – it is quantised, meaning that it only absorbs or emits specific amounts of energy. “It is wonderful to be able to celebrate the way that century-old quantum mechanics continually offers new surprises. It is also enormously useful, as quantum mechanics is the foundation of all digital technology,” says Olle Eriksson, Chair of the Nobel Committee for Physics. The transistors in computer microchips are one example of the established quantum technology that surrounds us. This year’s Nobel Prize in Physics has provided opportunities for developing the next generation of quantum technology, including quantum cryptography, quantum computers, and quantum sensors. [/QUOTE]
Insert quotes…
Verification
Nawa warak dahaya keeyada? (Namaya wadi kireema dahaya)
Post reply
Top
Bottom