Mysteries and Surprises in Quantum Physics

By studying the behaviour of these atoms and photons in this protected environment, the physicists can illustrate fundamental aspects of quantum theory, such as state superpositions, complementarity and decoherence. This research is related to the physics of quantum information, a new domain at the frontier of information science and physics that tries to harness the logic of the quantum world to realise tasks in communication and computing that classical devices cannot achieve.

“During the 20th century, quantum physics has given us new technologies that have changed our lives – for example the computer, the laser and magnetic resonance imaging to name a few,” explained Prof. Haroche. “However, quantum laws have counterintuitive aspects that defy common sense. This has led to a paradox: although we all take advantage of quantum physics, it remains very strange - even some of the scientists that developed the theory, such as Einstein, Schrödinger and de Broglie, were uneasy about its deep meaning,” he said.

Prof. Haroche and his team have recently succeeded in trapping a single photon in a box on the time scale of seconds and have detected this photon many times without destroying it. The researchers have achieved this by sending atoms across the box and measuring the imprint left on the atoms by the photon. This is a new kind of light detection called ‘quantum non-demolition’,” explained Prof. Haroche. “Until now, single photons were always destroyed upon detection.”

The result means that it is now possible repeatedly to extract information from the same photon. This is important because the major part of all information we get from the universe come from light. “Developing a new way of ‘seeing’ could have applications in quantum science,” said Prof. Haroche. “A photon could share its information with an ensemble of atoms to build up an ‘entangled state’ of light or matter”.

Attempting to manipulate and control quantum systems raises important questions about the transition between quantum and classical behaviour. “Fundamentally, the goal is to understand nature better,” explained Prof. Haroche. “Applications, such as quantum communication machines, will certainly come but what they will be useful for is not yet clear. This is why research is so exciting – unpredictable things keep happening all the time.”

Prof. Haroche’s group is currently working with atoms and photons in cavities but related work is being done by other groups on trapped ions and cold atoms in optical potential wells, with superconducting junction or quantum dots in solid state devices. “Although the technologies may differ widely, the quantum and information science concepts used are the same,” he explained. “We are therefore witnessing a kind of unification between different fields of research that is very promising.”

Source: Institute of Physics

Material may help autos turn heat into electricity
Researchers have invented a new material that will make cars even more efficient, by converting heat wasted through engine exhaust into electricity. In the current issue of the journal Science, they describe a material with twice the efficiency of anything currently on the market.
Electron microscopy enters the picometer scale
Jülich scientists have succeeded in precisely measuring atomic spacings down to a few picometres using new methods in ultrahigh-resolution electron microscopy. This makes it possible to find out decisive parameters determining the physical properties of materials directly on an atomic level in a microscope. Knut Urban from Forschungszentrum Jülich, a member of the Helmholtz Association, reports on this in the latest issue (25 July) of the scientific high-impact journal Science.
Improving Quantum Dot Synthesis
Materials researchers at the National Institute of Standards and Technology have developed a simplified, low-cost process for producing high-quality, water-soluble quantum dots for biomedical applications. By using a laboratory microwave reactor to promote the synthesis of the widely used nanomaterials, the recently published NIST process avoids a problematic step in the conventional approach to making quantum dots, resulting in brighter, more stable dots.
Research helps understand factors that influence efficiency of organic-based devices
Organic-based devices, such as organic light-emitting diodes, require a transparent conductive layer with a high work function, meaning it promotes injection of electron holes into an organic layer to produce more light.
Visualizing atomic-scale acoustic wavesin nanostructures
Acoustic waves play many everyday roles - from communication between people to ultrasound imaging. Now the highest frequency acoustic waves in materials, with nearly atomic-scale wavelengths, promise to be useful probes of nanostructures such as LED lights. However, detecting them isn't so easy.
New paper offers insights into 'blinking' phenomena
A new paper by a team of researchers led by University of Notre Dame physicist Bolizsár Jankó provides an overview of research into one of the few remaining unsolved problems of quantum mechanics.
Physicists create millimeter-sized 'Bohr atom'
Nearly a century after Danish physicist Niels Bohr offered his planet-like model of the hydrogen atom, a Rice University-led team of physicists has created giant, millimeter-sized atoms that resemble it more closely than any other experimental realization yet achieved.
Unknown molecule opens the door to quantum computing
The odd behavior of a molecule in an experimental silicon computer chip has led to a discovery that opens the door to quantum computing in semiconductors.

Mysteries and Surprises in Quantum Physics

Related stories:

News discussion: