PRESS-NEWS.org - Press Release Distribution
PRESS RELEASES DISTRIBUTION

Ultra-short X-ray pulses explore the nano world

Characterization of X-ray flashes open new perspectives in X-ray science

Ultra-short X-ray pulses explore the nano world
2014-11-24
(Press-News.org) This news release is available in German.

X-ray flashes are a unique scientific tool. They are generated by accelerating electrons to very high energy levels in kilometer-long vacuum tubes, so-called linear accelerators, and then deflecting them with specially arranged magnets. In the process the particles emit X-ray radiation that is amplified until an ultra-short and intensive X-ray flash is released.

Researchers use these X-ray flashes to resolve structures as small as one ten billionth of a meter (0.1 nanometer) in size. That is roughly the diameter of a hydrogen atom. In this way, biomolecules, for example, can be imaged at extremely high resolution, providing new insight into the nano cosmos of nature.

Using two quickly sequenced flashes the researchers can even obtain information on structural changes during reactions. The first laser flash triggers a reaction while the second measures structural changes during the reaction. For this it is essential to know the precise duration and temporal intensity distribution of the X-ray flashes. However, hitherto it has not been possible to measure the ultra-short pulses directly.

Researchers at the Technische Universität München (TUM), the Hamburg Center for Free-Electron Laser Science (CFEL) and the Max Planck Institute of Quantum Optics (MPQ) in Garching, in collaboration with other colleagues, have now developed just such a methodology. The respective experiments were done at the SLAC National Accelerator Laboratory in California (USA) by a team headed by Professor Reinhard Kienberger, Dr. Wolfram Helml (TUM) and Dr. Andreas Maier (CFEL).

Streaking spectroscopy characterizes X-ray pulses

The scientists determined the duration of the X-ray flashes by modifying a process originally developed to measure ultra-short flashes of light. The physicists directed the X-ray flashes into a vacuum chamber filled with a few atoms of an inert gas. There they superimposed the flashes with 2.4 micrometer wavelength pulses of infrared light.

When the X-ray flashes hit a gas atom they knock electrons out of the innermost shell, setting them free. After being liberated the electrons are accelerated or decelerated by the electrical field of the infrared light pulse. The change in an electron's velocity is a function of when the light intercepts the electron, and thus of the electrical field strength at the moment of ionization.

Since electrons are set free during the full duration of an X-ray flash, electrons emitted at different points in time "feel" different field strengths of the periodically oscillating infrared light. As a result they are accelerated at varying rates. The physicists can then calculate the duration of the original X-ray flash from the different arrival times of the electrons in a detector.

Attosecond X-ray flashes

Using this approach, the researchers determined that the average pulse duration doesn't exceed four and a half femtoseconds - a femtosecond is a millionth of a billionth of a second (10-15 seconds). In addition, the researchers obtained insight into the structure of the X-ray flashes.

A characteristic of the intense X-ray flashes generated in free-electron lasers is their randomly changing pulse form. A typical X-ray pulse comprises multiple contiguous shorter "X-ray spikes." The number and intensity of these spikes varies from one shot to the next.

For the first time ever, the researchers managed to measure these ultra-short sub-peaks directly and confirm predictions that the individual flashes last only around 800 attoseconds - an attosecond is a billionth of a billionth of a second (10-18 seconds). The new methodology allows the detailed, direct temporal measurement of X-ray pulses and augments methodologies for determining pulse shape and length indirectly from the structure of the electron packets used to generate the flashes.

New fields of application

The enhanced X-ray pulse measurement technology may also find application at the new Center for Advanced Laser Applications (CALA) at the Garching campus. Researchers there are working on, among other things, generating even shorter X-ray pulses using high-energy lasers. Pulses with a duration of only a few attoseconds, would allow researchers to take "snapshots" of even faster processes in nature, like the movement of electrons around atomic nuclei.

However, X-ray flashes provide not only basic research with new perspectives. Medicine could also profit from the technology. "Ultra-short laser-like X-ray pluses serve not only the investigation of the fastest physical processes at the core of matter, but could, because of their extremely high intensity, also be used to destroy tumors following X-ray diagnosis," explains Reinhard Kienberger, professor for laser and X-ray physics at TU München and leader of the research consortium.

INFORMATION:

The research was funded by the German Research Foundation (Excellence Cluster Munich - Center for Advanced Photonics, MAP), the Bavaria California Technology Center (BaCaTec), the International Max Planck Research School on Advanced Photon Science (IMPRS), a Marie Curie International Outgoing Fellowship, the US Department of Energy, the National Science Foundation (USA), the Science Foundation Ireland (SFI) and the European Research Council (ERC Starting Grant). CFEL is a collaboration facility of the German Electron Synchrotron (DESY), the University of Hamburg and the Max Planck Society. CALA is a joint research facility of Technische Universität München and Ludwig-Maximilians-Universität München.

Publication:

W. Helml, A. R. Maier, W. Schweinberger, I. Grguraš, P. Radcliffe, G. Doumy, C. Roedig, J. Gagnon, M. Messerschmidt, S. Schorb, C. Bostedt, F. Grüner, L. F. DiMauro, D. Cubaynes, J. D. Bozek, Th. Tschentscher, J. T. Costello, M. Meyer, R. Coffee, S. Düsterer, A. L. Cavalieri & R. Kienberger Measuring the temporal structure of few-femtosecond FEL X-ray pulses directly in the time domain Nature Photonics online, 24. November 2014, Doi: 10.1038/NPHOTON.2014.278


[Attachments] See images for this press release:
Ultra-short X-ray pulses explore the nano world

ELSE PRESS RELEASES FROM THIS DATE:

Pain and itch in a dish

Pain and itch in a dish
2014-11-24
LA JOLLA, CA--November 24, 2014--A team led by scientists from The Scripps Research Institute (TSRI) has found a simple method to convert human skin cells into the specialized neurons that detect pain, itch, touch and other bodily sensations. These neurons are also affected by spinal cord injury and involved in Friedreich's ataxia, a devastating and currently incurable neurodegenerative disease that largely strikes children. The discovery allows this broad class of human neurons and their sensory mechanisms to be studied relatively easily in the laboratory. The "induced ...

Scientists identify bone cells that could help children who need corrective facial surgery

2014-11-24
ANN ARBOR--Our bones are smart. Bones know that by adolescence it's time to stop growing longer and stronger, and from that point on bones keep their shape by healing injuries. This question of why bones grow longer and stronger in children, but stay static in adults--yet retain the ability to heal themselves, has long perplexed scientists in the bone regeneration field. But researchers from the University of Michigan, Kyoto University and Harvard University believe they may have unearthed a big piece of this puzzle. The team discovered that a certain subset of cartilage-making ...

Drugs to block angiogenesis could provide new treatment for TB

Drugs to block angiogenesis could provide new treatment for TB
2014-11-24
VIDEO: When zebrafish are infected with bright blue Mycobacterium marinum, bright red immune cells quickly surround the bacteria to form tightly organized nuggets called granulomas (vessels green, bacteria blue, immune cells... Click here for more information. DURHAM, N.C. -- The body responds to tuberculosis infection by locking the bacterial offenders into tiny clusters of immune cells called granulomas, which are a hallmark of the disease. This containment strategy succeeds ...

Research reveals how our bodies keep unwelcome visitors out of cell nuclei

Research reveals how our bodies keep unwelcome visitors out of cell nuclei
2014-11-24
The structure of pores found in cell nuclei has been uncovered by a UCL-led team of scientists, revealing how they selectively block certain molecules from entering, protecting genetic material and normal cell functions. The discovery could lead to the development of new drugs against viruses that target the cell nucleus and new ways of delivering gene therapies, say the scientists behind the study. At the heart of every cell in our body is a cell nucleus, a dense structure that contains our DNA. For a cell to function normally, it needs to surround its nucleus with a ...

Underwater robot sheds new light on Antarctic sea ice

Underwater robot sheds new light on Antarctic sea ice
2014-11-24
The first detailed, high-resolution 3-D maps of Antarctic sea ice have been developed using an underwater robot. Scientists from the UK, USA and Australia say the new technology provides accurate ice thickness measurements from areas that were previously too difficult to access. The results, published this week in the journal Nature Geoscience (Monday 24 November 2014), step up the pace of research in the polar regions aimed at understanding the dramatic sea ice changes in the context of climate change. Scientists use a range of technologies and techniques to measure ...

New research discovers gene that reduces risk of stroke

2014-11-24
Scientists have discovered a gene that protects people against one of the major causes of stroke in young and middle-aged adults and could hold the key to new treatments. Researchers from Royal Holloway, University of London, together with an international team from across the United States and Europe, have found that people with a specific variant of a gene, known as PHACTR1, are at reduced risk of suffering cervical artery dissection, which is caused by a tear in an artery that leads to the brain. The new discovery, published in the journal Nature Genetics, could ...

Magnetic fields and lasers elicit graphene secret

Magnetic fields and lasers elicit graphene secret
2014-11-24
Scientists at the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) have studied the dynamics of electrons from the "wonder material" graphene in a magnetic field for the first time. This led to the discovery of a seemingly paradoxical phenomenon in the material. Its understanding could make a new type of laser possible in the future. Together with researchers from Berlin, France, the Czech Republic and the United States, the scientists precisely described their observations in a model and have now published their findings in the scientific journal Nature Physics. Graphene ...

Excessive contact between cellular organelles disrupts metabolism in obesity

2014-11-24
Boston, MA - Researchers at Harvard School of Public Health (HSPH) have found a novel mechanism causing type 2 diabetes that could be targeted to prevent or treat the disease. The research highlights a previously unrecognized molecular pathway that contributes to the malfunction of liver cells in obesity, leading to insulin resistance and diabetes. The study appears online November 24, 2014 in Nature Medicine. "While it is well-established that obesity generates cellular and molecular stress leading to abnormal functioning of many cellular processes, the mechanisms ...

New device could make large biological circuits practical

2014-11-24
CAMBRIDGE, MA -- Researchers have made great progress in recent years in the design and creation of biological circuits -- systems that, like electronic circuits, can take a number of different inputs and deliver a particular kind of output. But while individual components of such biological circuits can have precise and predictable responses, those outcomes become less predictable as more such elements are combined. A team of researchers at MIT has now come up with a way of greatly reducing that unpredictability, introducing a device that could ultimately allow such ...

Pain in a dish

Pain in a dish
2014-11-24
After more than six years of intensive effort, and repeated failures that made the quest at times seem futile, Harvard Stem Cell Institute (HSCI) researchers at Boston Children's Hospital (BCH) and Harvard's Department of Stem Cell and Regenerative Biology (HSCRB) have successfully converted mouse and human skin cells into pain sensing neurons that respond to a number of stimuli that cause acute and inflammatory pain. This "disease in a dish" model of pain reception may advance the understanding of different types of pain, identify why individuals differ in their pain ...

LAST 30 PRESS RELEASES:

Call for papers: 14th Asia-Pacific Conference on Transportation and the Environment (APTE 2025)

A novel disturbance rejection optimal guidance method for enhancing precision landing performance of reusable rockets

New scan method unveils lung function secrets

Searching for hidden medieval stories from the island of the Sagas

Breakthrough study reveals bumetanide treatment restores early social communication in fragile X syndrome mouse model

Neuroscience leader reveals oxytocin's crucial role beyond the 'love hormone' label

Twelve questions to ask your doctor for better brain health in the new year

Microelectronics Science Research Centers to lead charge on next-generation designs and prototypes

Study identifies genetic cause for yellow nail syndrome

New drug to prevent migraine may start working right away

Good news for people with MS: COVID-19 infection not tied to worsening symptoms

Department of Energy announces $179 million for Microelectronics Science Research Centers

Human-related activities continue to threaten global climate and productivity

Public shows greater acceptance of RSV vaccine as vaccine hesitancy appears to have plateaued

Unraveling the power and influence of language

Gene editing tool reduces Alzheimer’s plaque precursor in mice

TNF inhibitors prevent complications in kids with Crohn's disease, recommended as first-line therapies

Twisted Edison: Bright, elliptically polarized incandescent light

Structural cell protein also directly regulates gene transcription

Breaking boundaries: Researchers isolate quantum coherence in classical light systems

Brain map clarifies neuronal connectivity behind motor function

Researchers find compromised indoor air in homes following Marshall Fire

Months after Colorado's Marshall Fire, residents of surviving homes reported health symptoms, poor air quality

Identification of chemical constituents and blood-absorbed components of Shenqi Fuzheng extract based on UPLC-triple-TOF/MS technology

'Glass fences' hinder Japanese female faculty in international research, study finds

Vector winds forecast by numerical weather prediction models still in need of optimization

New research identifies key cellular mechanism driving Alzheimer’s disease

Trends in buprenorphine dispensing among adolescents and young adults in the US

Emergency department physicians vary widely in their likelihood of hospitalizing a patient, even within the same facility

Firearm and motor vehicle pediatric deaths— intersections of age, sex, race, and ethnicity

[Press-News.org] Ultra-short X-ray pulses explore the nano world
Characterization of X-ray flashes open new perspectives in X-ray science