Pre-Röntgen observations and research , a type of
discharge tube that emitted X-rays X-rays were originally noticed in science as a type of unidentified
radiation emanating from
discharge tubes by experimenters investigating
cathode rays produced by such tubes, which are energetic
electron beams that were first observed in 1869. Early researchers noticed effects that were attributable to them in many of the early
Crookes tubes (invented around 1875). Crookes tubes created free electrons by
ionization of the residual air in the tube by a high
DC voltage of anywhere between a few
kilovolts and 100 kV. This voltage accelerated the electrons coming from the
cathode to a high enough velocity that they created X-rays when they struck the
anode or the glass wall of the tube. The earliest experimenter thought to have (unknowingly) produced X-rays was
William Morgan. In 1785, he presented a paper to the
Royal Society of London describing the effects of passing
electrical currents through a partially evacuated glass tube, producing a glow created by X-rays. This work was further explored by
Humphry Davy and his assistant
Michael Faraday. Starting in 1888, Philipp Lenard conducted experiments to see whether cathode rays could pass out of the Crookes tube into the air. He built a Crookes tube with a "window" at the end made of thin aluminium, facing the cathode so the cathode rays would strike it (later called a "Lenard tube"). He found that something came through, that would expose photographic plates and cause fluorescence. He measured the penetrating power of these rays through various materials. It has been suggested that at least some of these "Lenard rays" were actually X-rays. Helmholtz formulated mathematical equations for X-rays. He postulated a dispersion theory before Röntgen made his discovery and announcement. He based it on the
electromagnetic theory of light. However, he did not work with actual X-rays. In early 1890 photographer
William Jennings and associate professor of the
University of Pennsylvania Arthur W. Goodspeed were making photographs of coins with electric sparks. On 22 February after the end of their experiments two coins were left on a stack of photographic plates before Goodspeed demonstrated to Jennings the operation of
Crookes tubes. While developing the plates, Jennings noticed disks of unknown origin on some of the plates, but nobody could explain them, and they moved on. Only in 1896 they realized that they accidentally made an X-ray photograph (they didn't claim a discovery). Also in 1890, Roentgen's assistant
Ludwig Zehnder noticed a flash of light from a fluorescent screen immediately before the covered tube he was switching on punctured. When
Stanford University physics professor
Fernando Sanford conducted his "electric photography" experiments in 1891–1893 by photographing coins in the light of electric sparks, like Jennings and Goodspeed, he may have unknowingly generated and detected X-rays. His letter of
6 January 1893 to the
Physical Review was duly published In 1894,
Nikola Tesla noticed damaged film in his lab that seemed to be associated with Crookes tube experiments and began investigating this invisible,
radiant energy. After Röntgen identified the X-ray, Tesla began making X-ray images of his own using high voltages and tubes of his own design, as well as Crookes tubes.
Discovery by Röntgen On November 8th, 1895, German physics professor
Wilhelm Röntgen discovered X-rays while experimenting with Lenard tubes and
Crookes tubes and began studying them. He wrote an initial report "On a new kind of ray: A preliminary communication" and on 28 December 1895, submitted it to
Würzburg's Physical-Medical Society journal. This was the first paper written on X-rays. Röntgen referred to the radiation as "X", to indicate that it was an unknown type of radiation. Some early texts refer to them as Chi-rays, having interpreted "X" as the uppercase
Greek letter Chi,
Χ. There are conflicting accounts of his discovery because Röntgen had his
lab notes burned after his death, but this is a likely reconstruction by his biographers: Röntgen was investigating cathode rays from a Crookes tube which he had wrapped in black cardboard so that the visible light from the tube would not interfere, using a
fluorescent screen painted with barium
platinocyanide. He noticed a faint green glow from the screen, about away. Röntgen realized some invisible rays coming from the tube were passing through the cardboard to make the screen glow. He found they could also pass through books and papers on his desk. Röntgen threw himself into investigating these unknown rays systematically. Two months after his initial discovery, he published his paper. of the Physik Institut,
University of Freiburg, on 1 January 1896 Röntgen discovered their medical use when he made a picture of his wife's hand on a photographic plate formed due to X-rays. The photograph of his wife's hand was the first photograph of a human body part using X-rays. When she saw the picture, she said "I have seen my death." The discovery of X-rays generated significant interest. Röntgen's biographer
Otto Glasser estimated that, in
1896 alone, as many as 49 essays and 1044 articles about the new rays were published. This was probably a conservative estimate, if one considers that nearly every paper around the world extensively reported about the new discovery, with a magazine such as
Science dedicating as many as 23 articles to it in that year alone. Sensationalist reactions to the new discovery included publications linking the new kind of rays to occult and paranormal theories, such as telepathy. The name X-rays stuck, although (over Röntgen's great objections) many of his colleagues suggested calling them
Röntgen rays. They are still referred to as such in many languages, including German, Hungarian, Ukrainian, Danish, Polish, Czech, Bulgarian, Swedish, Finnish, Portuguese, Estonian, Slovak, Slovenian, Turkish, Russian, Latvian, Lithuanian, Albanian, Japanese, Dutch, Georgian, Hebrew, Icelandic, and Norwegian. Röntgen received the inaugural
Nobel Prize in Physics for his discovery.
Advances in radiology apparatus, late 1800s. The Crookes tube is visible in center. The standing man is viewing his hand with a
fluoroscope screen. The seated man is taking a
radiograph of his hand by placing it on a
photographic plate. No precautions against radiation exposure are taken; its hazards were not known at the time. Röntgen immediately noticed X-rays could have medical applications. Along with his 28 December Physical-Medical Society submission, he sent a letter to physicians he knew around Europe (1 January 1896). News (and the creation of "shadowgrams") spread rapidly with Scottish electrical engineer
Alan Archibald Campbell-Swinton being the first after Röntgen to create an X-ray photograph (of a hand). Through February, there were 46 experimenters taking up the technique in North America alone.
), Lacerta vivipara
(now Zootoca vivipara), and Lacerta agilis'' In early 1896, several weeks after Röntgen's discovery,
Ivan Romanovich Tarkhanov irradiated frogs and insects with X-rays, concluding that the rays "not only photograph, but also affect the living function". At around the same time, the zoological illustrator James Green began to use X-rays to examine fragile specimens.
George Albert Boulenger first mentioned this work in a paper he delivered before the
Zoological Society of London in May 1896. The book
Sciagraphs of British Batrachians and Reptiles (sciagraph is an obsolete name for an X-ray photograph), by Green and James H. Gardiner, with a foreword by Boulenger, was published in 1897. The first medical X-ray made in the United States was obtained using a discharge tube of
Ivan Puluj's design. In January 1896, on reading of Röntgen's discovery, Frank Austin of
Dartmouth College tested all of the discharge tubes in the physics laboratory and found that only the Puluj tube produced X-rays. This was a result of Puluj's inclusion of an oblique "target" of
mica, used for holding samples of
fluorescent material, within the tube. On 3 February 1896, Gilman Frost, professor of medicine at the college, and his brother Edwin Frost, professor of physics, exposed the wrist of Eddie McCarthy, whom Gilman had treated some weeks earlier for a fracture, to the X-rays and collected the resulting image of the broken bone on
gelatin photographic plates obtained from Howard Langill, a local photographer also interested in Röntgen's work. . The authors named the technique
Röntgen photography. Many experimenters, including Röntgen himself in his original experiments, came up with methods to view X-ray images "live" using some form of luminescent screen.
Hazards discovered With the widespread experimentation with X‑rays after their discovery in
1895 by scientists, physicians, and inventors came many stories of burns, hair loss, and worse in technical journals of the time. In February 1896, Professor John Daniel and
William Lofland Dudley of
Vanderbilt University reported hair loss after Dudley was X-rayed. A child who had been shot in the head was brought to the Vanderbilt laboratory in 1896. Before trying to find the bullet, an experiment was attempted, for which Dudley "with his characteristic devotion to science" volunteered. Daniel reported that 21 days after taking a picture of Dudley's
skull (with an exposure time of one hour), he noticed a bald spot in diameter on the part of his head nearest the X-ray tube: "A plate holder with the plates towards the side of the skull was fastened and a
coin placed between the skull and the head. The tube was fastened at the other side at a distance of one-half-inch [] from the hair." In August 1896, H. D. Hawks, a graduate of Columbia College, suffered severe hand and chest burns from an X-ray demonstration. It was reported in
Electrical Review and led to many other reports of problems associated with X-rays being sent in to the publication. Many experimenters including
Elihu Thomson at Edison's lab,
William J. Morton, and
Nikola Tesla also reported burns. Elihu Thomson deliberately exposed a finger to an X-ray tube over a period of time and suffered pain, swelling, and blistering. Other effects were sometimes blamed for the damage including ultraviolet rays and (according to Tesla) ozone. Hall-Edwards developed a cancer (then called X-ray dermatitis) sufficiently advanced by 1904 to cause him to write papers and give public addresses on the dangers of X-rays. His left arm had to be amputated at the elbow in 1908, and four fingers on his right arm soon thereafter, leaving only a thumb. His amputated left hand was placed at
Birmingham University as a specimen. He died of cancer in 1926.
20th century and beyond in
1940, which displayed continuous moving images. This image was used to argue that
radiation exposure during the X-ray procedure would be negligible. The many applications of X-rays immediately generated enormous interest. Workshops began making specialized versions of Crookes tubes for generating X-rays and these first-generation
cold cathode or Crookes X-ray tubes were used until about 1920. A typical early 20th-century medical X-ray system consisted of a
Ruhmkorff coil connected to a
cold cathode Crookes X-ray tube. A spark gap was typically connected to the high voltage side in parallel to the tube and used for diagnostic purposes. The spark gap allowed detecting the polarity of the sparks, measuring voltage by the length of the sparks thus determining the "hardness" of the vacuum of the tube, and it provided a load in the event the X-ray tube was disconnected. To detect the hardness of the tube, the spark gap was initially opened to the widest setting. While the coil was operating, the operator reduced the gap until sparks began to appear. A tube in which the spark gap began to spark at around was considered soft (low vacuum) and suitable for thin body parts such as hands and arms. A spark indicated the tube was suitable for shoulders and knees. An spark would indicate a higher vacuum suitable for imaging the abdomen of larger individuals. Since the spark gap was connected in parallel to the tube, the spark gap had to be opened until the sparking ceased to operate the tube for imaging. Exposure time for photographic plates was around half a minute for a hand to a couple of minutes for a thorax. The plates may have a small addition of fluorescent salt to reduce exposure times. In about 1906, the physicist
Charles Barkla discovered that X-rays could be scattered by gases, and that each element had a characteristic
X-ray spectrum. He won the
1917 Nobel Prize in Physics for this discovery. In
1912,
Max von Laue, Paul Knipping, and Walter Friedrich first observed the
diffraction of X-rays by crystals. This discovery, along with the early work of
Paul Peter Ewald,
William Henry Bragg, and
William Lawrence Bragg, gave birth to the field of
X-ray crystallography. In
1913,
Henry Moseley performed crystallography experiments with X-rays emanating from various metals and formulated
Moseley's law which relates the frequency of the X-rays to the atomic number of the metal. The
Coolidge X-ray tube was invented the same year by
William D. Coolidge. It made possible the continuous emissions of X-rays. Modern X-ray tubes are based on this design, often employing the use of rotating targets which allow for significantly higher heat dissipation than static targets, further allowing higher quantity X-ray output for use in high-powered applications such as rotational CT scanners. The use of X-rays for medical purposes (which developed into the field of
radiation therapy) was pioneered by Major
John Hall-Edwards in
Birmingham, England. Then in 1908, he had to have his left arm amputated because of the spread of
X-ray dermatitis on his arm. Medical science also used the motion picture to study human physiology. In 1913, a motion picture was made in Detroit showing a hard-boiled egg inside a human stomach. This early X-ray movie was recorded at a rate of one still image every four seconds. Dr Lewis Gregory Cole of New York was a pioneer of the technique, which he called "serial radiography". In 1918, X-rays were used in association with
motion picture cameras to capture the human skeleton in motion. In 1920, it was used to record the movements of tongue and teeth in the study of languages by the Institute of Phonetics in England. In
1914,
Marie Curie developed radiological cars to support soldiers injured in
World War I. The cars would allow for rapid X-ray imaging of wounded soldiers so battlefield surgeons could quickly and more accurately operate. From the early 1920s through to the 1950s, X-ray machines were developed to assist in the fitting of shoes and were sold to commercial shoe stores. Concerns regarding the impact of frequent or poorly controlled use were expressed in the 1950s, leading to the practice's eventual decline. Canberra proposed a ban in 1957, while Switzerland prohibited the machines in 1989. The
X-ray microscope was developed during the late 1940s and early 1950s. The
Chandra X-ray Observatory, launched on
23 July 1999, has been allowing the exploration of the very violent processes in the
universe that produce X-rays. Unlike
visible light, which gives a relatively stable view of the universe, the X-ray universe is unstable. It features
stars being torn apart by
black holes,
galactic collisions, and
novae, and
neutron stars that build up layers of
plasma that then
explode into
space. An
X-ray laser device was proposed as part of the
Reagan Administration's
Strategic Defense Initiative in the 1980s, but the only test of the device (a sort of laser "blaster" or
death ray, powered by a thermonuclear explosion) gave inconclusive results. For technical and political reasons, the overall project (including the X-ray laser) was defunded (though was later revived by the second
Bush Administration as
National Missile Defense using different technologies).
Phase-contrast X-ray imaging refers to a variety of techniques that use phase information of an X-ray beam to form the image. Due to its good sensitivity to density differences, it is especially useful for imaging soft tissues. It has become an important method for visualizing cellular and histological structures in a wide range of biological and medical studies. There are several technologies being used for X-ray phase-contrast imaging, all using different principles to convert phase variations in the X-rays emerging from an object into intensity variations. These include propagation-based phase contrast,
Talbot interferometry, and X-ray interferometry. These methods provide higher contrast compared to normal absorption-based X-ray imaging, making it possible to distinguish from each other details that have almost similar density. A disadvantage is that these methods require more sophisticated equipment, such as
synchrotron or
microfocus X-ray sources,
X-ray optics, and high resolution X-ray detectors. ==Energy ranges==