diamond

Diamond dissolves in melts of carbon-dissolving metals such as iron, nickel, cobalt, chromium, titanium, platinum, palladium and their alloys. The larger the grain or the crystal, the lower the rate of conversion - in all cases - according to the ratio of reactive surface to volume.

Age determination

The age of the diamonds can be determined from their inclusions. These inclusions arise at the same time as the diamond that surrounds them and are often composed of surrounding silicate minerals . The age of the silicate minerals can be determined with geochronology based on their isotopic composition; mainly the decay systematics of ¹⁴⁷ Sm to ¹⁴³ Nd and ¹⁸⁷ Re to ¹⁸⁷ Os are used. Based on the now large database of isotope data, it can be determined that diamond formation took place again and again at different times across all geological ages, and that there are not only very old diamonds that are more than three billion years old, but also younger ones that are still reach an age of several hundred million years. The oldest known diamond has been dated to an age of 4.25 billion years.

Modifications and varieties

In addition to cubic crystallizing diamond, the following carbon modifications are known:

• Graphite (hexagonal),
• Lonsdaleit (hexagonal),
• Chaoite (hexagonal),
• Fullerenes (with a few exceptions only synthetic),
• Graphene (synthetic).

Diamond is metastable at room temperature and normal pressure . However, the activation energy for the phase transition to the stable modification (graphite) is so high that conversion to graphite practically does not take place at room temperature.

Ballas (radial, fibrous) and carbonado (black, porous polycrystalline diamond, which so far has only been found in Central Africa and South America) are special diamond varieties whose crystal structures have increased lattice defects due to unfavorable growth conditions .

Education and Locations

Play media file

Video about the creation of diamonds

Octahedral diamond of about 1.8 carats (6 mm) in kimberlite from the "Finsch Diamond Mine", South Africa

The respective transport time from the depths is estimated at a few hours, so that, due to the speed, there is no phase change to graphite. The last phase of the eruption occurs at supersonic speeds. Diamonds are foreign or xenocrystals in kimberlite and lamproit and are not chemically stable in these magmas (metastable). So you can always observe signs of dissolution in natural diamonds. From their occurrence in diatrems, the diamond crystals can be transported away by natural weathering processes, during which they remain intact due to their hardness, and enriched in sedimentary rocks , which are one of the main sources of this mineral today. Such occurrences are called alluvial . In particular, the best, low-inclusion diamonds survive the transport undamaged, so that alluvial deposits contain a particularly large number of diamonds of gem quality.

Metamorphic so-called UHP microdiamonds ( Ultra High Pressure ) have been found in the Ore Mountains , in Greece and in Kazakhstan , for example . The deposits are tied to sections of the earth's crust that were exposed to high pressures and temperatures during mountain formation and metamorphosis .

Origin of the carbon

Carbon occurs relatively rarely in the earth's mantle, either it represents a residue of the carbon that did not go into the crust during the differentiation of the earth's body, or it was brought back to these depths by the thrust or subduction of oceanic crust. Therefore diamonds sometimes have isotopic compositions that indicate a biogenic origin of the carbon and salty inclusions.

Earthly occurrences

Map showing regions where diamonds were extracted

The Siberian Udachnaya open-cast mine in the largest diamond deposit in Russia.

The largest diamond deposits are in Russia , Africa , especially in South Africa , Namibia , Angola , Botswana , the Democratic Republic of the Congo and Sierra Leone , in Australia , Canada and Brazil . Meanwhile diamonds have been found on every continent .

A total of around 700 locations for diamond are known so far (as of 2015). In Germany, diamonds were found on the Nördlinger Ries and near the Saidenbach dam near Forchheim.

Since diamonds are only stable on earth from a depth of approx. 140 km, the largest specimens can be found when they came up particularly quickly (usually with magmas) from at least this depth; diamonds from the lower mantle have even been detected become. Diamonds that have come to the surface of the earth through purely tectonic processes ( exhumation ) are usually relatively small (diameter usually less than 1 mm).

Dismantling

Diamonds are mostly extracted from pipes of extinct volcanoes, which are usually mined vertically downwards in their chimney filling , first in opencast mines, then underground. The host rock is ground up in order to separate the diamond crystals from the rock composite. Extensive opencast mines of this type are operated in Botswana, Russia and Angola. In Namibia and South Africa, diamonds are also found in the inland in the gravel terraces of some river valleys and in the partly desert-like coastal strips on the Atlantic in alluvial soils as well as submarine on the continental shelf , where they reached after erosion of their primary deposit by external natural influences, with other river scree components. The mining in these deposits is very space-intensive and is carried out by mechanical selection from the extracted loose sediments. It has a major impact on the affected ecosystems. Specially constructed ships are used for mining underwater, on which the diamonds are washed out of the sucked in sand.

The world production of natural diamonds (for example by the Rio Tinto Group ) is around twenty tons per year, which currently only covers around 20% of industrial demand. This is why synthetically produced diamonds, whose properties such as toughness, crystal habit, conductivity and purity can be precisely influenced, are increasingly filling this gap in demand.

Extraterrestrial formation and occurrence

Microdiamonds are mainly formed when meteorite impacts occur : the high temperatures and pressure conditions that occur during this process compress earthly carbon so much that small diamond crystals and also Lonsdaleite form, which are deposited from the explosion cloud and are still today in the vicinity of meteorite craters such as the Barringer Crater can be proven. Microdiamonds also occur in finds of iron meteorites and ureilitic achondrites , where they were probably formed from graphite by shock events. Tiny diamonds, often called nanodiamonds because of their typical size of just a few nanometers, also occur in the form of presolar minerals in primitive meteorites.

Carbonaceous chondrites

Carboniferous chondrite

Carbonaceous chondrites are stone meteorites with a comparatively high (up to 3%) proportion of carbon. These sometimes contain tiny, nanometer-sized diamonds that were formed outside of our solar system .

Synthetic manufacture

Synthetic diamonds

Synthetic diamond single crystal with a diameter of 92 mm and a weight of 155 carats

The production of synthetic diamonds was first achieved on February 15, 1953 by the physicist Erik Lundblad at the Swedish electrical engineering group ASEA .

In diamond burial , carbon is pressed from the ashes of the deceased into diamonds.

production method

High pressure high temperature process

Detonation Synthesis

Other methods of generating high temperatures and pressures are so-called detonation synthesis and shock wave synthesis. In detonation synthesis, a distinction is made between the detonation of a mixture of graphite and explosive or exclusively the detonation of explosive substances. In the case of the latter, an explosive mixture of TNT (trinitrotoluene) and RDX ( hexogen ) is detonated in a sealed container. The explosives provide the required energy and are at the same time a carbon carrier. In shock wave synthesis, the pressure required to convert carbon material into diamond is brought about by the action of an external shock wave, also triggered by an explosion. The explosion compresses a capsule filled with carbon material. This force causes the carbon material inside to be converted into diamond. Industrial diamond is just as hard as natural diamond.

layers

An alternative to the production of artificial diamond is the coating of substrates by means of chemical vapor deposition (engl. Chemical vapor deposition , CVD). A CVD diamond layer a few micrometers thick is deposited on the substrates , for example hard metal tools, in a vacuum chamber . The starting material is typically a gas mixture of methane and hydrogen , the former serving as a carbon source.

According to Ostwald's rule of levels , mainly metastable diamond should be deposited; According to the Ostwald-Volmer rule , mainly graphite is formed due to its lower density. With atomic hydrogen it is possible to decompose graphite selectively and to promote the formation of diamond. Atomic hydrogen (H) is created in a thermally or electrically heated plasma from molecular hydrogen gas (H ₂ ). The substrate temperature must be below 1000 ° C in order to prevent the conversion into the stable graphite. Growth rates of several micrometers per hour can then be achieved.

As a further development, with the help of the technology of plasma coating, for example with PECVD, layers of so-called diamond-like carbon ( DLC : diamond-like carbon ) that are only a few nanometers to micrometers thick can be produced. These layers combine very high hardness and very good sliding friction properties at the same time. Depending on the coating parameters, they contain a mixture of sp ² - and sp ³ - hybridized carbon atoms. These layers are therefore not diamond. However, these layers have certain properties of the diamond and are therefore referred to as "diamond-like" or "diamond-like". By controlling the process and the choice of precursor material , many types of carbon layers, from hard hydrogen-free to very elastic hydrogen-containing layers, can be produced.

Homo- and heteroepitaxy

Using chemical vapor deposition (MWPCVD) supported by a microwave plasma, it is possible to produce thick diamond bodies on thin diamond substrates or on lattice-adapted foreign substrates ( heteroepitaxy ). The successful production of a disc-shaped diamond with a weight of 155 carats and a diameter of 92 mm in 2016 was based on the latter process. The process consists in that, on the one hand, carbon is released from hydrocarbons (e.g. methane ) in the plasma and is deposited; on the other hand, a high proportion of atomic hydrogen in the plasma ensures that all non-diamond-like deposited structures are removed again. In 2008, the most promising substrate for production of heteroepitaxial diamond wheels is a multilayer structure of an iridium layer on yttrium -stabilized zirconium (IV) oxide (YSZ), which on a single crystal silicon - wafer was deposited.

Further processing

This commercially successful route provides diamond powder in various finenesses. The synthetically produced rough diamonds are first mechanically crushed (grinding in ball mills ). Impurities from residues of the starting materials on the surface of the diamond particles, such as non-flammable impurities or unconverted graphite residues , are removed chemically. In the case of coarser grain sizes, classification is carried out by sieving. Micro-grains, on the other hand, have to be sedimented. For this purpose, the diamond powder is placed in a water basin. The sedimentation speed of a spherical particle can be calculated with the help of Stokes' law . The upper layers of the water-diamond powder mixture are carefully suctioned off and physically dried after each sedimentation period.

Magnetic diamond

At the Rensselaer Polytechnic Institute in Troy it was possible to produce magnetic diamonds. They are only five nanometers in size and have their own magnetic field . The effect is based on a defect in the crystal lattice. Applications of the health-friendly carbon are predicted primarily in medicine.

Monocrystalline diamond powder

Monocrystalline industrial diamond ( single crystal ) is relatively inexpensive and can be produced in large quantities. In industrial technology, it is therefore widely used in grinding , lapping and polishing processes. The diamond has a monocrystalline lattice structure, the sliding planes are oriented parallel to the optical axis (111 plane). When loaded, the monocrystalline diamond grain breaks along the parallel cleavage planes. This results in grains in block form with sharp cutting edges. In symbolic terms, a monocrystalline diamond grain breaks like a salami that is cut into slices ("salami slice model").

Polycrystalline diamond powder

A polycrystalline (industrial) diamond ( polycrystalline ) is composed of a large number of tiny diamond grains. When loaded, small corners and edges break out of the diamond grain, so that new, sharp cutting edges are created again and again (self-sharpening effect). This characteristic enables high removal rates and, at the same time, the finest surfaces to be achieved. It is suitable for lapping and polishing extremely hard materials such as ceramics or sapphire glass.

Nanodiamond

Nanodiamond powder is used in various applications and research areas. The large volume-to-surface ratio creates new physical and chemical properties. Nanodiamonds, for example, have perfect lubricating properties and are therefore added to lubricating oils. Another area of ​​application for nanodiamonds is said to be cancer therapy.

Natural diamond powder

The monocrystalline natural diamond powder is preferably used for the production of electroplated diamond tools. As a waste product of the jewelry industry, it is very rare and correspondingly expensive.

Coated diamond powder

SEM image of nickel-coated diamond powder

Monocrystalline industrial diamond powder coated with nickel , copper or titanium is used, among other things, for the production of electroplated diamond tools.

Use as a gem stone

Natural brilliant cut diamonds

A diamond has a very high refraction and a strong shine , paired with a striking dispersion, which is why it is mainly used as a gemstone to this day . Its brilliance is based on innumerable internal light reflections, which are caused by the careful grinding of the individual facets, which must be in specially selected angular relationships to one another. The aim is to allow a high percentage of the incident light to exit the stone again in the direction of the viewer through reflections inside the stone. In the meantime, cuts and their effects are simulated on computers and the stones are ground on machines in order to achieve optimal results through an exact execution. Only a quarter of all diamonds are qualitatively suitable as gem stones. Only a small fraction of this meets the criteria that are placed on gemstones today: Sufficient size, suitable shape, high purity, freedom from defects, quality of cut, brilliance, color dispersion, hardness, rarity and, depending on the wishes, color or colorlessness.

In the early Middle Ages , the diamond had no special value due to the lack of processing options, and mostly only the colored stones were called precious stones.

Probably beginning in the 14th century and up to the 16th century, diamonds were cut into facets with a smooth cleavage surface upwards and downwards in a curved shape. This cut was called the rose cut , later variants with several facet levels the "Antwerp rose". These diamonds were then set in silver over a foil-covered recess that was polished and sometimes also had impressions of the facets of the rose cut to increase the reflection.

With the invention of better grinding wheels in the 17th century, it was possible to grind diamonds with a pointed lower part, which for the first time could reflect light incident from above back to the viewer through total reflection . Such diamonds were then set open at the bottom, and many diamond roses are said to have been cut. Like the diamond roses foiled below, this cut showed good brilliance and the fire of the diamond. Up until the 19th century, processing consisted of only two techniques, splitting along the split planes (octahedron surfaces) and grinding / polishing. With the invention of sawing, diamonds could be developed with a modern cut and with less processing loss. The modern cut was created in the 20th century, with a significantly higher light output that pushes the fire into the background.

Since the 1980s, diamonds have been processed with lasers, among other things, to remove dark inclusions and mark stones. The natural color of diamonds cannot be influenced as easily as with other gemstones. Unsightly stones have been given to irradiation in nuclear reactors to change their color since the 1960s. The result is permanent color changes. Dirty gray, white and yellowish stones are given a bright blue or green. This can be followed by a heat treatment, whereby the crystal changes generated by radiation partially “heal” again and become visible as further color changes. The results are not always clearly predictable.

Diamond determination

Diamond spectrum, figures in Ångström units

Criteria for recognizing a diamond include: a. its density, hardness, thermal conductivity, gloss, light scattering or dispersion, light refraction or refraction and the type and formation of existing inclusions.

Another important instrument to distinguish between natural and artificially colored diamonds is absorption spectroscopy . Diamonds come in a variety of colors and shades, including yellow, brown, red, and blue. The colors are mainly based on the incorporation of foreign elements (e.g. nitrogen or boron ) in the carbon lattice of natural diamonds.

Diamonds

Eppler -brillant

Diamond tools are not suitable for machining steel, as they convert to graphite at the high temperatures that occur there and the carbon atoms diffuse into the steel .

Diamond-like layers

Thin CVD layers made of diamond-like carbon serve as wear protection.

By adding boron , phosphorus or nitrogen , diamond can be made conductive and function as a semiconductor or even as a superconductor . Use in electronic circuits could lead to higher switching speeds due to the high mobility of the charge carriers in the diamond single crystal and the good temperature tolerance. Electrically conductive diamond coatings can be used to manufacture electrodes for use in chemical reactions that have to withstand very reactive radicals. On an industrial scale, wastewater treatment and purification comes into focus, where CVD diamond electrodes are used for the oxidation and disinfection of e.g. B. sewage and process water are used.

The coating of silicon wafers with artificial diamond, which can be used by the semiconductor industry to achieve better cooling of electronic circuits, has already been implemented .

optics

One field of application for pure diamonds is infrared spectroscopy and the manufacture of lenses and windows.

Others

The stylus of higher quality cartridges for playing records are made of diamond. These diamonds have a special shape and sit in the aluminum or boron needle carrier.

A multitude of tiny diamonds in a free-flowing form were used in an hourglass .

Diamond anvil cells are used in materials research to achieve very high pressures in the gigapascal range.

Social influences

Diamond prospectors in Sierra Leone

While the majority of today's diamonds are mined with modern means by very few international corporations such as the De Beers company , the exorbitant price that is paid for diamonds is causing excavations among pathetic ones, especially in the underdeveloped regions and crisis areas of the world and sometimes life-threatening conditions. Even if individual miners find what they are looking for, the rough diamonds are mostly sold cheaply to the local rulers, so that only a fraction of the profits remain with the actual miners.

In the illegal arms trade, especially in West Africa, paying with diamonds is not uncommon. The reasons for this are obvious: they are small (therefore easy to carry and hide), valuable, and their value hardly fluctuates. None of this is usually the case with local currencies.

Others

In 2019, a diamond was discovered within another diamond for the first time. The 5 mm large and 0.6 carat diamond contains a 6 mm ³ cavity in which a 2 mm large and 0.02 carat diamond is enclosed . It is therefore also known as the “ Matryoshka diamond” and was funded by the Russian company ALROSA in Yakutia . The age of the diamond is estimated to be around 800 million years.

See also

• List of minerals
• List of mineral jewelry and precious stones
• Adamantane
• Diamondoids
• Aggregated diamond nanorods (according to controversial opinion, harder substance)
• Rhenium diboride (another crystalline solid with an extreme hardness)
• Q-carbon

literature

• Diamond . In: John W. Anthony, Richard A. Bideaux, Kenneth W. Bladh, Monte C. Nichols (Eds.): Handbook of Mineralogy, Mineralogical Society of America . 2001 ( handbookofmineralogy.org [PDF; 58 kB ; accessed on July 14, 2018]). 
• Ulrich Schwarz: diamond, naturally grown gemstone and tailor-made material . In: Chemistry in Our Time . tape 34 , no. 4 , 2000, pp. 212-222 , doi : 10.1002 / 1521-3781 (200008) 34: 4 <212: AID-CIUZ212> 3.0.CO; 2-7 . 
• Hendrik Helzberg: Pocket Guide Diamonds. ( Memento from January 25, 2012 in the Internet Archive ) E-book. Gentlemen's Digest, Berlin 2005 (pdf).
• Lorenz Gerke: Diamond-like carbon layers as expansion-tolerant wear and corrosion protection for shape memory alloys . Shaker, Aachen 2012, ISBN 978-3-8440-1055-8 , urn : nbn: de: 101: 1-201503294381 ( free full text - dissertation, Ruhr University Bochum). 
• Ian Balfour : Famous Diamonds. Antique Collectors Club, Woodbridge 2009, ISBN 978-1-85149-479-8 .

Web links

Commons : Diamond  - collection of pictures, videos and audio files

Wiktionary: Diamant  - explanations of meanings, word origins, synonyms, translations

Wikiquote: Diamond  Quotes

• Diamond. In: Mineralienatlas Lexikon. Stefan Schorn u. a., accessed on August 15, 2020 . 
• Refraction diamonds. In: leifiphysik.de. Joachim Herz Stiftung , accessed on August 15, 2020 (Explanations on the light path in cut diamonds at school level ( LEIFI )). 
• Shapes of diamond cut. In: diamanten-infos.com. Retrieved August 15, 2020 . 

Individual evidence

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2. ↑ What will happen if you burn a diamond Feed Your Need, youtube.com, uploaded January 20, 2017, accessed August 22, 2017.
3. ↑ Burning diamonds Beyond the press, youtube.com, uploaded May 15, 2016, accessed on August 22, 2017. - Fire test with fragments of a 1.2-carat diamond. (English)
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6. ↑ Diamond Crystals from Africa - Crystal Habits and Surface Morphology (English).
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10. ↑ Ben Harte: Diamond formation in the deep mantle: the record of mineral inclusions and their distribution in relation to mantle dehydration zones . In: Mineralogical Magazine . tape 74 , no. 2 , April 2010, ISSN  0026-461X , p. 189–215 , doi : 10.1180 / minmag.2010.074.2.189 ( cambridge.org [accessed August 24, 2019]). 
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25. ↑ Matthias Schreck, Stefan Gsell, Rosaria Brescia, Martin Fischer: Ion bombardment induced buried lateral growth: the key mechanism for the synthesis of single crystal diamond wafers. Nature Scientific Reports, March 15, 2017, accessed December 3, 2017 . doi: 10.1038 / srep44462 
26. ↑ Alexander Jung: Augsburger Soup Box. Bavarian researchers have succeeded in growing the largest diamond in the world - a matter of days. Are gemstones now becoming mass-produced? . In: Der Spiegel 48/2017, pp. 70–71
27. ↑ https://www.researchgate.net/publication/229164193_Preparation_of_4-inch_IrYSZSi001_substrates_for_the_large-area_deposition_of_single-crystal_diamond Fischer, M .; Gsell, S .; Schreck, M .; Brescia, R .; Stritzker, B .: Preparation of 4-inch Ir / YSZ / Si (001) substrates for the large-area deposition of single-crystal diamond. in Diamond and Related Materials Vol. 17 (2008), pages 1035-1038, doi: 10.1016 / j.diamond.2008.02.028. , accessed on December 12, 2019
28. ↑ Researchers create tiny magnetic diamonds on the nanoscale. In: phys.org. September 12, 2005, accessed July 1, 2017 . 
29. ↑ S. Talapatra, PG Ganesan, T. Kim, R. Vajtai, M. Huang, M. Shima, G. Ramanath, D. Srivastava, SC Deevi, PM Ajayan: Irradiation-Induced Magnetism in Carbon Nanostructures . In: Physical Review Letters . tape 95 , no. 9 , 2005, 097201, doi : 10.1103 / PhysRevLett.95.097201 . 
30. ↑ Spiegel-Online: Nano-Technologie: Mini-Diamonds Should Advance Cancer Therapy , March 10, 2011.
31. ↑ January Hirschbiegel : Etrennes: Studies on the court Gift traffic in late medieval France at the time of King Charles VI. (1380-1422) . De Gruyter, Berlin / Boston 2003, ISBN 978-3-486-56688-8 , pp. 154 , urn : nbn: de: 101: 1-2016072920398 (free full text). 
32. ↑ Alois Haas, L. Hödl, Horst Schneider: Diamond: Magic and history of a miracle of nature . Springer, Berlin / Heidelberg 2004, ISBN 978-3-540-40877-2 , pp. 78 ( limited preview in Google Book search). 
33. ↑ Namibia's quality still world-class, Allgemeine Zeitung, September 1, 2010 .
34. ↑ World record: 39.1 million euros for "Pink Legacy" , T-Online Panorama, November 14, 2018, accessed November 14, 2018
35. ↑ Pink clunker auctioned for record price , SPIEGEL ONLINE, April 4, 2017, accessed November 14, 2018
36. ↑ Blauer Diamant achieves record price in Geneva , SRF Panorama, May 19, 2016, accessed November 14, 2018
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39. ↑ Blauer Oppenheimer: A diamond breaks records , SZ from May 19, 2016
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47. ↑ LVMH buys second largest rough diamond in history orf.at, January 16, 2020, accessed January 16, 2020.
48. ↑ Daniel Lingenhöhl: 1111 carats - giant diamond found in Botswana. In: Spektrum.de. November 19, 2015, accessed November 19, 2015 . 
49. ↑ Lucara makes diamond history. Recovers 1,111 carat diamond. (PDF) (No longer available online.) In: lucaradiamond.com. Lucara Diamond, November 18, 2015; archived from the original on November 20, 2015 ; accessed on November 19, 2015 (English). 
50. ↑ Tennis-ball sized diamond found by Canadian firm could fetch $ 90M. CTV News , May 4, 2016, accessed March 14, 2018 : "After being closely examined, it was found to measure 1,109 carats" 
51. ↑ Giant Diamond - "Our Light" sold for $ 53 million . Spiegel Online, September 26, 2017
52. ↑ New giant diamond found in Lesotho. In: Frankfurter Allgemeine Zeitung . January 16, 2018, accessed January 16, 2018 . 
53. ↑ Giant diamond from Lesotho sold for $ 40 million. In: Frankfurter Allgemeine Zeitung. March 13, 2018, accessed March 14, 2018 . 
54. ^ The Incomparable Diamond .
55. ↑ Lucara Recovers Two More Large Diamonds Including an 813 Carat Stone from the Karowe Mine in Botswana. (No longer available online.) In: lucaradiamond.com. Lucra Diamond on November 19, 2015; archived from the original on November 19, 2015 ; accessed on November 19, 2015 (English). 
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57. ↑ Diamant Kontor - The Millennium Star. Retrieved January 16, 2018 . 
58. ↑ Famous Diamonds - The Peace Diamond (and others). Retrieved January 16, 2018 . 
59. ↑ Massive diamond found by Sierra Leone pastor now for sale in Antwerp. Mining.com, October 4, 2017.
60. ↑ 6.5 million for the "Peace Diamond" at Frankfurter Allgemeine Zeitung on December 5, 2017
61. ^ Famous, Historic and Notable Diamonds - Ryan Thompson .
62. ↑ Largest diamond in North America discovered orf.at, December 16, 2018, accessed on December 16, 2018.
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64. ↑ The 110.3 carat, Cora Sun-Drop
65. ^ Walter Schumann: Precious stones and gemstones. All kinds and varieties. 1900 unique pieces . 16th revised edition. BLV Verlag, Munich 2014, ISBN 978-3-8354-1171-5 , pp. 94 . 
66. ↑ MuseumDiamonds.com - Nassak ( Memento of 25 September 2015, Internet Archive )
67. ↑ Spoon Maker Diamond ( Memento from November 11, 2012 in the Internet Archive )
68. ^ Ian Balfour: Famous Diamonds Antique Collectors Club, Woodbridge 2009, p. 250.
69. ↑ Erica and Harold van Pelt: Precious stones. Symbols of beauty and power. Verlag Hans Schöner, Königsbach-Stein, Luzern 1999, pp. 49, 199.
70. ↑ "Blauer Wittelsbacher" brings 18.7 million euros ( Memento of February 17, 2009 in the Internet Archive ). On: br-online.de, December 10, 2008; Wittelsbach diamond . On: royal-magazin.de, 2008.
71. ↑ Listing Bourses. World Federation of Diamond Bourses, accessed December 5, 2015 . 
72. ↑ welt.de: Diamond dealer De Beers gives up de facto monopoly , July 14, 2000.
73. ↑ https://www.steine-und-minerale.de/artikel.php?f=6&ID=484&topic=1&titel=Industriediamanten&keywords=industriediamant,%20man%20made%20diamond,%20industrial%20diamond,%20industriediamanten%20preis,%20industriediamanten % 20buy,% 20kunstdiamant,% 20synthetischer% 20diamant Torsten Purle: Industrial diamonds , accessed on Nov. 8, 2019
74. ↑ Chris JH Wort, Richard S. Balmer: Diamond as an electronic material . In: Materials Today . tape 11 , no. 1 , 2008, p. 22-28 , doi : 10.1016 / S1369-7021 (07) 70349-8 . 
75. ↑ Diamond hourglass from De Beers with 2000 diamonds in the online catalog of Hampel Fine Art Auctions Munich
76. ↑ Daniel Lingenhöhl: Rare Minerals: Diamond found in a diamond. Retrieved October 11, 2019 . 

This article was added to the list of articles worth reading on June 15, 2005 in this version .