Top 50 moments - In the history of materials
A Great Materials Moment is defined as a pivotal or capstone event of human observation and/or intervention that led to a paradigm shift in humanity's understanding of materials behavior, that introduced a new era of materials utilization, and/or that yielded significant materials-enabled socio-economic changes.
These are the top 50 materials moments in history as voted upon by more than 900 survey participants during late 2006.
No 1
1864
Dmitri Mendeleev devises the Periodic Table of Elements.
Introduces the ubiquitous reference tool of materials scientists and engineers
No 2
3500 BC (estimated)
Egyptians smelt iron (perhaps as a by-product of copper refining) for the first time, using tiny amounts mostly for ornamental or ceremonial purposes.
Unlocks the first processing secret of what will become the world's dominant metallurgical material.
No 3
1948
John Bardeen, Walter H. Brattain, and William Shockley invent the transistor.
Becomes the building block for all modern electronics and the foundation for microchip and computer technology
No 4
2200 BC (estimated)
The peoples of northwestern Iran invent glass.
Introduces the second great nonmetallic engineering material following ceramics
No 5
1668 (estimated)
Anton van Leeuwenhoek develops optical microscopy capable of magnifications of 200 times and greater.
Enables study of the natural world and its structures that are invisible to the unaided eye.
No 6
1755
John Smeaton invents modern concrete (hydraulic cement).
Introduces the dominant construction material of the modern age.
No 7
300 BC (estimated)
Metal workers in south India develop crucible steel making.
Produces "wootz" steel which becomes famous as "Damascus" sword steel hundreds of years later, inspiring artisans, blacksmiths, and metallurgists for many generations to come
No 8
5000 BC (estimated)
In and around modern Turkey, people discover that liquid copper can be extracted from malachite and azurite and that the molten metal can be cast into different shapes.
Introduces extractive metallurgy--the means of unlocking the Earth's mineralogical treasures
No 9
1912
Max von Laue discovers the diffraction of x-rays by crystals.
Creates means to characterize crystal structures and inspires W.H. Bragg and W.L Bragg in developing the theory of diffraction by crystals, providing insight into the effects of crystal structure on material properties.
No 10
1856
Henry Bessemer patents a bottom-blown acid process for melting low-carbon iron.
Ushers in the era of cheap, large tonnage steel, thereby enabling massive progress in transportation, building construction, and general industrialization
The whimsical artwork for the top ten was created by David Rasel in the style of Georgius Agricola's volume De Re Metallica, which is Moment 30
No 11
1876
J. Willard Gibbs publishes the first part of the two-part paper "On the Equilibrium of Heterogeneous Substances." Provides a basis for understanding modern thermodynamics and physical chemistry
No 12
28,000 BC (estimated)
The earliest fired ceramics--in the form of animal and human figurines, slabs, and balls--(found at sites in the Pavlov Hills of Moravia) are manufactured starting about this time. Introduces materials processing
No 13
400 (estimated)
Iron smiths forge and erect a seven meter high iron pillar in Delhi, India. Defies deleterious environmental effects for more than one and a half millennia, creating an artifact of long-standing materials science and archaeological intrigue
No 14
1896
Pierre and Marie Curie discover radioactivity. Marks the beginning of modern-era studies on spontaneous radiation and applications of radioactivity for civilian and military applications
No 15
1844
Charles Goodyear invents the vulcanization of rubber. Enables enormous progress in the transportation, electricity, manufacturing, and myriad other industries.
No 16
1898
William Roberts-Austen develops the phase diagram for iron and carbon. Initiates work on the most significant phase diagram in metallurgy, providing the foundation for the indispensable tool for other material systems.
No 17
1925
Werner Heisenberg develops matrix mechanics and Erwin Schrödinger invents wave mechanics and the non-relativistic Schrödinger equation for atoms. Forms the basis of quantum mechanics.
No 18
3000 BC (estimated)
Metal workers in the region of modern Syria and Turkey discover that addition of tin ore to copper ore before smelting produces bronze. Establishes the concept of metals alloying--blending two or more metals to create a substance that is greater than the sum of its parts
No 19
1450
Johannes Gutenberg devises a lead-tin-antimony alloy to cast in copper alloy molds to produce large and precise quantities of the type required by his printing press. Establishes the fundamental enabling technology for mass communication
No 20
1913
Niels Bohr publishes his model of atomic structure. Introduces the theory that electrons travel in discrete orbits around the atom's nucleus, with the chemical properties of the element being largely determined by the number of electrons in each of the outer orbits
No 21
1822
Augustin Cauchy presents his theory of stress and strain to the French Academy of Sciences. Provides the first careful definition of stress as the load per unit area of the cross section of a material
No 22
1939
Otto Hahn and Fritz Strassmann find that they can split the nucleus of a uranium atom by bombarding it with neutrons Establishes nuclear fission and leads to applications in energy and atomic weapons.
No 23
1934
Egon Orowan, Michael Polyani, and G.I. Taylor, in three independent papers, propose that the plastic deformation of ductile materials could be explained in terms of the theory of dislocations. Provides critical insight toward developing the modern science of solid mechanics
No 24
200 BC (estimated)
Chinese metal workers develop iron casting. Introduces the primary approach to manufacturing iron objects for centuries in China
No 25
1886
Charles Martin Hall and Paul Héroult independently and simultaneously discover the electrolytic reduction of alumina into aluminum. Provides the processing foundation for the proliferation of aluminum for commercial applications
No 26
1965
Cambridge Instruments introduces a commercial scanning electron microscope. Provides an improved method for the high-resolution imaging of surfaces at greater magnifications and with much greater depth of field than possible with light microscopy
No 27
1904
Leon Guillet develops the alloying compositions of the first stainless steels. Expands the versatility of steel for use in corrosive environments
No 28
1933
Max Knoll and Ernst Ruska build the first transmission electron microscope. Accesses new length scales and enables improved understanding of material structure.
No 29
1500 BC (estimated)
Metal workers in the Near East develop the art of lost-wax casting. Establishes the ability to create and replicate intricate and complex metallurgical structures.
No 30
1556
Georgius Agricola publishes De Re Metallica. Provides a systematic and well-illustrated examination of mining and metallurgy as practiced in the sixteenth century
No 31
100 BC (estimated)
Glass blowing is developed, probably somewhere in the region of modern Syria, Lebanon, Jordan, and Israel--most likely by Phoenicians. Enables the quick manufacture of large, transparent, and leak-proof vessels
No 32
1807
Sir Humphry Davy develops the process of electrolysis to separate elemental metals from salts, including potassium, calcium, strontium, barium, and magnesium. Establishes the foundation for electrometallurgy and electrochemistry
No 33
1709
Abraham Darby I discovers that coke can effectively replace charcoal in a blast furnace for iron smelting. Lowers dramatically the cost of ironmaking (enabling large-scale production) and saves regions from deforestation.
No 34
1920
Hermann Staudinger publishes work that states that polymers are long chains of short repeating molecular units linked by covalent bonds. Paves the way for the birth of the field of polymer chemistry.
No 35
1939
Russell Ohl, George Southworth, Jack Scaff, and Henry Theuerer discover the existence of p- and n-type regions in silicon. Provides a necessary precursor to the invention of the transistor eight years later
No 36
1991
Sumio Iijima discovers nanotubes, carbon atoms arranged in tubular structures. Creates expectations of important structural and nonstructural applications as nanotubes are about 100 times stronger than steel at just a sixth of the weight while also possessing unusual heat and conductivity characteristics.
No 37
1867
Alfred Nobel patents dynamite. Proves of immeasurable assistance in conducting large-scale mining
No 38
1958
Jack Kilby integrates capacitors, resistors, diodes, and transistors into a single germanium monolithic integrated circuit or "microchip." Makes possible microprocessors and, thereby, high-speed, efficient, convenient, affordable, and ubiquitous, computing and communications systems
No 39
8000 BC (estimated)
The earliest form of metallurgy begins with the decorative hammering of copper by Old World Neolithic peoples. Leads to the replacement of stone tools with much more durable and versatile copper ones
No 40
1827
Friedrich Wöhler isolates elemental aluminum. Unlocks the most abundant metallic element in the Earth's crust
No 41
1911
Kammerlingh Omnes discovers superconductivity while studying pure metals at very low temperatures. Forms the basis for modern discoveries in low- and high-temperature superconductors and resulting high-performance applications
No 42
1500 BC (estimated)
Potters in China craft the first porcelain using kaolin. Begins a long tradition of exceptional craftsmanship and artistry with this class of ceramics
No 43
1909
Leo Baekeland synthesizes the thermosetting hard plastic Bakelite. Marks the beginning of the "plastic age" and the modern plastics industry
No 44
1926
Paul Merica patents the addition of small amounts of aluminum to Ni-Cr alloy to create the first "superalloy." Leads to the commercialization of the jet engine, along with increased efficiency for modern power turbine machinery
No 45
1863
Henry Clifton Sorby uses light microscopy to reveal the microstructure of steel. Leads to the use of photomicrography with metals and the science of metallurgy
No 46
1935
Wallace Hume Carothers, Julian Hill, and other researchers patent the polymer nylon. Greatly reduces the demand for silk and serves as the impetus for the rapid development of polymers
No 47
1805
Luigi Brugnatelli invents electroplating. Originates the widely employed industrial process for functional and decorative applications
No 48
1959
Richard Feynman presents "There's Plenty of Room at the Bottom" at a meeting of the American Physical Society Introduces the concept of nanotechnology (while not naming it as such)
No 49
1890
Adolf Martens examines the microstructure of a hard steel alloy and finds that, unlike many inferior steels that show little coherent patterning, this steel had many varieties of patterns, especially banded regions of differently oriented microcrystals. Initiates the use of microscopy to identify the crystal structures in metals and correlate these observations to the physical properties of the material
No 50
1920
A.A. Griffith publishes "The Phenomenon of Rupture and Flow in Solids," which casts the problem of fracture in terms of energy balance. Gives rise to the field of fracture mechanics.
How Was the List Developed?
The list of 100 nominees was arrived upon via a multi-step process conducted by JOM's editorial staff. It began with an inventory of more than 600 candidate moments compiled via a review of the literature and solicitation of input from TMS technical committee members, editorial review boards of peer-reviewed journals that cover materials science and engineering, and other respected members of the materials community.
This list of 600+ was honed to the official nominee list of 100 by the staff of The Minerals, Metals & Materials Society working with input from invited members.
The list of 100 official candidates was presented to on-line voters during the closing months of 2006. Voters were asked to create their own individual top ten lists from the pool of candidates. More than 900 voters participated in this somewhat lengthy exercise.
When the polls closed, a first-place vote for a candidate moment was counted as 10 points, a second-place vote was counted as 9 points, and so on until a tenth-place vote for a moment was counted as 1 point. The points accumulated by all of the moments were tallied, and moments were sorted from top to bottom based on the total point values received by each.
For purposes of public presentation, only the moments that rank in the top 50 are displayed. (This allows for consideration of the notion that moments that did not achieve top 50 status may, in fact, not all belong among the top 100. That matter can serve as fodder for debate another day.)
Headquartered in the United States but international in both its membership and activities, The Minerals, Metals & Materials Society (TMS) is a rare professional organization that encompasses the entire range of materials and engineering, from minerals processing and primary metals production to basic research and the advanced applications of materials.
In support of its Mission statement and Strategic Plan, the society provides forums for the exchange of information; promotes technology transfer; promotes the education and development of current and future professionals; represents the profession in the accreditation of educational programs and in the registration of professional engineers (a U.S.-grounded activity); encourages professionalism, ethical behavior, and concern for the environment; and stimulates a worldwide sense of unity in the profession.
(Sourced from http://www.materialmoments.org)
