Technological discussions in iron and steel 1871 1885

Technological discussions in iron and steel, 1871 -1885 Carol Siri Johnson, New Jersey Institute of Technology, USA Peter B. Meyer, Research Economist, U. S. Bureau of Labor Statistics* APEBH conference, Sydney, Feb 14, 2007 *Views expressed here do not reflect official policies or measurements of the U. S. Bureau of Labor Statistics. Outline 1. Iron and steel developments 2. The TAIME journal 3. Hypotheses about the text 4. A few findings

U. S. steel production quantity and price Output grew and costs fell because of technological advance and scale Source: Historical Statistics of US

Our questions We analyze the text of an American engineering journal (TAIME) looking for: • Evidence of new technological “paradigm” as mass production steel is becoming established • Different expectations of the future: social “uncertainty”

Transition to mass production From craft: toward industrial machines:

After the Bessemer converter, steelmaking became less like craft work . . . and more chemical knowledge would be necessary

Transactions of the American Institute of Mining Engineers (TAIME) We have scanned this professional engineering journal from 1871 -1885 where iron and steel making was discussed Authors include professors, employees in iron industry, consultants, and others 712 articles so far 135 have the word “Bessemer”

Scans of the journal A nonprofit contractor, Digital Divide Data, photocopied the journals • Scanned them to make image files • Ran OCR (optical character recognition) software on the images to produce PDF files • Ran spell checks to reduce errors Most of this computer work was done in Cambodia. All the PDF files are available on web site http: //techterms. net/ironwork/TAIME/ Quality is variable and some sections are missing. The resulting files can be: • searched for particular words • copy-and-pasted from • patched to make corrections

Data: article length, word counts We have constructed counts of particular words in articles, and can compare iron and steel articles to other articles, very imperfectly but systematically.

Data Exploration: Author Biographies

Thomas Kuhn’s hypothesis (from Structure of Scientific Revolutions) An established scientific paradigm (of methods, measurements, tools, and natural laws) has an agreed-on vocabulary • Precisely covering its subject • Standardized within the group • Delivered to a new group members by standard formal education As a new paradigm develops, communication involves: • inventing and exploring alternative definitions • translation between reader and writer concepts “The price is often sentences of great length and complexity. ” (Kuhn, p. 203) Claim: “early”, pre-paradigm scientific articles are long; later ones assume more, are short, and use specialized vocabulary.

Stretching Kuhn’s hypothesis to industrial technology (from science) A technological paradigm might have the same property (a working hypothesis) For example, the Big Steel “paradigm” involves • High volume, speedy, mass production • Big equipment; capital-intensive production; • Big plants; large staff employers • Chemistry and physics relevant • Centralized geographically • Contents of inputs and outputs more precisely understood • Mechanical, chemical, and industrial engineering have roles Do steel articles shrink over time? No strong evidence. We find that TAIME articles on average got a little longer over time Articles with steel words grew longer, but a little less so.

Percentages of TAIME articles years an author lists no advanced degree an author has Ph. D articles which do not have the word "Bessemer“ (~570 of these) 1871 -1875 28% 26% 1876 -1880 44% 30% 1881 -1885 59% 21% 1871 -1875 35% 26% 1876 -1880 49% 27% 1881 -1885 74% 11% steel articles (with "Bessemer") (135 of these) Related hypothesis: education of technologist becomes more formal, standardized (paradigmatic). Trends: A decreasing fraction of articles in TAIME were by people with advanced degrees. This is especially true of the Bessemer articles. Possible interpretation: This technological paradigm draws from science and is taken over by industrial engineers (unlike the airplane’s invention which was led by tinkerers not academics. ) (Or: scientists increasingly publish elsewhere. )

Kuhn idea, cont’d: We do see discussion of definitions 1875: 1880:

Paradigm shift to chemistry Bayles, 1884 quotes a letter from 1872, written by the general manager of an important iron-works: “The president of our company thinks we ought to follow the fashion and have a chemist. To my mind it is a waste of money. When I want an analysis Ican have it made—and that is very seldom; for the furnace-manager who needs a chemist to tell him the quality of ore or limestone, or whether his pig-iron is soft or hard, had better resign and go to farming. However, if the president says chemist, chemist it is. My object in writing is to know if you can recommend a young man competent to fit up a laboratory and take charge of it. We have very little society here, and it is desirable that he should be a gentleman. My wife plays the piano and I do a little on the flute; and if we can get a chemist who plays the violin, we could have some music evenings. If you can suggest a man who combines these qualifications, I could employ him. I do not know what a chemist would expect; but I should not care to pay more than $10 a week. ” A paradigm shift is happening. By 1884 the wage and capability of chemists is part of the necessary knowledge of an iron manager

Other formative discussions in TAIME • Discussion about relevant new inventions • When and whether patenting is appropriate • What makes a good rail and whether chemistry is enough • Educational institutions for iron workforce

Uncertainty hypothesis: count “uncertainty” Hypothesis: development of technology occurs in an environment of technological uncertainty, meaning its future is unknown and to some extent all the people are guessing. • Count the fraction of words in each article made up of iron-related phrases: (“hot blast”, “Bessemer”, “puddling”, “open hearth”, “Siemens”, “Martin”, “spiegel”) • Count fraction of words containing "uncert" • These counts across the 712 articles have a tiny positive correlation: . 0071. So articles with iron-related terms are slightly more likely to use literal “uncertainty” than other TAIME articles were.

Also steel articles are more likely to have “question” and “whether”

Early tentative conclusions • Some statistical evidence for a Kuhnian or uncertainty story – Maybe the big paradigm/uncertainty transition is before 1871 • Steel articles use “experiment” and “test” more than others • “Uncertainty”, “question”, “whether” are a bit more common in steel articles than others • Articles were increasingly authored by people without advanced degrees, especially Bessemer steel articles. • We are trying to count whether the authors were academics, employee engineers, or consultants • The text data and databases can improve and we plan to extend them past 1885 • Would welcome advice and comment

Advancing productive processes in layers Iron and steel, 1871 -1884 Earlier, more basic, "upstream" levels Blast furnaces making pig iron Materials science and solid state physics Bessemer and open hearth steel production Chip design and electrical engineering Iron and steel plants Railroads (transportation) Later, “downstream" levels Production of information technology goods, in recent decades Business process of railroad companies (cost accounting, personnel departments, time setting, timekeeping) Semiconductor memory and microprocessor chips Microcomputers Applications software (word processors, spreadsheets, databases, chip design software) Net software and business process (e-commerce, auctions, search engines) In both cases there were feedback processes by which downstream advances affected earlier stages of production