Anthotype

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Rhododendron leaf and ivy leaf on photo paper for printers, sensitized with beetroot juice 10x15 cm
Maple leaf, anthotype with sour cherry juice, 2 h exposure time at high noon in summer time

An anthotype (from Greek άνθος anthos "flower" and τύπος týpos "imprint", also called Nature Printing) is an image created using photosensitive material from plants under the influence of light (e.g. UV light, rays of sun).[1]

An emulsion[2][3] is made from crushed flower petals or any other light-sensitive plant, fruit or vegetable.

A sheet of paper is covered with the emulsion, and then it is dried.

Some leaves, a transparent photo positive or other material is placed on the paper; and then it is exposed to direct full sunlight until the image part not covered by the material is bleached out by the sun rays.

The original color remains in the shadowed parts depending on the exposure. The paper remains sensitive against such rays. It cannot be fixed.

Note: The color of anthocyanidins, anthocyans, carotinoids, and other light sensitive plant material may depend on PH of the water and of the paper.[4]

History[edit]

The photo-sensitive properties of plants and vegetables have been known to scholars for centuries. Among many early observations the experiments of Henri August Vogel in Paris are of particular interest. In 1816 he discovered that an alcoholic tincture of either red carnations, violets or corn poppy turned white behind blue glass in a few days, while it remained unchanged behind red glass after about the same time. Cotton and paper colored with these tinctures exhibited the same differences.

The anthotype process was discovered in 1839 by Sir John Herschel.[5] Herschel referenced an experiment on October 11, 1839 in a paper published in 1840 at the Philosophical Transactions of the Royal Society of London.[6] Herschel gave the anthotype process a proper introduction in his 1842 paper to the same institution.[7] Mary Somerville built on Herschel's research and documented it in a letter to him dated 1845. Sir John Herschel presented her findings to the Royal Society, giving her full credit in his 1845 paper.[8]

Herschel's research into making photographic images from flowers was limited and was ultimately abandoned since no commercial application was feasible from a process which takes days to produce an image.[citation needed]

The process continued to be listed in photographic literature of the time but was likely little used.

Over time the process earned a reputation for being too impractical. Image permanence have been brought into question, but this problem seems to be mostly related to choice of flower or plant matter.[citation needed]

How it works[edit]

From an examination of the researches of Sir John Herschel on the coloring matter of plants, it will be seen that the action of the sun's rays is to destroy the color, effecting a sort of chromatic analysis, in which two distinct elements of color are separated, by destroying the one and leaving the other. The action is confined within the visible spectrum, and thus a broad distinction is exhibited between the action of the sun's rays on vegetable juices and on argentine compounds, the latter being most sensibly affected by the invisible rays beyond the violet. It may also be observed, that the rays effective in destroying a given tint, are in a great many cases, those whose union produces a color complementary to the tint destroyed, or, at least, one belonging to that class of colors to which such complementary tint may be preferred. For instance, yellows tending towards orange are destroyed with more energy by the blue rays; blues by the red, orange and yellow rays; purples and pinks by yellow and green rays.

— Henry H. Snelling[9]

Other flower suggestions[edit]

Henry H. Snelling writes based on his research: "Viola odorata--or sweet scented violet, yields to alcohol a rich blue color, which it imparts in high perfection to paper. Senecio Splendens -- or double purple groundsel, yields a beautiful color to paper."

Bingham, quoting by Sir John Herschel, recommends Corchorus japonicus flower (japanese Jute) for a "fine yellow colour" that "upon exposure to sunlight, it is in about half an hour rendered quite white".[10]

References[edit]

  1. ^ https://www.alternativephotography.com/anthotypes/ |Malin Fabbri, Anthotypes – Explore the darkroom in your garden and make photographs using plants, January 1, 2021 by Malin Fabbri
  2. ^ https://www.alternativephotography.com/anthotype-emulsions-1/, Anthotype Emulsions, Volume 1, October 29, 2022, by Malin Fabbri
  3. ^ https://www.alternativephotography.com/anthotype-emulsions-2/, Anthotype Emulsions, Volume 2, September 27, 2023, by Malin Fabbri
  4. ^ Khoo, Hock Eng; Azlan, Azrina; Tang, Sou Teng; Lim, See Meng (13 August 2017). "Anthocyanidins and anthocyanins: colored pigments as food, pharmaceutical ingredients, and the potential health benefits". Food & Nutrition Research. 61 (1): 1361779. doi:10.1080/16546628.2017.1361779. PMC 5613902. PMID 28970777.
  5. ^ "Did Sir John Herschel or MRS Mary Somerville discover anthotypes?". 10 December 2023.
  6. ^ "I. On the chemical action of the rays of the solar spectrum on preparations of silver and other substances, both metallic and non-metallic, and on some photographic processes". Philosophical Transactions of the Royal Society of London. 130: 1–59. 1840. doi:10.1098/rstl.1840.0002. S2CID 98119765.
  7. ^ Herschel, John F. W. (1842). "On the Action of the Rays of the Solar Spectrum on Vegetable Colours, and on Some New Photographic Processes". Philosophical Transactions of the Royal Society of London. 132: 181–214. Bibcode:1842RSPT..132..181H. JSTOR 108152.
  8. ^ "VIII. On the action of the rays of the spectrum on vegetable juices. Extract of a letter from MRS. M. Somerville to Sir J. F. W. Herschel, Bart., dated Rome, September 20, 1845. Communicated by Sir J. Herschel". Philosophical Transactions of the Royal Society of London. 136: 111–120. 1846. doi:10.1098/rstl.1846.0009. S2CID 109196456.
  9. ^ "History and Practice of the Art of Photography - Chapter III". G. P. Putnam, New York. 1849. Retrieved 2020-09-09.
  10. ^ Bingham, Robert J. (1847). Photogenic manipulation. containing the theory and plain instructions in the art of photography, or the production of pictures through the agency of light : including calotype, fluorotype, ferrotype, chromotype, chrysotype, cyanotype, catalissisotype and anthotype. Getty Research Institute. London : George Knight and Sons. p. 63.
  • Heritage-Tilley, Clive.
  • Snelling, Henry H. The History and Practice of the Art of Photography. New York, 1849.
  • Eder, Josef. The History of Photography. Dover Press, 1978

External links[edit]