Hygroscopy Explained

Hygroscopy is the phenomenon of attracting and holding water molecules via either absorption or adsorption from the surrounding environment, which is usually at normal or room temperature. If water molecules become suspended among the substance's molecules, adsorbing substances can become physically changed, e.g. changing in volume, boiling point, viscosity or some other physical characteristic or property of the substance. For example, a finely dispersed hygroscopic powder, such as a salt, may become clumpy over time due to collection of moisture from the surrounding environment.

Deliquescent materials are sufficiently hygroscopic that they dissolve in the water they absorb, forming an aqueous solution.

Hygroscopy is essential for many plant and animal species' attainment of hydration, nutrition, reproduction and/or seed dispersal. Biological evolution created hygroscopic solutions for water harvesting, filament tensile strength, bonding and passive motion – natural solutions being considered in future biomimetics.[1]

Etymology and pronunciation

The word hygroscopy uses combining forms of hygro- and -scopy. Unlike any other -scopy word, it no longer refers to a viewing or imaging mode. It did begin that way, with the word hygroscope referring in the 1790s to measuring devices for humidity level. These hygroscopes used materials, such as certain animal hairs, that appreciably changed shape and size when they became damp. Such materials were then said to be hygroscopic because they were suitable for making a hygroscope. Eventually, the word hygroscope ceased to be used for any such instrument in modern usage, but the word hygroscopic (tending to retain moisture) lived on, and thus also hygroscopy (the ability to do so). Nowadays an instrument for measuring humidity is called a hygrometer (hygro- + -meter).

History

Early hygroscopy literature began circa 1880.[2] Studies by Victor Jodin (Annales Agronomiques, October 1897) focused on the biological properties of hygroscopicity.[3] He noted pea seeds, both living and dead (without germinative capacity), responded similarly to atmospheric humidity, their weight increasing or decreasing in relation to hygrometric variation.

Marcellin Berthelot viewed hygroscopicity from the physical side, a physico-chemical process. Berthelot's principle of reversibility, briefly- that water dried from plant tissue could be restored hygroscopically, was published in "Recherches sur la desiccation des plantes et des tissues végétaux; conditions d'équilibre et de réversibilité," (Annales de Chimie et de Physique, April 1903).

Léo Errera viewed hygroscopicity from perspectives of the physicist and the chemist. His memoir "Sur l'Hygroscopicité comme cause de l'action physiologique à distance" (Recueil de l'lnstitut Botanique Léo Errera, Université de Bruxelles, tome vi., 1906) provided a hygroscopy definition that remains valid to this day. Hygroscopy is "exhibited in the most comprehensive sense, as displayed

Overview

Hygroscopic substances include cellulose fibers (such as cotton and paper), sugar, caramel, honey, glycerol, ethanol, wood, methanol, sulfuric acid, many fertilizer chemicals, many salts (like calcium chloride, bases like sodium hydroxide etc.), and a wide variety of other substances.[4]

If a compound dissolves in water, then it is considered to be hydrophilic.

Zinc chloride and calcium chloride, as well as potassium hydroxide and sodium hydroxide (and many different salts), are so hygroscopic that they readily dissolve in the water they absorb: this property is called deliquescence. Not only is sulfuric acid hygroscopic in concentrated form but its solutions are hygroscopic down to concentrations of 10% v/v or below. A hygroscopic material will tend to become damp and cakey when exposed to moist air (such as the salt inside salt shakers during humid weather).

Because of their affinity for atmospheric moisture, desirable hygroscopic materials might require storage in sealed containers. Some hygroscopic materials, e.g., sea salt and sulfates, occur naturally in the atmosphere and serve as cloud seeds, cloud condensation nuclei (CCNs). Being hygroscopic, their microscopic particles provide an attractive surface for moisture vapour to condense and form droplets. Modern-day human cloud seeding efforts began in 1946.[5]

When added to foods or other materials for the express purpose of maintaining moisture content, hygroscopic materials are known as humectants.

Materials and compounds exhibit different hygroscopic properties, and this difference can lead to detrimental effects, such as stress concentration in composite materials. The volume of a particular material or compound is affected by ambient moisture and may be considered its coefficient of hygroscopic expansion (CHE) (also referred to as CME, or coefficient of moisture expansion) or the coefficient of hygroscopic contraction (CHC)—the difference between the two terms being a difference in sign convention.

Differences in hygroscopy can be observed in plastic-laminated paperback book covers—often, in a suddenly moist environment, the book cover will curl away from the rest of the book. The unlaminated side of the cover absorbs more moisture than the laminated side and increases in area, causing a stress that curls the cover toward the laminated side. This is similar to the function of a thermostat's bimetallic strip. Inexpensive dial-type hygrometers make use of this principle using a coiled strip. Deliquescence is the process by which a substance absorbs moisture from the atmosphere until it dissolves in the absorbed water and forms a solution. Deliquescence occurs when the vapour pressure of the solution that is formed is less than the partial pressure of water vapour in the air.

While some similar forces are at work here, it is different from capillary attraction, a process where glass or other solid substances attract water, but are not changed in the process (e.g., water molecules do not become suspended between the glass molecules).

Deliquescence

Deliquescence, like hygroscopy, is also characterized by a strong affinity for water and tendency to absorb moisture from the atmosphere if exposed to it. Unlike hygroscopy, however, deliquescence involves absorbing sufficient water to form an aqueous solution. Most deliquescent materials are salts, including calcium chloride, magnesium chloride, zinc chloride, ferric chloride, carnallite, potassium carbonate, potassium phosphate, ferric ammonium citrate, ammonium nitrate, potassium hydroxide, and sodium hydroxide. Owing to their very high affinity for water, these substances are often used as desiccants, which is also an application for concentrated sulfuric and phosphoric acids. Some deliquescent compounds are used in the chemical industry to remove water produced by chemical reactions (see drying tube).[6]

Biology

Hygroscopy appears in both plant and animal kingdoms, the latter benefiting via hydration and nutrition. Some amphibian species secrete a hygroscopic mucus that harvests moisture from the air. Orb web building spiders produce hygroscopic secretions that preserve the stickiness and adhesion force of their webs. One aquatic reptile species is able to travel beyond aquatic limitations, onto land, due to its hygroscopic integument.

Plants benefit from hygroscopy via hydration and reproduction – demonstrated by convergent evolution examples. Hygroscopic movement (hygrometrically activated movement) is integral in fertilization, seed/spore release, dispersal and germination. The phrase "hygroscopic movement" originated in 1904's "Vorlesungen Über Pflanzenphysiologie", translated in 1907 as "Lectures on Plant Physiology" (Ludwig Jost and R.J. Harvey Gibson, Oxford, 1907).[7] When movement becomes larger scale, affected plant tissues are colloquially termed hygromorphs.[8] Hygromorphy is a common mechanism of seed dispersal as the movement of dead tissues respond to hygrometric variation,[9] e.g. spore release from the fertile margins of Onoclea sensibilis. Movement occurs when plant tissue matures, dies and desiccates, cell walls drying, shrinking;[10] and also when humidity re-hydrates plant tissue, cell walls enlarging, expanding. The direction of the resulting force depends upon the architecture of the tissue and is capable of producing bending, twisting or coiling movements.

Hygroscopic hydration examples

File:Air Plant (Tillandsia bulbosa) (8307461501).jpg|Air plant (Tillandsia bulbosa)File:File snake (Acrochordus granulatus).jpg|The aquatic file snake (A. granulatus) with hygroscopic skin, shown out of waterFile:Herbstspinne445.JPG|An orb-weaver spider (Larinioides cornutus) with hygroscopic coated capture threadsFile:Makifrosch-59.jpg|Waxy monkey tree frog (Phyllomedusa sauvagii)

Hygroscopic-assisted propagation examples

Typical of hygroscopic movement are plant tissues with "closely packed long (columnar) parallel thick-walled cells (that) respond by expanding longitudinally when exposed to humidity and shrinking when dried (Reyssat et al., 2009)". Cell orientation, pattern structure (annular, planar, bi-layered or tri-layered) and the effects of the opposite-surface's cell orientation control the hygroscopic reaction. Moisture responsive seed encapsulations rely on valves opening when exposed to wetting or drying; discontinuous tissue structures provide such predetermined breaking points (sutures), often implemented via reduced cell wall thickness or seams within bi- or tri-layered structures. Graded distributions varying in density and/or cell orientation focus hygroscopic movement, frequently observed as biological actuators (a hinge function); e.g. pinecones (Pinus spp.), the ice plant (Aizoaceae spp.) and the wheat awn (Triticum spp.),[19] described below.

Two angiospermae families have similar methods of dispersal, though method of implementation varies within family: Geraniaceae family examples are the common stork's-bill (Erodium cicutarium) and geraniums (Pelargonium sp.); Poaceae family, Needle-and-Thread (Hesperostipa comata) and wheat (Triticum spp.). All rely upon a bi-layered parallel fiber hygroscopic cell physiology to control the awn's movement for dispersal and self-burial of seeds. Alignment of cellulose fibrils in the awn's controlling cell wall determines direction of movement. If fiber alignments are tilted, non-parallel venation, a helix develops and awn movement becomes twisting (coiling) instead of bending; e.g. coiling occurs in awns of Erodium, and Hesperostipa.[28]

Engineering properties

Hygroscopicity is a general term used to describe a material's ability to absorb moisture from the environment.[30] There is no standard quantitative definition of hygroscopicity, so generally the qualification of hygroscopic and non-hygroscopic is determined on a case-by-case basis. For example, pharmaceuticals that pick up more than 5% by mass, between 40 and 90% relative humidity at 25 °C, are described as hygroscopic, while materials that pick up less than 1%, under the same conditions are regarded as non-hygroscopic.[31]

The amount of moisture held by hygroscopic materials is usually proportional to the relative humidity. Tables containing this information can be found in many engineering handbooks and is also available from suppliers of various materials and chemicals.

Hygroscopy also plays an important role in the engineering of plastic materials. Some plastics, e. g. nylon, are hygroscopic while others are not.

Polymers

Many engineering polymers are hygroscopic, including nylon, ABS, polycarbonate, cellulose, carboxymethyl cellulose, and poly(methyl methacrylate) (PMMA, plexiglas, perspex).

Other polymers, such as polyethylene and polystyrene, do not normally absorb much moisture, but are able to carry significant moisture on their surface when exposed to liquid water.[32]

Type-6 nylon (a polyamide) can absorb up to 9.5% of its weight in moisture.[33]

Applications in baking

The use of different substances' hygroscopic properties in baking are often used to achieve differences in moisture content and, hence, crispiness. Different varieties of sugars are used in different quantities to produce a crunchy, crisp cookie (British English: biscuit) versus a soft, chewy cake. Sugars such as honey, brown sugar, and molasses are examples of sweeteners used to create moister and chewier cakes.[34]

Research

Several hygroscopic approaches to harvest atmospheric moisture have been demonstrated and require further development to assess their potentials as a viable water source.

Hygroscopic glues are candidates for commercial development. The most common cause of synthetic glue failure at high humidity is attributed to water lubricating the contact area, impacting bond quality. Hygroscopic glues may allow more durable adhesive bonds by absorbing (pulling) inter-facial environmental moisture away from the glue-substrate boundary.

Integrating hygroscopic movement into smart building designs and systems is frequently mentioned, e.g. self-opening windows. Such movement is appealing, an adaptive, self-shaping response that requires no external force or energy. However, capabilities of current material choices are limited. Biomimetic design of hygromorphic wood composites and hygro-actuated building systems have been modeled and evaluated.[36]

See also

External links

Notes and References

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  2. Book: Parker . Phillip M. . Hygroscopic: Webster's Timeline History, 1880 - 2007 . May 17, 2010 . ICON Group International, Inc..
  3. Book: Guppy . Henry B. . Studies in Seeds and Fruits . 1912 . Williams and Norgate . London, England . 147–150 . 5 February 2023.
  4. Web site: Hygroscopic compounds. hygroscopiccycle.com. IBERGY. April 7, 2017. April 8, 2017. https://web.archive.org/web/20170408000150/http://www.hygroscopiccycle.com/hygroscopic-compounds/. live.
  5. Pelley . Janet . Does cloud seeding really work? . Chemical & Engineering News . May 30, 2016 . 94 . 22 . 29 January 2023.
  6. Wells . Mickey . Wood . Daniel . Sanftleben . Ronald . Shaw. Kelley . Hottovy . Jeff . Weber . Thomas . Geoffroy . Jean-Marie . Alkire . Todd . Emptage. Sarabia . Rafael . Potassium carbonate as a desiccant in effervescent tablets . International Journal of Pharmaceutics . June 1997 . 152 . 2 . 227–235 . 10.1016/S0378-5173(97)00093-8.
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  8. Reyssat . E. . Mahadevan . L. . Hygromorphs: from pine cones to biomimetic bilayers . Journal of the Royal Society Interface . July 1, 2009 . 6 . 39 . 951–957 . 10.1098/rsif.2009.0184 . The Royal Society Publishing. 19570796 . 2838359 .
  9. Watkins, Jr . James E . Testo . Weston L . Close observation of a common fern challenges long-held notions of how plants move. A commentary on 'Fern fronds that move like pine cones: humidity-driven motion of fertile leaflets governs the timing of spore dispersal in a widespread fern species' . Annals of Botany . 11 April 2022 . 129 . 5 . i-iii . 10.1093/aob/mcac017 . 35211726 . 9007092 . 23 February 2023.
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  11. Ni . Feng . Qiu . Nianxiang . Xiao . Peng . Zhang . Chang Wei . Jian . Yukun . Liang . Yun . Xie . Weiping . Yan . Luke . Chen . Tao . Tillandsia-Inspired Hygroscopic Photothermal Organogels for Efficient Atmospheric Water Harvesting . Angewandte Chemie International Edition . July 2020 . 59 . 43 . 19237–19246 . 10.1002/anie.202007885 . 33448559 . 225188835 . 26 January 2023.
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  14. Comanns . Philipp . Passive water collection with the integument: mechanisms and their biomimetic potential . Journal of Experimental Biology . May 2018 . 221 . 10 . Table 1 . 10.1242/jeb.153130. 29789349 . 46893569 . free .
  15. Comanns . Philipp . Passive water collection with the integument: mechanisms and their biomimetic potential . Journal of Experimental Biology . May 2018 . 221 . 10 . 10.1242/jeb.153130. 29789349 . 46893569 . free .
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  17. Hyde . E. O. C. . The Function of the Hilum in Some Papilionaceae in Relation to the Ripening of the Seed and the Permeability of the Testa . Annals of Botany . April 1954 . 18 . 70 . 241–256 . 11 February 2023 . Oxford University Press. 10.1093/oxfordjournals.aob.a083393 . 42907240 .
  18. Web site: AskNature Team . Valve Regulates Water Permeability: Tree lupin . March 23, 2020 . asknature.org . The Biomimicry Institute . 10 February 2023.
  19. Brulé . Véronique . Rafsanjani . Ahmad . Asgari . Meisam . Western . Tamara L. . Pasini . Damiano . Three-dimensional functional gradients direct stem curling in the resurrection plant Selaginella lepidophylla . Journal of the Royal Society Interface . October 2019 . 16 . 159 . 10.1098/rsif.2019.0454 . 31662070 . 6833318 .
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  34. Sloane, T. O'Conor. Facts Worth Knowing Selected Mainly from the Scientific American for Household, Workshop, and Farm Embracing Practical and Useful Information for Every Branch of Industry. Hartford: S. S. Scranton and Co. 1895.
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