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Sun printing

Sun printing, commonly associated with the process, is a cameraless photographic technique that utilizes light, typically from , to expose a light-sensitive solution of iron salts applied to paper, fabric, or other absorbent materials, resulting in distinctive images with white silhouettes of placed objects. The process, invented by English astronomer Sir in 1842 as an alternative to silver-based , involves coating a surface with a mixture of ferric ammonium citrate and , arranging objects or transparencies on it, exposing it to UV light for several minutes to hours depending on conditions, and then rinsing with water to develop and fix the image. This method gained prominence through its use in scientific illustration, notably by , who in 1843 published Photographs of British : Cyanotype Impressions, the first book illustrated entirely with photographs, documenting over 400 species of algae and seaweeds over a decade. The term "" derives from cyanotypes, which were widely adopted in the 19th and early 20th centuries for architectural and engineering reproductions due to their low cost, durability, and simplicity compared to other printing methods. In and , sun printing remains popular for its accessibility, with modern kits based on the cyanotype process enabling hands-on exploration of light, chemistry, and nature, as developed by institutions like the since 1975. While variations exist, such as using light-sensitive on fabric or simple photograms with photo-reactive , the core cyanotype technique defines sun printing's historical and artistic legacy.

History

Origins and invention

Sun printing, a family of photographic processes that rely on direct exposure to to produce images without the need for a camera, emerged in the early amid the rapid advancements in . The year 1842 stands as a pivotal moment, marking the invention of several foundational techniques by the English astronomer and chemist Sir , who sought to create simple, reproducible copies of his scientific notes and diagrams using only . Herschel's most enduring contribution was the process, developed in as a straightforward method for duplicating written and drawn materials. By combining solutions of ferric ammonium citrate and , he created a light-sensitive coating that produced vivid blue images upon exposure to , offering a permanent and inexpensive alternative to earlier copying methods. This innovation was driven by Herschel's desire for a non-camera-based technique that could faithfully reproduce complex astronomical and mathematical content directly onto paper. Simultaneously, Herschel pioneered the process in 1842, experimenting with natural light-sensitive extracts from plants such as berries to form emulsions that yielded subtle, permanent images after prolonged solar exposure. These organic pigments, derived from juices rich in light-decomposing compounds, allowed for the creation of monochromatic prints that highlighted the photochemical potential of everyday botanical materials, further expanding the possibilities of sun-based imaging. Herschel also conducted early experiments with silver-based processes in 1842, including the use of silver chloride emulsions that, when coated on paper and exposed to , produced toned images serving as precursors to later techniques like brown printing. These silver salts, activated by components in , laid the groundwork for iron-silver hybrid methods that would gain prominence in subsequent decades, emphasizing the versatility of direct solar exposure in early photographic chemistry.

Early applications in science and art

One of the earliest and most influential applications of sun printing emerged in through the work of , who in 1843 self-published Photographs of British Algae: Cyanotype Impressions, the first book illustrated entirely with photographic images. These sun prints captured detailed impressions of specimens placed directly on sensitized paper and exposed to , providing accurate, scalable representations that surpassed traditional hand-drawn illustrations in precision and reproducibility for documentation. Atkins's project built on the process to create over 400 plates across multiple volumes, distributed privately to fellow scientists and marking a pivotal shift toward in scientific publishing. In scientific documentation, sun printing found practical use for replicating notes and diagrams, as demonstrated by Sir John Herschel, who invented the in 1842 and applied it to copy his astronomical observations and sketches, including material from his earlier fieldwork in . Herschel's method allowed for quick, lightfast duplicates of complex diagrams without the need for cameras, proving invaluable for astronomers and naturalists handling intricate data. Atkins, in turn, refined the technique for botanical purposes through her close collaboration with her father, John George Children, a prominent chemist and curator at the , who supported her experiments and facilitated access to scientific networks to adapt sun printing for detailed records. Early artistic experiments with sun printing extended beyond monochrome cyanotypes to explore color through contact printing methods, including William Henry Fox Talbot's photograms, which involved placing objects on light-sensitive exposed to to produce silhouette-like images akin to primitive sun prints. Complementing these, Herschel developed anthotypes around 1842, coating with plant-derived pigments such as berry juices or flower extracts to yield varied hues—ranging from reds and purples to greens—upon exposure, offering artists an organic means to capture ephemeral color impressions directly from nature. By the 1850s, sun printing techniques like cyanotypes and anthotypes had spread across , where French and German botanists adopted them for creating records, enabling precise preservation of plant specimens through direct exposures that complemented pressed collections. However, early anthotypes faced significant limitations due to their inherent instability, as the unfixed plant pigments continued to fade under prolonged light exposure, prompting experimenters like Herschel to explore rudimentary fixing agents, such as diluted salts, to stabilize images without fully resolving the .

Principles

Photochemical basics

Sun printing relies on photochemical reactions triggered by ultraviolet (UV) light in the 290-400 nm range, where photosensitive compounds absorb photons, exciting electrons and initiating reduction-oxidation (redox) processes that alter molecular structures to form visible images. These reactions typically involve the breakdown or transformation of light-sensitive species in an emulsion coated on a substrate, creating contrast between exposed and unexposed areas without the need for traditional development chemicals. In iron-based sun printing processes, UV absorption by ferric (Fe³⁺) ions in complexes such as ferric ammonium citrate leads to photoreduction to (Fe²⁺) ions. This reduction occurs through the oxidation of the coordinating , such as citrate, which decomposes to and other byproducts. The resulting Fe²⁺ ions then react with ([Fe(CN)₆]³⁻) to form insoluble (ferric ferrocyanide, Fe₄[Fe(CN)₆]₃), the characteristic deep blue pigment responsible for image visibility. The key reaction in these iron-based systems can be represented as: \text{Fe}^{3+} + \text{light (UV)} \rightarrow \text{Fe}^{2+} followed by: $4\text{Fe}^{2+} + 3[\text{Fe(CN)}_6]^{3-} \rightarrow \text{Fe}_4[\text{Fe(CN)}_6]_3 Variants may involve different ligands like , which enhance around 1.2 by facilitating efficient , but the core mechanism remains consistent. In natural pigment-based methods, UV light induces degradation of plant-derived photosensitizers such as and anthocyanins, primarily through photooxidative pathways involving (ROS) like . absorbs UV and blue light, leading to its conversion to colorless pheophytin and eventual bleaching, while anthocyanins undergo similar fading via bond cleavage and glycosylation disruptions. This selective degradation creates contrast as exposed areas lose color, revealing underlying substrates or unbleached pigments. Reaction efficiency in sun printing emulsions is influenced by exposure time, which can range from minutes to days depending on pigment stability; , where higher UV flux accelerates ; and , with optimal ranges of 2-5 for iron complexes to maintain reactive without . and also modulate these factors indirectly by affecting emulsion uniformity and .

Role of sunlight and UV exposure

Sun printing processes rely on ultraviolet (UV) radiation from to initiate the photochemical reactions that form images, with UVB (280-315 nm) and UVA (315-400 nm) wavelengths being essential drivers, while visible light alone is generally insufficient without added sensitizers. These UV bands penetrate the atmosphere and activate the light-sensitive compounds in materials like those used in cyanotypes and anthotypes, producing the characteristic color changes upon exposure. Exposure dynamics in sun printing are influenced by several variables, including seasonal intensity, which is stronger in summer due to higher solar elevation, often reducing required durations compared to winter. Typical times range from minutes in bright conditions to hours in weaker light, depending on the process and setup. plays a critical role, as can reduce UV efficiency significantly, often by 30% or more depending on thickness, necessitating extended times to achieve equivalent results. Practical setups distinguish between direct and diffused : direct yields higher and faster but can increase , whereas diffused under skies provides more even illumination at the cost of longer times. To secure objects in with the sensitized surface and minimize distortion, practitioners often use glass or UV-transmitting plastic sheets, which filter out () heat to prevent while allowing UV wavelengths to through. For controlled indoor applications, modern alternatives include UV lamps peaking at around 365 nm or sunlight simulators, enabling consistent results regardless of outdoor conditions. These sources adhere approximately to the in photochemical processes, where the total exposure effect remains constant as the product of time and intensity. Environmental factors further modulate UV availability: at higher latitudes, lower solar angles reduce intensity, while equatorial regions experience elevated levels that can accelerate printing by 20-30%. Altitude also amplifies UV , with levels increasing by about 10-12% per 1,000 meters due to thinner atmospheric filtering.

Techniques

Cyanotype is a prominent sun printing technique that produces distinctive blue images, known as blueprints, through a simple photochemical reaction involving iron salts. Invented in 1842 by Sir , it has become one of the most accessible methods for creating photograms and contact prints using . The process is particularly valued in sun printing for its straightforward preparation and development, relying on (UV) light to trigger the formation of pigment. The primary materials for the classic sensitizer are and . A 20% of is prepared by dissolving 20 grams in 100 milliliters of , while a 10% of uses 10 grams in 100 milliliters of ; these are mixed in equal parts (1:1 ratio) to form the coating , which is applied to substrates such as paper or fabric. The solutions should be prepared and the coating performed in dim light or under a to prevent premature exposure. The step-by-step process begins with evenly coating the using a , , or in subdued , ensuring full coverage without pooling. The coated material is then dried completely in the dark, typically for 1-2 hours or longer depending on , to form a yellow-green . Once dry, objects such as leaves, , or ferns are placed directly on the surface in a arrangement, or a negative is positioned for contact printing; the setup is covered with or a frame to maintain flatness and covered with a black cloth to block . occurs in direct , lasting 5-30 minutes based on UV , , and object opacity, during which the exposed areas gradually turn from green to blue while unexposed regions remain yellow. Development follows by immersing the exposed print in cold running water for 5-10 minutes, or until the water runs clear, which clears unexposed sensitizer and reveals the fully developed blue image through oxidation. The print is then briefly rinsed in distilled water to halt development and hung to dry, where the color deepens upon full oxidation. For color variations, optional toning can be applied post-development by soaking the print in a weak black tea solution (such as 5-10 tea bags in hot water, cooled), which shifts the Prussian blue to earthy browns or sepia tones through tannic acid interaction, followed by a final rinse. Cyanotype stands out for its relative non-toxicity compared to traditional silver-based photographic processes, as the chemicals—while requiring careful handling—are not as hazardous and produce no silver halides. After thorough washing, the prints exhibit excellent archival stability, resisting fading for decades when stored away from direct light and humidity, due to the insoluble nature of the pigment. Full sun exposure yields high-contrast results, with sharp delineations between shadowed and illuminated areas, enhancing the dramatic effects typical of photograms. A notable variation is the New Cyanotype formula developed by chemist Mike Ware in the 1990s, which replaces with ferric ammonium oxalate to achieve greater light sensitivity, resulting in sharper images and exposures as short as 1-5 minutes under similar conditions. This single-solution recipe maintains the core chemistry but improves contrast and detail resolution, making it suitable for finer artworks or larger prints. Common issues like yellow staining in highlights, often from overexposure or incomplete washing of excess sensitizer, can be addressed by immersing the print in a dilute clearing bath (1-2% solution) during the initial rinse to oxidize residual iron compounds and enhance clearing without affecting the blue image.

Anthotype

Anthotype is a sun printing technique that employs photosensitive emulsions derived from plant juices to create images through prolonged exposure to , relying on the differential fading of pigments in exposed areas. Invented by Sir in 1842, the process was detailed in his paper "On the Action of the Rays of the Solar Spectrum on Vegetable Colours," where he described experiments using juices from flowers like dahlias and gillyflowers to produce contact prints. This method, also explored by in her 1845 correspondence with Herschel, represents an early form of organic that avoids synthetic chemicals, emphasizing natural principles where light breaks down anthocyanins and other pigments. Materials for anthotypes consist primarily of plant-derived substances, such as juices extracted from berries, flowers, or spices, which are crushed and strained to form a light-sensitive . Common examples include for reddish tones, for yellows, for greens, and rose petals for pinks; these are typically mixed with or and painted onto absorbent substrates like . The coated must dry in complete darkness to preserve sensitivity, as even brief light exposure can initiate fading. The process begins with preparing the in subdued light, followed by arranging translucent positives or specimens directly on the dried within a contact frame to ensure sharp edges. Exposure occurs over 1 to 30 days in direct , during which unmasked areas gradually while protected sections retain their color, forming a positive image without any need for chemical development or fixing. Progress can be monitored using color charts to track degradation, though interruptions like cloudy weather extend times significantly. Unique to anthotypes is their impermanent nature, as the organic pigments continue to fade over years even in low light without stabilizers, yielding a range of hues from reds and purples to greens depending on the plant source. This fugitive quality underscores the technique's eco-friendly appeal, producing ethereal, monochromatic prints that highlight the transient effects of light on natural materials. Modern examples include spinach-based anthotypes for subtle green images or rose petal emulsions for delicate pinks, often used in educational settings to demonstrate sustainable printing. Artists have adapted the method with achiote seeds for quick exposures of about three days or blackberries for deeper tones requiring 4 to 8 weeks. Limitations of anthotype include extended exposure times that render it impractical for rapid production, variable results based on sunlight intensity and plant freshness, and the inherent instability of images, with attempts at stabilization via alcohol baths or heat treatments offering only partial success.

Van Dyke brown

The Van Dyke brown process is a contact printing technique in sun printing that utilizes a silver-iron to produce warm-toned images, developed as a modification of 19th-century kallitype methods. First documented by in 1842 and later patented in by Arndt and Troost in 1895, it derives its name from the rich brown hues reminiscent of the associated with Flemish painter . This iron-silver process involves the reduction of silver halides upon UV exposure, similar to other siderotype methods but yielding distinctive results without requiring a separate developer. The primary materials include ferric ammonium citrate, , and , prepared as separate solutions and coated sequentially onto paper substrates such as watercolor or papers. Typically, Solution A consists of 9-10 grams of ferric ammonium citrate dissolved in 30-33 ml of , Solution B uses 1.5 grams of in an equal volume of , and Solution C employs 3.8-4 grams of in 30-33 ml of ; these are combined carefully in subdued light to form the sensitizer, which is stored in dark bottles and can remain viable for months under refrigeration. Additional supplies include a brush for even coating, a high-contrast negative or for contact printing, UV exposure source, and a fixer such as 3-10% solution. The process begins with coating the paper evenly with the sensitizer in a dim room to prevent premature exposure, followed by thorough drying in the dark for 10-15 minutes. The sensitized paper is then placed in contact with a negative or objects under , such as direct , for 2-10 minutes depending on , allowing the image to form as a print-out process (POP) where exposure itself develops the . Post-exposure, the print is rinsed in running water for 2-5 minutes to remove unexposed salts, fixed in for 20 seconds to 1 minute, and washed again for 15-40 minutes to halt development and stabilize the image. For enhanced brown shades ranging from to chocolate, optional toning follows in dilute chloride solutions, such as Clerc's formula, which intensifies contrast and blacks while shifting tones toward warmer reds or neutrals. The print is then dried naturally, often overnight, to achieve its final deep brown appearance. Unique to the are its warm tonal range from light tan highlights to deep shadows, offering greater subtlety in gradations compared to the more uniform blues of prints. As a contact method, it excels in capturing fine details from objects or negatives, providing sharp resolution suitable for intricate botanical or architectural subjects. The is notably simple and cost-effective, requiring no facilities beyond basic trays and UV access, making it accessible for both historical replication and contemporary experimentation. Variations include adjustments for contrast through extended times or varied durations in the fixer, allowing over without additional chemicals. applications, such as overexposing a pre-made base for 20-30 minutes to layer brown tones, create abstract effects with desaturated blues and enhanced depth. Historically, the process gained popularity in the 1890s following its , particularly for portraiture and prints due to its elegant brown tones and ease of use in contact setups. It has seen revival in modern alternative photography workshops, where it serves as an educational tool for exploring early photographic chemistry and sustainable printing practices.

Dichromate-based methods

Dichromate-based methods, particularly gum bichromate printing, utilize the light-hardening properties of dichromate salts combined with and s to produce textured, relief-like sun prints. These processes emerged in the mid-19th century as an alternative to silver-based , allowing for durable, multi-color images through subtractive techniques. The core principle involves the insolubilization of the gum upon exposure, enabling the creation of raised areas that form the image after . The primary materials include or , typically prepared as a 5-13% solution in , mixed with (a natural derived from trees, often at 20% concentration) and water-soluble pigments such as watercolors or cadmium-based colors for vibrant hues. This emulsion is brushed onto sized , such as gelatin- or AKD-sized sheets, to ensure even adhesion and prevent bleeding during development. is preferred for its stability and lower toxicity compared to , though both require careful handling. In the process, the is applied in one or more layers, dried in the dark for 30-60 minutes, and then exposed to direct or UV for 10-60 minutes, depending on and layer depth, using a contact frame with a negative or physical objects for photograms. Upon , the dichromate cross-links the gum , rendering exposed areas insoluble in water and creating a structure where adheres selectively. The print is then developed by immersing in lukewarm for 5-30 minutes, gently agitating or brushing to dissolve and remove unhardened gum and excess dichromate, revealing a textured image with varying thickness corresponding to . Multiple coatings—often in , , and —can be registered and exposed sequentially to build full-color prints, with each layer contributing to depth and tonal range. A key unique aspect is the subtractive nature of the , where UV from hardens the dichromate-gum progressively from the surface downward, allowing for selective formation and artistic manipulation during ; this contrasts with additive processes by emphasizing material removal to highlight highlights and midtones. The method's forgiving quality permits corrections, such as re-coating softened areas with vapor, and supports creative brushstrokes for painterly effects. However, the toxicity of dichromates necessitates good , gloves, and during mixing and coating to avoid skin absorption or . Variations include single-layer applications for simple monochromatic photograms, where objects are placed directly on the for direct , producing high-contrast silhouettes. As a precursor to carbon , gum bichromate adaptations use pigmented tissue on flexible supports to achieve deep blacks and continuous tones, though carbon typically employs instead of for finer grain. Modern practices explore non-toxic substitutes like stilbazolium quaternized (SbQ) sensitizers or diazidostilbene-2,2'-disulfonic acid () to replace dichromates, reducing carcinogenicity while maintaining similar hardening mechanisms; these alternatives are particularly adopted in regions with strict chemical regulations. Dichromates are classified as probable carcinogens by health authorities, prompting their phased restriction in artistic processes.

Vat dye printing

Vat dye printing utilizes reduced forms of vat dyes, such as or synthetic and anthraquinone-based dyes, which are sensitized with to create a soluble leuco compound for application to natural fabrics like or . These dyes are inherently water-insoluble in their oxidized state but become soluble and colorless in the reduced leuco form, allowing penetration into the fabric fibers before fixation. The process begins by immersing or brushing the fabric with the reduced solution in low to prevent premature oxidation. Objects, stencils, or film negatives are then placed in contact with the coated fabric to act as resists, and the assembly is exposed to direct , where rays selectively oxidize the dye in light-struck areas, converting it to its vibrant, insoluble colored form. Unexposed regions retain the , which is subsequently removed by washing with a mild or specialized fixer, such as sodium hydrosulfite-based solutions, yielding permanent patterns on the cloth. Exposure times typically range from 30 minutes to several hours, depending on intensity and dye concentration, with optimal results achieved midday under clear skies. This method produces highly colorfast, insoluble pigments in shades like deep blues from or greens from synthetic variants, ideal for creating batik-like effects or photograms on without requiring steaming or chemical developers. In the leuco form, the dyes enable precise selective oxidation through , and variations often incorporate stencils or natural resists for intricate patterns, enhancing artistic versatility in fabric design. Emerging in 20th-century , the builds on synthetic commercialized by the since the early 1900s, such as indanthrene introduced in 1901. The oxidation process aligns with photochemical principles where accelerates the re-conversion of leuco compounds to their stable, pigmented state.

Materials and preparation

Common chemicals and substrates

Sun printing techniques rely on a variety of substrates that can effectively hold light-sensitive emulsions while allowing for clear image development. Common substrates include watercolor paper, which provides a textured surface ideal for detailed prints; cotton fabric, valued for its absorbency and durability in textile applications; and transparency film, used for creating reusable negatives or overlays. To enhance emulsion adhesion, especially on absorbent papers, substrates are often sized with arrowroot starch, which forms a thin, even layer that prevents excessive spreading during coating. The chemicals used in sun printing are selected for their photosensitivity to UV light and compatibility with different techniques. Iron salts, such as ferric ammonium citrate combined with , form the basis of emulsions, producing the characteristic blue tones upon exposure. brown processes employ ferric ammonium citrate, , and to yield warm brown images. Anthotypes utilize natural plant extracts, for instance, crushing 15g of blackcurrants or juicing a handful of leaves to prepare the emulsion from flowers, leaves, or fruits for their light-sensitive pigments such as anthocyanins or . Dichromate-based methods, such as gum bichromate, incorporate 5-10% solutions of or mixed with and water-soluble pigments to create layered, color prints. Vat dye printing involves reduced forms of dyes like , using agents such as to prepare soluble vats for application on fabrics. Sourcing these materials is straightforward through specialized suppliers. Cyanotype kits, including pre-measured iron salts, are readily available from art supply stores like Jacquard Products or Photographers' Formulary. Silver nitrate and other lab-grade compounds for or silver-based processes can be obtained from chemical suppliers such as Bostick & Sullivan. emulsions are typically prepared at home by extracting juices from garden or foraged plants, requiring no commercial purchase beyond basic kitchen tools. Supporting tools include soft brushes for even application of emulsions, shallow trays for mixing and rinsing, and UV-blocking envelopes to preserve unexposed coated substrates from premature . In terms of cost and accessibility, a basic kit typically costs $20-50 as of 2025 and can produce up to 50 8x10-inch prints, making it an economical entry point. Silver-based processes are generally more expensive than iron-based methods due to the additional requirement of fixers like .

Safety and environmental considerations

Sun printing techniques involve chemicals that pose health risks, particularly dichromate compounds used in processes like gum bichromate and printing. is highly toxic and acts as a probable , with contact causing severe burns, ulceration, and allergic reactions, while of dust or fumes can lead to lung damage and increased cancer risk. , employed in salt printing and related methods, is corrosive and light-sensitive, staining black upon contact and potentially causing burns or blindness if it reaches the eyes. Proper handling mitigates these hazards through standard protective measures. Practitioners should wear nitrile gloves, safety goggles, and work in well-ventilated spaces to avoid skin absorption, eye exposure, and inhalation. For disposal, dichromate waste must be neutralized by adding to reduce (Cr(VI)) to the less toxic trivalent form (Cr(III)) before sewer release, following local regulations. Environmentally, sun printing's impact varies by method, with non-toxic options like anthotypes—using plant juices as sensitizers—and cyanotypes preferred for their minimal and biodegradability. Silver-containing fixers from processes like salt printing should be recycled to recover silver and prevent , as even low concentrations harm aquatic life. Avoid direct dumping of any into natural bodies of water to protect ecosystems. Regulatory guidelines emphasize strict controls on dichromate use. The (OSHA) sets a (PEL) of 0.005 mg/m³ for in air, averaged over an 8-hour workday, to minimize occupational health risks. Eco-alternatives, such as plant-based sensitizers derived from proteins like lupin or anthocyanin-rich dyes, are gaining adoption as less-toxic substitutes for dichromate in bichromate processes. For educational settings, child-safe sun printing avoids chemicals altogether by leveraging on , where sunlight fades exposed areas while objects shield designs, requiring only direct sun exposure for 4-6 hours. This method promotes safe, hands-on learning about UV light without handling sensitizers.

Applications and legacy

Historical uses

Sun printing techniques, particularly the process, played a pivotal role in 19th- and early 20th-century scientific documentation and reproduction. From the 1870s onward, architects and extensively used cyanotypes to create blueprints, enabling the rapid and cost-effective duplication of technical drawings on or other supports. This application revolutionized architectural and practices by producing durable, monochromatic images through contact exposure to sunlight, eliminating the labor-intensive engraving methods of prior eras. In , employed cyanotypes to meticulously record and other plant specimens in her seminal 1843 publication, Photographs of British Algae: Cyanotype Impressions, which is recognized as the first book illustrated entirely with photographic images. The Royal Botanic Gardens at further utilized cyanotypes for preserving and cataloging botanical records, leveraging the process's simplicity and fidelity for scientific study and archival purposes. Industrial applications of sun printing extended to the production of permanent records in fields like and . Carbon printing, a dichromate-sensitized gelatin process exposed to , was employed to generate high-quality, fade-resistant images for maps and technical diagrams during the late 19th and early 20th centuries, offering superior longevity compared to earlier silver-based methods. A significant advancement came in when Henri Pellet, working with Alphonse Poitevin, patented an improved blueprinting variant of the process, which enhanced its viability for widespread industrial reproduction of plans and schematics. In documentation contexts, sun printing served practical roles in military and archival efforts. During World War I, frontline units applied cyanotype blueprinting to duplicate trench maps by placing transparent drawings over sensitized paper and exposing them directly to sunlight, providing quick copies essential for tactical operations without access to darkroom facilities. The prominence of sun printing waned in the early 20th century as it was supplanted by faster-developing film photography and, from the 1930s, by diazo whiteprint processes that avoided water washing and produced positive images more efficiently.

Modern artistic and educational practices

In , sun printing techniques such as and continue to inspire artists who explore themes of nature, decay, and human intervention through experimental applications. For instance, Iranian artist Gohar Dashti employs to create the "" series, where organic materials like leaves and filaments are used to produce fragmented images evoking physical decay, drawing from her experiences of war-torn environments. Similarly, British artist Joy Gregory integrates and prints in her 2020 project "Invisible Life Force of Plants," examining the historical role of plants in from the 17th to 19th centuries, using natural pigments to highlight ecological narratives. These works often extend beyond traditional paper substrates, incorporating fabrics and translucent materials to blend with and . Other artists push the boundaries of sun printing by merging it with modern media. French artist Alix Marie transfers found images onto large-scale translucent fabrics via in her "Styx" project, connecting ancient Greek mythology with contemporary to explore themes of the body and the underworld. British specialist Chloe McCarrick experiments with large-format prints on diverse surfaces, including ceramics and textiles, to investigate and botanical forms in her ongoing series. Events like World Cyanotype Day, celebrated annually since 2015, foster a global community of artists sharing innovations, such as combining sun printing with digital negatives or eco-dyes for mixed-media pieces. In educational settings, sun printing serves as an accessible entry point for teaching , , and , particularly through hands-on workshops and curricula designed for K-12 students. The Museum's educational program introduces as a cameraless process, where learners place objects on photosensitive paper and expose it to to create blue-toned images, linking the to 19th-century botanical while emphasizing light's chemical effects. Similarly, the Botanical Garden's workshops guide participants in coating materials with solution using plants, integrating with to demonstrate and UV light interactions. School-based activities often incorporate commercial kits like SUNPRINT® from the , which enable students to produce solar prints without access, promoting STEAM (science, technology, , , and math) learning by exploring light sensitivity and natural patterns. University-level programs, such as those at University's College of Fine Arts, teach alongside Van Dyke brown methods in solar art courses, encouraging students to create site-specific installations that address through ephemeral, sunlight-dependent works. These practices not only build technical skills but also cultivate appreciation for sustainable, low-tech art forms, with lesson plans from institutions like the focusing on object arrangement and exposure timing to yield quantifiable results in image contrast and color development.

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