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Thermal paper (often supplied in roll form, and sometimes referred to as anaudit roll) is aspecial fine paper that is coated with a material formulated to change color locally when exposed to heat. It is used inthermal printers, particularly in inexpensive devices such asadding machines,cash registers, andcredit card terminals and small, lightweight portable printers.

The surface of the paper is coated with a substance which changes color when heated above a certain temperature. The printer essentially consists of a transport mechanism which drags the paper across a thermaldot matrixprint head. The (very small) dots of the head heat up very quickly to imprint a dot, then cool equally quickly.

Most thermal papers' coatings turn black when heated, but coatings that turn blue or red, and multicolor coatings, are sometimes used. An unintended heat source, such as a coffee cup, can discolour the paper and obscure any printing. A fingernail rubbed quickly across the paper may generate enough heat from friction to produce a mark.

The earliest direct thermal papers were developed byNCR Corporation (using dye chemistry) and3M (using metallic salts). The NCR technology became the market leader over time, although the image would fade rather rapidly compared with the much more expensive, but durable 3M technology.

Texas Instruments invented the thermal print head in 1965, and theSilent 700, a computer terminal with a thermal printer, was released in the market in 1969. The Silent 700 was the first thermal print system that printed on thermal paper. During the 1970s,Hewlett-Packard integrated thermal paper printers into the design of itsHP 9800 series desktop computers, and integrated it into the top of the 2600-series CRT terminals as well as in plotters.

In the 1970s and early 1980s, Japanese producers includingRicoh, Jujo, and Kanzaki, using similardye-based chemistry, formed partnerships withbarcode printer manufacturers including TEC and Sato and entered the emerging global bar code industry, primarily for supermarket receipt printers. U.S. producers including Appleton (NCR's license),Nashua Corporation, andGraphic Controls fought for market share. Users ofpressure-sensitive label such as those made byAvery Dennison became major consumers of direct thermal label stock.

In the late 1980s and early 1990s,thermal transfer (distinct from direct thermal, and stable),laser printing,electrophotography, and, to a lesser extent,inkjet printing began to take away industrial and warehouse barcode applications due to better stability and durability of prints. Direct thermal made a strong comeback with point-of-sale receipt printing.

During 1998,Nintendo used thermal paper technology for theirGame Boy Printer.

The printer essentially consists of a transport mechanism which drags the paper across a thermaldot matrixprint head.^[1] The (very small) dots of the head heat up very quickly to imprint a dot, then cool equally quickly.

Four different types of imaging chemicals are used in thermally sensitive papers: leuco dyes, developers, sensitizers and stabilizers.^[2]

Leuco dyes

Theleuco dyes used in direct thermal paper are usually triaryl methane phthalide dyes, such as Yamamoto Blue 4450, or fluoran dyes, such as Pergascript Black 2C. A third widely used leuco dye isCrystal violet lactone. Red or magenta color can be achieved with dyes such as Yamamoto Red 40. Yellow can be produced by the protonation of a triaryl pyridine, such as Copikem Yellow 37. These dyes have a colorless leuco form when crystalline or when in a pH neutral environment, but become colored when dissolved in a melt and exposed to an acidic environment.

Developers

Leuco dyes, in general, provide little color when melted unless they are melted in conjunction with one or more organic acids. Examples of organic acids suitable for thermochromic papers are phenols such asBisphenol A (BPA) andBisphenol S (BPS). Other suitable acidic materials are sulfonyl ureas such as BTUM and Pergafast 201. Zinc salts of substituted salicylic acids, such as zinc di-tert-butylsalicylate have also been commercially used as developers .

Sensitizers

A leuco dye and a developer, when melted together, are enough to produce color. However, the thermal threshold of the coated layer containing the colorizing components is determined by the lowest melting component of the layer. Furthermore, developers and leuco dyes often mix poorly upon melting. To optimize the colorization temperature and to facilitate mixing, a third chemical called a sensitizer is commonly added to the imaging layer. Sensitizers are commonly simple ether molecules such as 1,2-bis-(3-methylphenoxy)ethane or2-benzyloxynapthalene. These two materials melt at approximately 100 °C, which is a practical lower limit for thermal coloration. These low-cost ethers are excellent low viscosity solvents for leuco dyes and developers, and this facilitates color formation at a well-defined temperature and with minimum energy input.

Stabilizers

Dyes in thermally sensitive paper are often unstable and return to their original colorless, crystalline forms when stored in hot or humid conditions.^[3] To stabilize the metastable glass formed by the leuco dye, developer and sensitizer, a fourth type of material called a stabilizer is often added to thermal papers. Stabilizers often share similarities with developers and are often complex multifunctional phenols that inhibit recrystallization of the dye and developer, thereby stabilizing the printed image.

Papers are supplied either as rolls or (particularly for wider letter-size printers) sheets. They may have a stick-and-peel adhesive backing, for use as labels and similar purposes. Paper may be white, other colors, or transparent.

In 2006, NCR Corporation's Systemedia division introduced two-sided thermal printing technology, called "2ST".

Most direct thermal papers require a protective top-coating to:

• reduce fading of the thermal image caused by exposure toUV light, water, oils and fats,plasticizers, and other causes
• reduce print-head wear
• reduce or eliminate residue from the thermal coating on the thermal print heads
• provide better anchorage of flexographic printing inks applied to the thermal paper
• focus the heat from the thermal print head on the active coating.

Multicolor thermal paper first became available in 1993 with the introduction of theFuji Thermo-Autochrome (TA) system.^[4]

This was followed in 2007 byPolaroid's development of theZink ("zero-ink") system.^[5] Both of these methods rely on multi-layer coatings with three separate colorizing layers, with different methods used for independent activation of each layer.^[6] The paper is used incompact photo printers. It has several layers: a backing layer with optionalpressure sensitive adhesive, heat-sensitive layers with cyan, magenta and yellow pigments in colorless form, and overcoat. Zink technology allows the printing of full-color images in a single pass without requiring ink cartridges. The color addressing is achieved by controlling the heat pulse length and intensity.^[7] The color-forming layers contain colorless crystals ofamorphochromic dyes. These dyes form microcrystals of their colorlesstautomers, which convert to the colored form by melting and retain color after resolidification.^[8] The yellow layer is the topmost one, sensitive to short heat pulses of high temperature. The magenta layer is in the middle, sensitive to longer pulses of moderate temperature. The cyan layer is at the bottom, sensitive to long pulses of low temperature. The layers are separated by thin interlayers, acting as heat insulation, moderating the heat throughput.^[9]

Some thermal papers are coated withBPA, a chemical considered to be anendocrine disruptor.^[10][11] This material can contaminate recycled paper.^[12][13] BPA can transfer readily to the skin in small amounts:

When taking hold of a receipt consisting of thermal printing paper for five seconds, roughly 1 μg BPA (0.2–0.6 μg) was transferred to the forefinger and the middle finger if the skin was rather dry, and about ten times more than this if these fingers were wet or very greasy. Exposure to a person who repeatedly touches thermal printer paper for about ten hours per day, such as at a cash register, could reach 71 micrograms per day, which is 42 times less than the present tolerable daily intake (TDI).^[14]

The chemical bisphenol A (BPA) is used for thermal paper coatings because of its stability and heat-resistance. This allows inkless printing for receipts from cash registers. People who often are in contact with BPA coated receipts do have a higher level of BPA in their bodies than people with average contact. Therefore, theNew York Suffolk County signed a resolution to ban BPA in thermal receipt papers. Violation of this new law, the "Safer Sales Slip Act", involves a US$500 penalty. The law became effective beginning January 3, 2014.^[15]

From about 2013bisphenol S (BPS), an analog of BPA that has been shown to have similarin vitro estrogenic activity to BPA,^[16][17] has been used in thermal paper coatings. The recycling of thermal paper coated with BPS can introduce BPS into the cycle of paper production and cause BPS contamination of other types of paper products.^[13]Newer formulations are available which use eitherurea-based compounds orvitamin C, and are "phenol free".^[18][19] They can have comparable or even improved print quality, but cost more.

• Texas Instruments-Computers & Software and Industrial Controls
• Silent 700 Electronic Data Terminals, 1976 (PDF) (archived 1 October 2007)
• 2ST Two-Sided Thermal PrintingNational Cash Register (archived 24 September 2011)

• Coated paper
• Office equipment
• Printing technology

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