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Line 1: {{~~refimprove~~more citations needed\|date=October 2010}} [[File:R2R line.jpg\|thumb\|A typical industrial roll-to-roll process line.]] In the field of electronic devices, '''~~Roll~~roll-to-roll processing''', also known as '''web processing''',<ref name="web processing">{{cite web\|title=Digital roll-to-roll web processing revolutionizes printed electronic production\|url=https://www.controleng.com/single-article/digital-roll-to-roll-web-processing-revolutionizes-printed-electronic-production.html?print=1\|website=Control Engineering\|accessdate=February 1, 2018\|date=March 12, 2013}}</ref> '''reel-to-reel processing''' or '''R2R''',<ref name=":0">{{Cite journal\|~~last~~last1=Goswami\|~~first~~first1=Debkalpa\|last2=Munera\|first2=Juan C.\|last3=Pal\|first3=Aniket\|last4=Sadri\|first4=Behnam\|last5=Scarpetti\|first5=Caio Lui P. G.\|last6=Martinez\|first6=Ramses V.\|date=2018-05-18\|title=Roll-to-Roll Nanoforming of Metals Using Laser-Induced Superplasticity\|journal=Nano Letters\|language=en\|volume=18\|issue=6\|pages=3616–3622\|doi=10.1021/acs.nanolett.8b00714\|pmid=29775318\|bibcode=2018NanoL..18.3616G\|issn=1530-6984}}</ref> is the process of creating electronic devices on a roll of [[flexible plastic]] or, metal [[Foil (chemistry)\|foil]], or flexible glass.<ref>{{cite journal \|url=https://www.researchgate.net/publication/260251815 \|via=[[ResearchGate]]\|doi=10.1016/j.surfcoat.2013.10.056 \|title=Roll-to-roll sputter deposition on flexible glass substrates \|year=2014 \|last1=Tamagaki \|first1=Hiroshi \|last2=Ikari \|first2=Yoshimitu \|last3=Ohba \|first3=Naoki \|journal=Surface and Coatings Technology \|volume=241 \|pages=138–141 }}</ref> In other fields predating this use, it can refer to any process of applying ~~coatings~~coating, [[Roll-to-roll printing\|printing]], or performing other processes starting with a roll of a flexible material and re-reeling after the process to create an output roll. These processes, and others such as sheeting, can be grouped together under the general term '''[[Converter (industry)\|converting]]'''. When the rolls of material have been coated, laminated or printed they can be subsequently slit to their finished size on a [[slitter]] rewinder. == In electronic devices == Large [[Integrated circuit\|circuit]]s made with [[thin-film transistor]]s and other devices can be [[pattern]]ed onto these large substrates, which can be up to a few metres wide and {{convert\|50~~ ~~\|km\|abbr=on}} long.{{cncitation needed\|date=March 2017}} Some of the devices can be patterned directly, much like an [[inkjet printer]] deposits ink. For most [[semiconductor]]s, however, the devices must be patterned using [[photolithography]] techniques. [[File:Roll tol rol slitting processing.jpg\|alt=roll to roll processing\|thumb\|roll to roll processing]] Roll-to-roll processing of large-area electronic devices reduces manufacturing cost.<ref>{{cite book\|chapter-url=https://books.google.com/books?id=ZiGjrlkSpOQC&~~pg=PA19&lpg=PA19&dq~~q=%22web+processing%22+%22Roll+to+roll%22&~~source~~pg=~~bl&ots=cKLMNnpKYw&sig=BJcY7byhE38jDUuCKOUHNca2hdo&hl=en&sa=X&ved=0ahUKEwi4r6W5noXZAhUUzGMKHfhlDe0Q6AEIbTAP#v=onepage&q=%22web%20processing%22%20%22Roll%20to%20roll%22&f=false~~PA19\|title=Flexible Electronics: Materials and Applications\|chapter=Fabrication on Web by Roll-to-Roll Processing\|page=19\|~~editors~~editor1=Wong, William S.~~, and~~ \|editor2=Salleo, Alberto\|publisher=Springer\|place=New York, NY\|year=2009\|isbn=978-0387743639}}</ref><ref name=":0" /> Most notable would be [[solar cell]]s, which are still prohibitively expensive for most markets due to the high cost per unit area of traditional bulk ([[Monocrystalline silicon\|mono-]] or [[Polycrystalline silicon\|polycrystalline]]) silicon manufacturing. Other applications could arise which take advantage of the flexible nature of the substrates, such as electronics embedded into clothing, large-area flexible displays, and [[rollable display \| roll-up portable displays]].▼ === ~~'''~~LED (Light Emitting Diode)~~'''~~ ===▼ ▲Roll-to-roll processing of large-area electronic devices reduces manufacturing cost.<ref>{{cite book\|chapter-url=https://books.google.com/books?id=ZiGjrlkSpOQC&pg=PA19&lpg=PA19&dq=%22web+processing%22+%22Roll+to+roll%22&source=bl&ots=cKLMNnpKYw&sig=BJcY7byhE38jDUuCKOUHNca2hdo&hl=en&sa=X&ved=0ahUKEwi4r6W5noXZAhUUzGMKHfhlDe0Q6AEIbTAP#v=onepage&q=%22web%20processing%22%20%22Roll%20to%20roll%22&f=false\|title=Flexible Electronics: Materials and Applications\|chapter=Fabrication on Web by Roll-to-Roll Processing\|page=19\|editors=Wong, William S., and Salleo, Alberto\|publisher=Springer\|place=New York, NY\|year=2009\|isbn=978-0387743639}}</ref><ref name=":0" /> Most notable would be [[solar cell]]s, which are still prohibitively expensive for most markets due to the high cost per unit area of traditional bulk ([[Monocrystalline silicon\|mono-]] or [[Polycrystalline silicon\|polycrystalline]]) silicon manufacturing. Other applications could arise which take advantage of the flexible nature of the substrates, such as electronics embedded into clothing, large-area flexible displays, and [[rollable display \| roll-up portable displays]]. * Inorganic LED - Flexible LED is commonly made into ~~25m~~ 25, ~~50m~~50, ~~100m~~100 m, or even longer strips using a roll-to-roll process. ~~Long~~A long neon LED tube is using such a long flexible strip and encapsulated with PVC or silicone diffusing encapsulation. ▼ ▲=== '''LED (Light Emitting Diode)''' === * Organic LED (OLED) - OLED for foldable phone screen is adopting roll-to-roll processing technology. ▼ ▲* Inorganic LED - Flexible LED is commonly made into 25m , 50m, 100m or even longer strips using roll-to-roll process. Long neon LED tube is using such a long flexible strip and encapsulated with PVC or silicone diffusing encapsulation. ▲* Organic LED (OLED) - OLED for foldable phone screen is adopting roll-to-roll processing technology. === Thin-film cells === A crucial issue for a roll-to-roll thin-film cell production system is the [[Deposition (physics)\|deposition]] rate of the [[microcrystalline]] layer, and this can be tackled using four approaches:<ref>{{cite web \|url=http://ec.europa.eu/research/energy/nn/nn_rt/nn_rt_pv/article_1109_en.htm \|title=PV projects in FP6 \|accessdate=2008-11-25 \|~~deadurl~~url-status=~~yes~~dead \|archiveurl=https://web.archive.org/web/20060618111512/http://ec.europa.eu/research/energy/nn/nn_rt/nn_rt_pv/article_1109_en.htm\|archivedate=June 18, 2006 ~~\|df=~~ }}</ref> very high frequency plasma-enhanced chemical vapour deposition ([[VHF]]-[[PECVD]]) microwave ([[Microwave\|MW]])-PECVD hot wire [[chemical vapour deposition]] (hot-wire CVD). the use of [[ultrasonic nozzle]]s in an in-line process == In electrochemical devices == ==See also== ▼ Roll-to-roll processing has been used in the manufacture of electrochemical devices such as batteries,<ref>{{Cite patent\|number=US11446915B2\|title=Roll-to-roll slot die coating method to create interleaving multi-layered films with chemical slurry coatings\|gdate=2022-09-20\|invent1=Biswas\|invent2=III\|invent3=Grady\|invent4=Ghezawi\|inventor1-first=Kaushik\|inventor2-first=David Lee Wood\|inventor3-first=Kelsey M.\|inventor4-first=Natasha B.\|url=https://patents.google.com/patent/US11446915B2/en}}</ref> supercapacitors,<ref>{{Cite journal \|last1=Yeo \|first1=Junyeob \|last2=Kim \|first2=Geonwoong \|last3=Hong \|first3=Sukjoon \|last4=Kim \|first4=Min Su \|last5=Kim \|first5=Daewon \|last6=Lee \|first6=Jinhwan \|last7=Lee \|first7=Ha Beom \|last8=Kwon \|first8=Jinhyeong \|last9=Suh \|first9=Young Duk \|last10=Kang \|first10=Hyun Wook \|last11=Sung \|first11=Hyung Jin \|last12=Choi \|first12=Jun-Ho \|last13=Hong \|first13=Won-Hwa \|last14=Ko \|first14=Jang Myoun \|last15=Lee \|first15=Seung-Hyun \|date=2014-01-15 \|title=Flexible supercapacitor fabrication by room temperature rapid laser processing of roll-to-roll printed metal nanoparticle ink for wearable electronics application \|url=https://www.sciencedirect.com/science/article/pii/S0378775313013499 \|journal=Journal of Power Sources \|language=en \|volume=246 \|pages=562–568 \|doi=10.1016/j.jpowsour.2013.08.012 \|bibcode=2014JPS...246..562Y \|s2cid=94203734 \|issn=0378-7753\|url-access=subscription }}</ref> fuel cells,<ref>{{Cite journal \|last1=Steenberg \|first1=Thomas \|last2=Hjuler \|first2=Hans Aage \|last3=Terkelsen \|first3=Carina \|last4=Sánchez \|first4=María T. R. \|last5=Cleemann \|first5=Lars N. \|last6=Krebs \|first6=Frederik C. \|date=2012-03-01 \|title=Roll-to-roll coated PBI membranes for high temperature PEM fuel cells \|url=https://pubs.rsc.org/en/content/articlelanding/2012/ee/c2ee02936g \|journal=Energy & Environmental Science \|language=en \|volume=5 \|issue=3 \|pages=6076–6080 \|doi=10.1039/C2EE02936G \|s2cid=95139481 \|issn=1754-5706\|url-access=subscription }}</ref><ref>{{Cite journal \|last1=Mauger \|first1=Scott A. \|last2=Neyerlin \|first2=K. C. \|last3=Yang-Neyerlin \|first3=Ami C. \|last4=More \|first4=Karren L. \|last5=Ulsh \|first5=Michael \|date=2018-09-11 \|title=Gravure Coating for Roll-to-Roll Manufacturing of Proton-Exchange-Membrane Fuel Cell Catalyst Layers \|journal=Journal of the Electrochemical Society \|language=en \|volume=165 \|issue=11 \|pages=F1012 \|doi=10.1149/2.0091813jes \|s2cid=105303844 \|issn=1945-7111\|doi-access=free }}</ref> and water electrolyzers.<ref>{{Cite journal \|last1=Park \|first1=Janghoon \|last2=Kang \|first2=Zhenye \|last3=Bender \|first3=Guido \|last4=Ulsh \|first4=Michael \|last5=Mauger \|first5=Scott A. \|date=2020-12-15 \|title=Roll-to-roll production of catalyst coated membranes for low-temperature electrolyzers \|journal=Journal of Power Sources \|language=en \|volume=479 \|pages=228819 \|doi=10.1016/j.jpowsour.2020.228819 \|bibcode=2020JPS...47928819P \|s2cid=224915162 \|issn=0378-7753\|doi-access=free }}</ref> Here, the roll-to-roll processing is utilized for electrode manufacturing and is the key to reducing manufacturing cost<ref>{{Cite journal \|last1=Mauler \|first1=Lukas \|last2=Duffner \|first2=Fabian \|last3=Leker \|first3=Jens \|date=2021-03-15 \|title=Economies of scale in battery cell manufacturing: The impact of material and process innovations \|journal=Applied Energy \|language=en \|volume=286 \|pages=116499 \|doi=10.1016/j.apenergy.2021.116499 \|s2cid=233658321 \|issn=0306-2619\|doi-access=free }}</ref> through stable production of electrodes on various film substrates such as metal foils, membranes, diffusion media, and separators. ▲==See also== {{Portal\|Manufacturing}} [[Amorphous silicon]] [[Low cost solar cell]] [[Printed electronics]] [[Slitter\|Roll slitting]] [[Rolling (metalworking)]] [[Roll-to-roll electronics inkjet printer]] [[Thin film solar cell]] [[~~web~~Web (manufacturing)\| ~~web~~Web manufacturing]] * [[Tape automated bonding]], TAB ==References== <references/> ~~== External links ==~~ [[Category:Electronics manufacturing]] [[Category:Semiconductors]] {{engineering-stub}}