date: 2022-01-29T02:38:42Z pdf:unmappedUnicodeCharsPerPage: 17 pdf:PDFVersion: 1.7 pdf:docinfo:title: Development and Experimental Assessment of a Model for the Material Deposition by Laser-Induced Forward Transfer xmp:CreatorTool: LaTeX with hyperref Keywords: transfer mechanisms; fluorescence imaging; vertical scanning interferometry access_permission:modify_annotations: true access_permission:can_print_degraded: true subject: The potential to deposit minute amounts of material from a donor to an acceptor substrate at precise locations makes laser-induced forward transfer (LIFT) a frequently used tool within different research fields, such as materials science and biotechnology. While many different types of LIFT exist, each specialized LIFT application is based on a different underlying transfer mechanism, which affects the to-be-transferred materials in different ways. Thus, a characterization of these mechanisms is necessary to understand their limitations. The most common investigative methods are high-speed imaging and numerical modeling. However, neither of these can, to date, quantify the material deposition. Here, analytical solutions are derived for the contact-based material deposition by LIFT, which are based on a previously observed equilibrium state. Moreover, an analytical solution for the previously unrecognized ejection-based material deposition is proposed, which is detectable by introducing a distance between the donor and acceptor substrates. This secondary mechanism is particularly relevant in large scale production, since each deposition from a donor substrate potentially induces a local distance between the donor and acceptor substrates. dc:creator: Grigori Paris, Dominik Bierbaum, Michael Paris, Dario Mager and Felix F. Loeffler dcterms:created: 2022-01-29T02:21:23Z Last-Modified: 2022-01-29T02:38:42Z dcterms:modified: 2022-01-29T02:38:42Z dc:format: application/pdf; version=1.7 title: Development and Experimental Assessment of a Model for the Material Deposition by Laser-Induced Forward Transfer Last-Save-Date: 2022-01-29T02:38:42Z pdf:docinfo:creator_tool: LaTeX with hyperref access_permission:fill_in_form: true pdf:docinfo:keywords: transfer mechanisms; fluorescence imaging; vertical scanning interferometry pdf:docinfo:modified: 2022-01-29T02:38:42Z meta:save-date: 2022-01-29T02:38:42Z pdf:encrypted: false dc:title: Development and Experimental Assessment of a Model for the Material Deposition by Laser-Induced Forward Transfer modified: 2022-01-29T02:38:42Z cp:subject: The potential to deposit minute amounts of material from a donor to an acceptor substrate at precise locations makes laser-induced forward transfer (LIFT) a frequently used tool within different research fields, such as materials science and biotechnology. While many different types of LIFT exist, each specialized LIFT application is based on a different underlying transfer mechanism, which affects the to-be-transferred materials in different ways. Thus, a characterization of these mechanisms is necessary to understand their limitations. The most common investigative methods are high-speed imaging and numerical modeling. However, neither of these can, to date, quantify the material deposition. Here, analytical solutions are derived for the contact-based material deposition by LIFT, which are based on a previously observed equilibrium state. Moreover, an analytical solution for the previously unrecognized ejection-based material deposition is proposed, which is detectable by introducing a distance between the donor and acceptor substrates. This secondary mechanism is particularly relevant in large scale production, since each deposition from a donor substrate potentially induces a local distance between the donor and acceptor substrates. pdf:docinfo:subject: The potential to deposit minute amounts of material from a donor to an acceptor substrate at precise locations makes laser-induced forward transfer (LIFT) a frequently used tool within different research fields, such as materials science and biotechnology. While many different types of LIFT exist, each specialized LIFT application is based on a different underlying transfer mechanism, which affects the to-be-transferred materials in different ways. Thus, a characterization of these mechanisms is necessary to understand their limitations. The most common investigative methods are high-speed imaging and numerical modeling. However, neither of these can, to date, quantify the material deposition. Here, analytical solutions are derived for the contact-based material deposition by LIFT, which are based on a previously observed equilibrium state. Moreover, an analytical solution for the previously unrecognized ejection-based material deposition is proposed, which is detectable by introducing a distance between the donor and acceptor substrates. This secondary mechanism is particularly relevant in large scale production, since each deposition from a donor substrate potentially induces a local distance between the donor and acceptor substrates. Content-Type: application/pdf pdf:docinfo:creator: Grigori Paris, Dominik Bierbaum, Michael Paris, Dario Mager and Felix F. Loeffler X-Parsed-By: org.apache.tika.parser.DefaultParser creator: Grigori Paris, Dominik Bierbaum, Michael Paris, Dario Mager and Felix F. Loeffler meta:author: Grigori Paris, Dominik Bierbaum, Michael Paris, Dario Mager and Felix F. Loeffler dc:subject: transfer mechanisms; fluorescence imaging; vertical scanning interferometry meta:creation-date: 2022-01-29T02:21:23Z created: 2022-01-29T02:21:23Z access_permission:extract_for_accessibility: true access_permission:assemble_document: true xmpTPg:NPages: 10 Creation-Date: 2022-01-29T02:21:23Z pdf:charsPerPage: 3981 access_permission:extract_content: true access_permission:can_print: true meta:keyword: transfer mechanisms; fluorescence imaging; vertical scanning interferometry Author: Grigori Paris, Dominik Bierbaum, Michael Paris, Dario Mager and Felix F. Loeffler producer: pdfTeX-1.40.21 access_permission:can_modify: true pdf:docinfo:producer: pdfTeX-1.40.21 pdf:docinfo:created: 2022-01-29T02:21:23Z