Index

  1.  
  2. a
  3. absorbing-film assisted laser-induced forward transfer (AFA-LIFT)
  4. absorption efficiency
  5. acousto-optical modulator (AOM)
  6. active-matrix OLED (AMOLED)
    1. displays
    2. prototype devices
  7. additive manufacturing
  8. Alexa 594 labeled lambda phage DNA
  9. amperometric biosensor
  10. amyloid peptides
  11. avidin
  12.  
  13. b
  14. BA-LIFT see blister-actuated laser-induced forward transfer (BA-LIFT)
  15. ballistic laser-assisted solid transfer (BLAST)
  16. bio-electronic nose
  17. Biological Laser Printing (BioLP)
  18. BioLP process
  19. biomicrodevices
  20. bioprinting
  21. biosensors
  22. blade coating
  23. blister-actuated laser-induced forward transfer (BA-LIFT)
    1. blister formation
      1. dynamics
      2. finite element modeling
    2. cavitation bubble collapse
    3. delicate materials
    4. experimental setup
    5. jet formation
    6. jet formation and expansion
      1. computational fluid dynamics model
      2. ink film properties
      3. laser energy
    7. laser absorption
    8. liquid ejection
    9. liquid jets
    10. mechanism
    11. penetration or absorption depth
    12. polyimide
    13. polymer laser-absorbing layer
    14. pump-probe imaging
    15. solvent orthogonality
    16. thick polymer layer
    17. time-resolved imaging
    18. vapor cavity
  24. blister formation
    1. dynamics
    2. finite element modeling
      1. boundary deformation function
      2. domain perturbation method
      3. kinetic energy
      4. velocity components
  25. “blow-off time”
  26.  
  27. c
  28. cancer research
  29. capacitive DNA biosensor
  30. CdSe(CdS) nanoquantum dots
  31. cell printing
  32. centripetal acceleration
  33. chalcogenide thin films
  34. chemical and biological sensors
    1. applications
    2. background of biosensors
    3. carbon nanotubes
    4. electrospray deposition
    5. inkjet printing technique
    6. laser-Induced forward transfer (LIFT)
    7. LIFT of liquid films
    8. microcontact printing
    9. nano-tip printing technique
    10. photochemistry-based printing
    11. pin printing approach
    12. polyepichlorohydrin (PECH) polymer/carbon
    13. printing of biological materials
  35. chemoresistor gas sensors
  36. colorimetric enzyme linked immunosorbent assay (ELISA)
  37. congruent LIFT, see laser decal transfer (LDT)
  38. contact printing methods
    1. microcontact printing
    2. nano-tip printing technique
    3. pin printing approach
  39. coplanar waveguide (CPW)
  40. cytoscribing
  41.  
  42. d
  43. digital micromirror device (DMD)
    1. advantages
    2. experimental setup
    3. pattern
    4. polymer films
  44. digital printing
  45. dip coating
  46. diPhAc-3T (Bis(2-phenylethynyl end-substituted terthiophene)
  47. dip-pen lithography
  48. direct-matrix absorption (DMA)
  49. direct patterning methods
  50. “direct-write” approaches
  51. dispensing or soaking techniques
  52. distyryl-quaterthiophene (DS4T)
  53. DMD-based pulse shaping, LIBT
  54. “8–17” DNAzyme
  55. doctor blading, see blade coating
  56. dot-blotting
  57. drawdown rods method
  58. droplet mode deposition
    1. contact and non-contact configurations
    2. copper droplets
    3. donor film
    4. droplet velocity
    5. femtosecond excimer LIFT
    6. jet instability
    7. jetting phenomena
    8. liquid jets
    9. mechanism
    10. microscale 3D printing
    11. multiple droplets per laser pulse
    12. nanosecond LIFT of aluminum
    13. printing lines
    14. transfer droplet
  59. dynamic release layer (DRL)
    1. advantage
    2. explosive polymers
    3. laser absorption
    4. trace material
  60. dynamics process
    1. lase-and-place
    2. laser transparent carrier tapes
    3. polyimide blistering layer
    4. silicon substrates
    5. thermo-mechanical selective laser-assisted die transfer
  61.  
  62. e
  63. electrical resistivity
  64. electrochemical biosensors
  65. electron lithography
  66. electrospray deposition
  67. energy harvesting
    1. chalcogenide thin films
    2. thermoelectric generator
  68. enzyme linked immunosorbent assay
  69. explosive polymers
  70.  
  71. f
  72. femtosecond laser
    1. printing
    2. system
  73. FF-LIFT, see film-free LIFT (FF-LIFT)
  74. film-formation methods
  75. film-free laser printing (FF-LP) technique
  76. film-free LIFT (FF-LIFT)
    1. applications
      1. micro-optical elements fabrication
      2. printing biomaterials
    2. forward (inverted) vs. backward (upright) systems
    3. fundamentals of
      1. cavitation-induced phenomena
      2. jet formation
      3. vs. LIFT
    4. implementation and optical considerations
      1. forward (inverted) vs. backward (upright) systems
      2. laser source
      3. spherical aberration and chromatic dispersion
    5. jet formation
    6. vs. LIFT
    7. micro-optical elements fabrication
    8. receiver substrate
    9. spherical aberration and chromatic dispersion
    10. thin liquid film preparation
      1. blade coating
      2. dip coating
      3. external instabilities
      4. rheological parameters
      5. spin coating
      6. spontaneous instabilities
    11. traditional LIFT
    12. transparent liquids
  77. finite-element analysis software
  78. finite element modeling
  79. flexography
  80. flip-chip technology
  81. fluence threshold value
  82. fluids
    1. ejection and deposition
      1. droplet deposition
      2. jet formation
    2. printing continuous patterns
    3. printing droplets
      1. fluid properties
      2. laser parameters
      3. setup parameters
    4. printing lines
  83. fluorescently tagged complementary proteins
  84. focussed ion beam (FIB)
  85. Fresnel diffraction
  86. fs-LIFT technique
  87. fully polymeric OTFT devices
  88. functional release layer (FRL)
  89.  
  90. g
  91. Gaussian/`top-hat' spatial intensity beam profile
  92. gentle hydration method
  93. gravure printing
  94.  
  95. h
  96. horizontally-aligned grain boundaries
  97. horseradish peroxidase (HRP)
  98. hybrid circuits
  99. hydrodynamic process
  100. hydrogen-assisted laser-induced forward transfer(HA-LIFT)
  101.  
  102. i
  103. immunoglobulin (IgG) microarrays
  104. inclined pillars
  105. inkjet printing
  106. intact polymer molecules
  107. interconnection and heterogeneous integration
  108. interdigitized electrodes
  109. interference effects
  110. isotropic conductive adhesive (ICA)
  111.  
  112. j
  113. jet-and spray-ejection regime
  114. jet formation dynamics
    1. experimental set up
    2. Newtonian glycerol solutions
      1. experimental design
      2. fluid properties and laser fluence
      3. jettability phase diagram
      4. typical jetting regimes
    3. viscoelastic alginate solutions
      1. alginate concentration effects
      2. experimental design
      3. ink coating preparation
      4. jettability phase diagram
      5. laser fluence effects
      6. material properties
      7. non-dimensional numbers
      8. typical jetting regimes
  115. jet formation mechanism
  116. jet morphology
  117. JetXpert imaging system
  118.  
  119.  
  120. l
  121. large area, high throughput LIFT/LIBT inline R2R-printing system
  122. lase-and-place
  123. laser ablation transfer (LAT)
  124. laser-assisted bioprinting (LAB)
    1. blood vessels
    2. bone
    3. cancer research
    4. effect of laser process and printing parameters
    5. heart
    6. history of cell bioprinting
    7. nervous system
    8. skin
    9. technical specifications
  125. laser-based non-lithographic processes
  126. laser-based printing/marking process
  127. laser decal transfer (LDT)
    1. arrays
      1. high viscosity donor material
      2. thicker and thinner voxels
    2. absorption efficiency
    3. congruent laser transfer
    4. CPW
    5. DMD
    6. edge acuity
    7. EDX analysis
    8. fabricated LDT features
    9. FRL
    10. high-aspect 3D stacks and freestanding structures
    11. intrinsic and engineered characteristics
    12. laser system and experimental setup
    13. low-viscosity Ag ink vs. high-viscosity Ag nanopaste
    14. mechanical stability
    15. multi-layered stack
    16. operating parameters
    17. OTFT
    18. potential applications and functional properties
    19. properties
    20. quantitative study
    21. self-supporting feature
    22. SRR
    23. steep sidewalls
    24. three complex interconnect patterns
    25. threshold fluence
    26. voxel separation mechanism
    27. voxels transfer
  128. laser direct-write (LDW)
    1. process
    2. techniques
  129. laser forward transfer process
  130. laser-guided direct writing (LGDW)
  131. laser-induced backward transfer (LIBT)
    1. beam-shaping
    2. experimental setup
    3. nanoimprinting approach
    4. structured carrier substrate
    5. transparent carrier
    6. transparent receiver and transparent donor
    7. unstructured carrier substrate
  132. laser-induced cavitation bubble
  133. laser induced forward transfer (LIFT)
    1. advantages
    2. amyloid peptides
    3. composite-matrix-based materials
    4. of DNA in solid and liquid phase
    5. donor substrate
    6. DRL
    7. early work
    8. film-free laser printing
    9. fluids, see fluids
    10. HA-LIFT
    11. limitations
    12. liposomes
    13. liquid donor films
    14. LITI
    15. LMI
    16. LP-LIFT
    17. MAPLE-DW
    18. material transfer
    19. of metals, see metals
    20. odorant binding proteins
    21. principle of operation
    22. printable inks
    23. repairing damaged photomasks
    24. soft materials, see soft materials
    25. solid donor films
    26. solid films (ceramics and polymers), see solid films (ceramics and polymers)
    27. steps
    28. streptavidin and avidin-biotin complex
    29. ultra-short laser pulses
    30. viscosity and size of particles
  134. laser-induced molecular implantation technique (LIMIT)
  135. laser-induced patternwise sublimation (LIPS)
  136. laser induced thermal imaging (LITI)
  137. laser induced transfer process technique, see laser induced forward transfer (LIFT) technique
  138. laser-induced transfer technology (LIT)
    1. gold nanoparticles
    2. hydrodynamic process
    3. LIBT
    4. LIFT
  139. laser molecular implantation (LMI)
  140. laser pressure catapulting (LPC)
  141. laser printing
    1. additive manufacturing method
    2. bulk-silicon and silicon films
      1. beam modification
      2. computer-based image evaluation
      3. femtosecond laser printing
      4. laser pulse energy
      5. layer thickness
      6. nanoparticle scattering properties
      7. nanoparticles fabrication
      8. normalized size distributions
      9. processing steps
      10. ring-shaped intensity distribution
      11. ring shaped laser beam profile
      12. scattering spectrum
      13. silicon wafer
      14. SOI
    3. of conducting layers
    4. of dielectric layers
    5. metasurfaces
    6. multi-stage process
    7. nanoparticles
    8. pre-structured films
    9. ribbon
    10. of semiconductor layer
    11. spherical nanoparticles
    12. ultraflat optical element
  142. Lasersonic® LIFT
    1. continuous wave laser source and fast modulation
    2. data flow
    3. digital printing market expectations and challenges
    4. future directions
    5. history of
    6. inking units
    7. large area, high throughput LIFT/LIBT inline R2R-printing system
    8. print experiments and results
    9. printing heads
    10. special printing markets
    11. special test pattern
    12. synthetic approaches
    13. time schemes
    14. transparent inks
    15. ultrafast pulse modulation
    16. ultrafast scan
  143. laser transfer, structures and functioning devices
    1. chemically/plasma driven traditional etching techniques
    2. dynamics process see dynamics process
    3. early demonstrations
    4. electronic systems
    5. embedded electronics
    6. flexible circuits
    7. hybrid circuits
    8. individual or multiple components
    9. metal foils
    10. patterned thin films
    11. pick-and-place tools
    12. self-assembly techniques
  144. lase-and-place
  145. laser transfer universe
  146. laser writing (LW)
  147. LDT, see laser decal transfer (LDT)
  148. LIFT, see laser induced forward transfer (LIFT)
  149. LIFT of liquid films
  150. LIFT of 3D metal structures
    1. adhesion
    2. characteristics
    3. definition of 3D structures
    4. demonstrators and potential applications
    5. droplet impact and solidification
    6. ejection phenomena
    7. ejection regimes of pure metal picosecond
    8. electrical properties
    9. inclined pillars
    10. mechanical properties
    11. metal LIFT printed pillars
    12. metallurgical microstructure
    13. copper pillars
    14. pulse duration and spot size
    15. reproducibility
    16. schematic representation of LIFT
    17. solidification phenomena
    18. surface roughness
    19. thermally induced nozzle
    20. transfer threshold fluence
  151. LIFT printed copper pillar
  152. LIFT-printed OTFT
  153. light-to heat-conversion (LTHC)
  154. liposomes
  155. long-pulsed LIFT (LP-LIFT)
  156.  
  157. m
  158. mass printing technologies
  159. material laser recording (MTR)
  160. MatrigelTM
  161. matrix-assisted pulsed laser evaporation (MAPLE)
  162. matrix-assisted pulsed laser evaporation direct write (MAPLE DW)
  163. metals
    1. numerical modeling of LIFT for metals
    2. applications
    3. beam pattern
    4. deposited structures
    5. deposition
    6. droplet mode deposition
      1. contact and non-contact configurations
      2. copper droplets
      3. donor film
      4. droplet velocity
      5. fs excimer LIFT
      6. jet instability
      7. jetting phenomena
      8. liquid jets
      9. mechanism
      10. microscale 3D printing
      11. multiple droplets per laser pulse
      12. nanosecond LIFT of aluminum
      13. transfer droplet
    7. feature characteristics
    8. metal films
    9. parametric effects
      1. donor-film gap spacing
      2. laser fluence and film thickness
      3. pulse width
    10. resolution
    11. single-step process
    12. thermal processes
    13. time scale and fluence
    14. transfer
  164. microbatteries
  165. micro-contact printing (μCP)
  166. microelectromechanical systems (MEMS)
  167. microfluidic patterning
  168. microscale 3D printing
  169. Mie theory
  170. mobility (μ)
  171. multilevel computer-generated holographic structure
  172.  
  173. n
  174. nanocrystal quantum dots (NCQDs
  175. nano-hydroxyapatite (nHA)
  176. nanoimprinting approach
  177. nanolasers
  178. nanomaterial enabled laser transfer (NELT)
  179. nanoparticles
    1. laser printing
    2. printing process
  180. nano-tip printing technique
  181. nervous system
  182. Newtonian glycerol solutions
    1. experimental design
    2. fluid properties and laser fluence
    3. jettability phase diagram
    4. typical jetting regimes
  183. nickel-chrome (NiCr) resistors
  184. non-contact digital technology
  185. non-contact printing methods
    1. electrospray deposition
    2. inkjet printing technique
    3. photochemistry-based printing
  186.  
  187. o
  188. odorant binding proteins (OBPs)
  189. one-dimensional thermal model
  190. on/off current ratio (Ion/IOff)
  191. optical chemical sensor
  192. organic electronic devices
  193. organic light-emitting diodes (OLEDs)
    1. TP-LIFT
  194. organic thin film transistor (OTFT)
    1. laser printing of conducting layers
    2. laser printing of dielectric layers
    3. laser printing of semiconductor layer
    4. operation and characteristics
    5. single step printing
  195. organ printing
  196.  
  197. p
  198. passive components
  199. photochemistry-based printing
  200. photoinduced decomposition
  201. photolithography
  202. pin printing approach
  203. platinum and gold inclined pillars
  204. pluming/splashing regime
  205. poly(butyl methacrylate) (PBMA)
  206. poly(3,4-ethylenedioxythiophene) polystyrene sulphonate (PEDOT:PSS)
  207. poly(ethyl methacrylate) (PEMA)
  208. poly-3-hexylthiophene (P3HT) semiconductor material
  209. polyimide blistering layer
  210. polymer laser-absorbing layer
  211. polymer sacrificial layer
  212. poly[2-methoxy-5-(2-ethylhexyloxy)-1,4-phenylenevinylene] (MEH-PPV)
  213. poly(methylmethacrylate) (PMMA)
  214. polymethyl methacrylate polymer layer
  215. polyvinyl butyral (PVB) inks
  216. power-law relaxation time model
  217. pulsed laser deposition (PLD)
  218. pump-probe imaging
  219.  
  220. q
  221. quantum dot-based light emitting diodes
  222.  
  223. r
  224. Rayleigh-Plateau instability
  225. reactive ion etching
  226. reactive LIFT (rLIFT)
  227. red-green-blue PFO pixel transfer
  228. robotic micro-needle array fabrication
  229.  
  230. s
  231. satellites
  232. SAW biosensor arrays
  233. “Scotch tape” test
  234. screen printing
  235. Seebeck coefficient
  236. selective laser melting (SLM)
  237. sequential laser printing
  238. shadowgraphy studies
    1. ceramic thin films
    2. compliant receivers
  239. silicon-on-insulator (SOI)
  240. silver split-ring resonators (SRR)
  241. single step printing, OTFT device
  242. slot-die approach
  243. soft materials
    1. jet formation, see jet formation dynamics
    2. jet formation mechanism
    3. jet morphology
    4. jet velocity
    5. laser printing applications
    6. multilayer hydrogel-cell planar structure
  244. sol–gel technique
  245. solid films (ceramics and polymers)
    1. energy harvesting
      1. chalcogenide thin films
      2. micro-scale thermoelectric generator
      3. thermoelectric generator
    2. laser pulse interference-assistedLIFT
      1. BLAST
      2. standing wave interference from multiple layers
    3. LIBT
      1. experimental setup
      2. ion beam milling/UV beam machining
      3. nanoimprinting approach
      4. structured carrier substrate
      5. transparent carrier
      6. transparent receiver and transparent donor
      7. unstructured carrier substrate
    4. polymer films
    5. pre-machined ceramic micro-discs, LIFT printing of
    6. shadowgraphy studies
      1. ceramic thin films
      2. compliant receivers
  246. solvent orthogonality
  247. spatial light modulator (SLM)
  248. spin coating
  249. spray coating technology
  250. streptavidin
    1. and avidin-biotin complex
  251. stroboscopic imaging techniques
  252. surface acoustic waves (SAW)
    1. biosensors
    2. chemical sensors
  253. surface tension
  254.  
  255. t
  256. tert-butyl acrylate (TBA)
  257. thermoelectric generator
  258. thermo-mechanical selective laser-assisted die transfer
  259. thin-film transistor-liquid crystal displays (TFT-LCD)
  260. 3D structures
  261. through silicon vias (TSVs)
  262. time-resolved imaging of jet formation
  263. time-resolved imaging of droplet deposition
  264. tissue engineering
    1. blood vessels
    2. bone
    3. heart
    4. nervous system
    5. skin
  265. traditionally packaged electronic components
  266. triazene DRL-LIFT
  267. triazene polymers (TP)
    1. chemical structure
    2. front and back side ablation
    3. higher ablation rates
    4. LIFT
      1. application
      2. aryltriazene photopolymers
      3. biomembrane model system
      4. materials
      5. OLEDs
      6. polystyrene microbeads
      7. sensors
    5. PS-microbead pixel
    6. UV-vis absorption spectrum
  268. tri-color pixels
  269. two-dimensional thermal model
  270. two-temperature model
  271.  
  272. u
  273. ultra flat lens
  274. ultra-short laser pulses
  275. UV photolysis
  276.  
  277. v
  278. viscoelastic alginate solutions
    1. alginate concentration effects
    2. experimental design
    3. ink coating preparation
    4. jettability phase diagram
    5. laser fluence effects
    6. material properties
    7. non-dimensional numbers
    8. typical jetting regimes
  279. voxel separation mechanism
  280.  
  281. w
  282. Wenzel wetting
  283. wild-type OBP from bovine (wtbOBP)
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