-
- a
- absorbing-film assisted laser-induced forward transfer (AFA-LIFT)
- absorption efficiency
- acousto-optical modulator (AOM)
- active-matrix OLED (AMOLED)
- displays
- prototype devices
- additive manufacturing
- Alexa 594 labeled lambda phage DNA
- amperometric biosensor
- amyloid peptides
- avidin
-
- b
- BA-LIFT see blister-actuated laser-induced forward transfer (BA-LIFT)
- ballistic laser-assisted solid transfer (BLAST)
- bio-electronic nose
- Biological Laser Printing (BioLP)
- BioLP process
- biomicrodevices
- bioprinting
- biosensors
- blade coating
- blister-actuated laser-induced forward transfer (BA-LIFT)
- blister formation
- dynamics
- finite element modeling
- cavitation bubble collapse
- delicate materials
- experimental setup
- jet formation
- jet formation and expansion
- computational fluid dynamics model
- ink film properties
- laser energy
- laser absorption
- liquid ejection
- liquid jets
- mechanism
- penetration or absorption depth
- polyimide
- polymer laser-absorbing layer
- pump-probe imaging
- solvent orthogonality
- thick polymer layer
- time-resolved imaging
- vapor cavity
- blister formation
- dynamics
- finite element modeling
- boundary deformation function
- domain perturbation method
- kinetic energy
- velocity components
- “blow-off time”
-
- c
- cancer research
- capacitive DNA biosensor
- CdSe(CdS) nanoquantum dots
- cell printing
- centripetal acceleration
- chalcogenide thin films
- chemical and biological sensors
- applications
- background of biosensors
- carbon nanotubes
- electrospray deposition
- inkjet printing technique
- laser-Induced forward transfer (LIFT)
- LIFT of liquid films
- microcontact printing
- nano-tip printing technique
- photochemistry-based printing
- pin printing approach
- polyepichlorohydrin (PECH) polymer/carbon
- printing of biological materials
- chemoresistor gas sensors
- colorimetric enzyme linked immunosorbent assay (ELISA)
- congruent LIFT, see laser decal transfer (LDT)
- contact printing methods
- microcontact printing
- nano-tip printing technique
- pin printing approach
- coplanar waveguide (CPW)
- cytoscribing
-
- d
- digital micromirror device (DMD)
- advantages
- experimental setup
- pattern
- polymer films
- digital printing
- dip coating
- diPhAc-3T (Bis(2-phenylethynyl end-substituted terthiophene)
- dip-pen lithography
- direct-matrix absorption (DMA)
- direct patterning methods
- “direct-write” approaches
- dispensing or soaking techniques
- distyryl-quaterthiophene (DS4T)
- DMD-based pulse shaping, LIBT
- “8–17” DNAzyme
- doctor blading, see blade coating
- dot-blotting
- drawdown rods method
- droplet mode deposition
- contact and non-contact configurations
- copper droplets
- donor film
- droplet velocity
- femtosecond excimer LIFT
- jet instability
- jetting phenomena
- liquid jets
- mechanism
- microscale 3D printing
- multiple droplets per laser pulse
- nanosecond LIFT of aluminum
- printing lines
- transfer droplet
- dynamic release layer (DRL)
- advantage
- explosive polymers
- laser absorption
- trace material
- dynamics process
- lase-and-place
- laser transparent carrier tapes
- polyimide blistering layer
- silicon substrates
- thermo-mechanical selective laser-assisted die transfer
-
- e
- electrical resistivity
- electrochemical biosensors
- electron lithography
- electrospray deposition
- energy harvesting
- chalcogenide thin films
- thermoelectric generator
- enzyme linked immunosorbent assay
- explosive polymers
-
- f
- femtosecond laser
- printing
- system
- FF-LIFT, see film-free LIFT (FF-LIFT)
- film-formation methods
- film-free laser printing (FF-LP) technique
- film-free LIFT (FF-LIFT)
- applications
- micro-optical elements fabrication
- printing biomaterials
- forward (inverted) vs. backward (upright) systems
- fundamentals of
- cavitation-induced phenomena
- jet formation
- vs. LIFT
- implementation and optical considerations
- forward (inverted) vs. backward (upright) systems
- laser source
- spherical aberration and chromatic dispersion
- jet formation
- vs. LIFT
- micro-optical elements fabrication
- receiver substrate
- spherical aberration and chromatic dispersion
- thin liquid film preparation
- blade coating
- dip coating
- external instabilities
- rheological parameters
- spin coating
- spontaneous instabilities
- traditional LIFT
- transparent liquids
- finite-element analysis software
- finite element modeling
- flexography
- flip-chip technology
- fluence threshold value
- fluids
- ejection and deposition
- droplet deposition
- jet formation
- printing continuous patterns
- printing droplets
- fluid properties
- laser parameters
- setup parameters
- printing lines
- fluorescently tagged complementary proteins
- focussed ion beam (FIB)
- Fresnel diffraction
- fs-LIFT technique
- fully polymeric OTFT devices
- functional release layer (FRL)
-
- g
- Gaussian/`top-hat' spatial intensity beam profile
- gentle hydration method
- gravure printing
-
- h
- horizontally-aligned grain boundaries
- horseradish peroxidase (HRP)
- hybrid circuits
- hydrodynamic process
- hydrogen-assisted laser-induced forward transfer(HA-LIFT)
-
- i
- immunoglobulin (IgG) microarrays
- inclined pillars
- inkjet printing
- intact polymer molecules
- interconnection and heterogeneous integration
- interdigitized electrodes
- interference effects
- isotropic conductive adhesive (ICA)
-
- j
- jet-and spray-ejection regime
- jet formation dynamics
- experimental set up
- Newtonian glycerol solutions
- experimental design
- fluid properties and laser fluence
- jettability phase diagram
- typical jetting regimes
- viscoelastic alginate solutions
- alginate concentration effects
- experimental design
- ink coating preparation
- jettability phase diagram
- laser fluence effects
- material properties
- non-dimensional numbers
- typical jetting regimes
- jet formation mechanism
- jet morphology
- JetXpert imaging system
-
-
- l
- large area, high throughput LIFT/LIBT inline R2R-printing system
- lase-and-place
- laser ablation transfer (LAT)
- laser-assisted bioprinting (LAB)
- blood vessels
- bone
- cancer research
- effect of laser process and printing parameters
- heart
- history of cell bioprinting
- nervous system
- skin
- technical specifications
- laser-based non-lithographic processes
- laser-based printing/marking process
- laser decal transfer (LDT)
- arrays
- high viscosity donor material
- thicker and thinner voxels
- absorption efficiency
- congruent laser transfer
- CPW
- DMD
- edge acuity
- EDX analysis
- fabricated LDT features
- FRL
- high-aspect 3D stacks and freestanding structures
- intrinsic and engineered characteristics
- laser system and experimental setup
- low-viscosity Ag ink vs. high-viscosity Ag nanopaste
- mechanical stability
- multi-layered stack
- operating parameters
- OTFT
- potential applications and functional properties
- properties
- quantitative study
- self-supporting feature
- SRR
- steep sidewalls
- three complex interconnect patterns
- threshold fluence
- voxel separation mechanism
- voxels transfer
- laser direct-write (LDW)
- process
- techniques
- laser forward transfer process
- laser-guided direct writing (LGDW)
- laser-induced backward transfer (LIBT)
- beam-shaping
- experimental setup
- nanoimprinting approach
- structured carrier substrate
- transparent carrier
- transparent receiver and transparent donor
- unstructured carrier substrate
- laser-induced cavitation bubble
- laser induced forward transfer (LIFT)
- advantages
- amyloid peptides
- composite-matrix-based materials
- of DNA in solid and liquid phase
- donor substrate
- DRL
- early work
- film-free laser printing
- fluids, see fluids
- HA-LIFT
- limitations
- liposomes
- liquid donor films
- LITI
- LMI
- LP-LIFT
- MAPLE-DW
- material transfer
- of metals, see metals
- odorant binding proteins
- principle of operation
- printable inks
- repairing damaged photomasks
- soft materials, see soft materials
- solid donor films
- solid films (ceramics and polymers), see solid films (ceramics and polymers)
- steps
- streptavidin and avidin-biotin complex
- ultra-short laser pulses
- viscosity and size of particles
- laser-induced molecular implantation technique (LIMIT)
- laser-induced patternwise sublimation (LIPS)
- laser induced thermal imaging (LITI)
- laser induced transfer process technique, see laser induced forward transfer (LIFT) technique
- laser-induced transfer technology (LIT)
- gold nanoparticles
- hydrodynamic process
- LIBT
- LIFT
- laser molecular implantation (LMI)
- laser pressure catapulting (LPC)
- laser printing
- additive manufacturing method
- bulk-silicon and silicon films
- beam modification
- computer-based image evaluation
- femtosecond laser printing
- laser pulse energy
- layer thickness
- nanoparticle scattering properties
- nanoparticles fabrication
- normalized size distributions
- processing steps
- ring-shaped intensity distribution
- ring shaped laser beam profile
- scattering spectrum
- silicon wafer
- SOI
- of conducting layers
- of dielectric layers
- metasurfaces
- multi-stage process
- nanoparticles
- pre-structured films
- ribbon
- of semiconductor layer
- spherical nanoparticles
- ultraflat optical element
- Lasersonic® LIFT
- continuous wave laser source and fast modulation
- data flow
- digital printing market expectations and challenges
- future directions
- history of
- inking units
- large area, high throughput LIFT/LIBT inline R2R-printing system
- print experiments and results
- printing heads
- special printing markets
- special test pattern
- synthetic approaches
- time schemes
- transparent inks
- ultrafast pulse modulation
- ultrafast scan
- laser transfer, structures and functioning devices
- chemically/plasma driven traditional etching techniques
- dynamics process see dynamics process
- early demonstrations
- electronic systems
- embedded electronics
- flexible circuits
- hybrid circuits
- individual or multiple components
- metal foils
- patterned thin films
- pick-and-place tools
- self-assembly techniques
- lase-and-place
- laser transfer universe
- laser writing (LW)
- LDT, see laser decal transfer (LDT)
- LIFT, see laser induced forward transfer (LIFT)
- LIFT of liquid films
- LIFT of 3D metal structures
- adhesion
- characteristics
- definition of 3D structures
- demonstrators and potential applications
- droplet impact and solidification
- ejection phenomena
- ejection regimes of pure metal picosecond
- electrical properties
- inclined pillars
- mechanical properties
- metal LIFT printed pillars
- metallurgical microstructure
- copper pillars
- pulse duration and spot size
- reproducibility
- schematic representation of LIFT
- solidification phenomena
- surface roughness
- thermally induced nozzle
- transfer threshold fluence
- LIFT printed copper pillar
- LIFT-printed OTFT
- light-to heat-conversion (LTHC)
- liposomes
- long-pulsed LIFT (LP-LIFT)
-
- m
- mass printing technologies
- material laser recording (MTR)
- MatrigelTM
- matrix-assisted pulsed laser evaporation (MAPLE)
- matrix-assisted pulsed laser evaporation direct write (MAPLE DW)
- metals
- numerical modeling of LIFT for metals
- applications
- beam pattern
- deposited structures
- deposition
- droplet mode deposition
- contact and non-contact configurations
- copper droplets
- donor film
- droplet velocity
- fs excimer LIFT
- jet instability
- jetting phenomena
- liquid jets
- mechanism
- microscale 3D printing
- multiple droplets per laser pulse
- nanosecond LIFT of aluminum
- transfer droplet
- feature characteristics
- metal films
- parametric effects
- donor-film gap spacing
- laser fluence and film thickness
- pulse width
- resolution
- single-step process
- thermal processes
- time scale and fluence
- transfer
- microbatteries
- micro-contact printing (μCP)
- microelectromechanical systems (MEMS)
- microfluidic patterning
- microscale 3D printing
- Mie theory
- mobility (μ)
- multilevel computer-generated holographic structure
-
- n
- nanocrystal quantum dots (NCQDs
- nano-hydroxyapatite (nHA)
- nanoimprinting approach
- nanolasers
- nanomaterial enabled laser transfer (NELT)
- nanoparticles
- laser printing
- printing process
- nano-tip printing technique
- nervous system
- Newtonian glycerol solutions
- experimental design
- fluid properties and laser fluence
- jettability phase diagram
- typical jetting regimes
- nickel-chrome (NiCr) resistors
- non-contact digital technology
- non-contact printing methods
- electrospray deposition
- inkjet printing technique
- photochemistry-based printing
-
- o
- odorant binding proteins (OBPs)
- one-dimensional thermal model
- on/off current ratio (Ion/IOff)
- optical chemical sensor
- organic electronic devices
- organic light-emitting diodes (OLEDs)
- TP-LIFT
- organic thin film transistor (OTFT)
- laser printing of conducting layers
- laser printing of dielectric layers
- laser printing of semiconductor layer
- operation and characteristics
- single step printing
- organ printing
-
- p
- passive components
- photochemistry-based printing
- photoinduced decomposition
- photolithography
- pin printing approach
- platinum and gold inclined pillars
- pluming/splashing regime
- poly(butyl methacrylate) (PBMA)
- poly(3,4-ethylenedioxythiophene) polystyrene sulphonate (PEDOT:PSS)
- poly(ethyl methacrylate) (PEMA)
- poly-3-hexylthiophene (P3HT) semiconductor material
- polyimide blistering layer
- polymer laser-absorbing layer
- polymer sacrificial layer
- poly[2-methoxy-5-(2-ethylhexyloxy)-1,4-phenylenevinylene] (MEH-PPV)
- poly(methylmethacrylate) (PMMA)
- polymethyl methacrylate polymer layer
- polyvinyl butyral (PVB) inks
- power-law relaxation time model
- pulsed laser deposition (PLD)
- pump-probe imaging
-
- q
- quantum dot-based light emitting diodes
-
- r
- Rayleigh-Plateau instability
- reactive ion etching
- reactive LIFT (rLIFT)
- red-green-blue PFO pixel transfer
- robotic micro-needle array fabrication
-
- s
- satellites
- SAW biosensor arrays
- “Scotch tape” test
- screen printing
- Seebeck coefficient
- selective laser melting (SLM)
- sequential laser printing
- shadowgraphy studies
- ceramic thin films
- compliant receivers
- silicon-on-insulator (SOI)
- silver split-ring resonators (SRR)
- single step printing, OTFT device
- slot-die approach
- soft materials
- jet formation, see jet formation dynamics
- jet formation mechanism
- jet morphology
- jet velocity
- laser printing applications
- multilayer hydrogel-cell planar structure
- sol–gel technique
- solid films (ceramics and polymers)
- energy harvesting
- chalcogenide thin films
- micro-scale thermoelectric generator
- thermoelectric generator
- laser pulse interference-assistedLIFT
- BLAST
- standing wave interference from multiple layers
- LIBT
- experimental setup
- ion beam milling/UV beam machining
- nanoimprinting approach
- structured carrier substrate
- transparent carrier
- transparent receiver and transparent donor
- unstructured carrier substrate
- polymer films
- pre-machined ceramic micro-discs, LIFT printing of
- shadowgraphy studies
- ceramic thin films
- compliant receivers
- solvent orthogonality
- spatial light modulator (SLM)
- spin coating
- spray coating technology
- streptavidin
- and avidin-biotin complex
- stroboscopic imaging techniques
- surface acoustic waves (SAW)
- biosensors
- chemical sensors
- surface tension
-
- t
- tert-butyl acrylate (TBA)
- thermoelectric generator
- thermo-mechanical selective laser-assisted die transfer
- thin-film transistor-liquid crystal displays (TFT-LCD)
- 3D structures
- through silicon vias (TSVs)
- time-resolved imaging of jet formation
- time-resolved imaging of droplet deposition
- tissue engineering
- blood vessels
- bone
- heart
- nervous system
- skin
- traditionally packaged electronic components
- triazene DRL-LIFT
- triazene polymers (TP)
- chemical structure
- front and back side ablation
- higher ablation rates
- LIFT
- application
- aryltriazene photopolymers
- biomembrane model system
- materials
- OLEDs
- polystyrene microbeads
- sensors
- PS-microbead pixel
- UV-vis absorption spectrum
- tri-color pixels
- two-dimensional thermal model
- two-temperature model
-
- u
- ultra flat lens
- ultra-short laser pulses
- UV photolysis
-
- v
- viscoelastic alginate solutions
- alginate concentration effects
- experimental design
- ink coating preparation
- jettability phase diagram
- laser fluence effects
- material properties
- non-dimensional numbers
- typical jetting regimes
- voxel separation mechanism
-
- w
- Wenzel wetting
- wild-type OBP from bovine (wtbOBP)
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