Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
Poly(amic acid)s and their ionic salt solutions: Synthesis, characterization and stability study |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
A new interpretation of the kinetic model for the imidization reaction of PMDA-ODA and BPDA-PDA poly(amic acid)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis and characterization of new organosoluble poly(ether imide)s derived from various novel bis(ether anhydride)s |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Synthesis of novel polyimides from dianhydrides with flexible side chains |
Polyimides based on rhenium(I) diimine complexes |
Polyimides based on rhenium(I) diimine complexes |
Polyimides based on rhenium(I) diimine complexes |
Polyimides based on rhenium(I) diimine complexes |
Polyimides based on rhenium(I) diimine complexes |
Polyimides based on rhenium(I) diimine complexes |
Polyimides based on rhenium(I) diimine complexes |
Polyimides based on rhenium(I) diimine complexes |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New highly phenylated bis(phthalic) and bis(naphthalic) anhydrides and polyimides therefrom |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
New photoalignable polyimides and their ability to control liquid-crystal alignment |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
Proton conducting polyimides from novel sulfonated diamines |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
High-modulus poly(p-phenylenepyromellitimide) films obtained using a novel gel-drawing technique |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
Effect of structure on the thermal behaviour of bisitaconimide resins |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
1-Amino-4,5-8-naphthalenetricarboxylic acid-1,8-lactam-4,5-imide-containing macrocycles: Synthesis, molecular modeling and polymerization |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Synthesis of aromatic benzoxazole polymers for high T, low dielectric properties/Title> |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Polybenzobisthiazoles – Critical issues in their performance and properties |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Electrical breakdown and electrostatic phenomena in ultra-thin polyimide Langmuir-Blodgett films |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Humid ageing of polyetherimide: Chemical and physical interactions with water |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
Transport of water in high T polymers: A comparison between interacting and non-interacting systems |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
New developments in the adhesion promotion of electroless Ni or Cu films to polyimide substrates |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Surface modification of polyimide to improve its adhesion to deposited copper layer |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Study on the structure and adhesion of copper thin films on chemically modified polyimide surfaces |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Chemical interaction of Fe, Ni and Au with poly(vinyl chloride) and poly(tetrafluoroethylene) during thermal evaporation and the effect of post-metallization X-ray irradiation studied by in situ X-ray photoelectron spectroscopy |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Plasma polymer adhesion promoters for metal-polymer systems |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
Metallized polyimide films with high reflectivity and electroconductivity |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
RF plasma etching of a polyimide film with oxygen mixed with nitrogen trifluoride |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Comparison of polyimide film surface properties exposed to real and simulated space environments: Relevance of atomic oxygen effects to wettability in space |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Development and optimization of a laser carbonized polyimide film as a sensor substrate for an all-polymer humidity sensor |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fluorinated copolyimides for microelectronics applications |
Fabrication of thin-film transistors on polyimide films |
Fabrication of thin-film transistors on polyimide films |
Fabrication of thin-film transistors on polyimide films |
Fabrication of thin-film transistors on polyimide films |
Fabrication of thin-film transistors on polyimide films |
Fabrication of thin-film transistors on polyimide films |
Fabrication of thin-film transistors on polyimide films |
Fabrication of thin-film transistors on polyimide films |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Polyimide/polystyrene nanocomposite films as membranes for gas separation and precursors for polyimide nanofoams |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Amine-quinone polyimides – High temperature polymers that protect iron against corrosion |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Semicrystalline DABP-BTDA polyimide modified by fullerenes for wear protection |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Influence of aramid fabric on fretting wear performance of polyetherimide composite |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |
Semicrystalline polyimides for advanced composites |