Patents by Inventor Michael J. Ford
Michael J. Ford has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
-
Patent number: 10559754Abstract: The present disclosure describes additives that attenuate a specific transport channel in ambipolar semiconductors to achieve unipolar characteristics. Carrier selective traps are included in the ambipolar semiconductors and are chosen on the basis of energetic preferences for holes or electrons and the relative positions of the molecular orbital energies of host polymer and the dopants. In one embodiment, a composition of matter useful as a current transport region in an organic semiconductor device comprises a semiconducting polymer; and means for accepting holes (e.g., a hole trapping compound) injected into the current transport region so as to impede conduction of the holes in the semiconducting polymer. This simple solution-processable method can improve the on and off current ratios (ION/IOFF) of OFETs by up to three orders of magnitude. Moreover, the treatment yields tailored blends that can be used to fabricate complementary inverters with excellent gain and low-power characteristics.Type: GrantFiled: May 19, 2017Date of Patent: February 11, 2020Assignee: THE REGENTS OF THE UNIVERSITY OF CALIFORNIAInventors: Michael J. Ford, Hengbin Wang, Guillermo C. Bazan
-
Patent number: 10367144Abstract: The present disclosure demonstrates that the introduction of electron deficient fullerene acceptors into thin films comprised of the high-mobility semiconducting polymers suppresses an undesirable “double-slope” in the current-voltage characteristics, improves operational stability, and changes ambipolar transport to unipolar transport. Examination of a variety of high ? polymers shows general applicability. The present disclosure also shows that instability is further reduced by tuning the relative electron affinity of the polymer and fullerene by creating blends containing different fullerene derivatives and semiconductor polymers. One can obtain hole ? values up to 5.6 cm2 V?1 s?1 that are remarkably stable over multiple bias-sweeping cycles. The results provide a simple, solution-processable route to dictate transport properties and improve semiconductor performance in systems that display similar non-idealities.Type: GrantFiled: January 6, 2017Date of Patent: July 30, 2019Assignee: THE REGENTS OF THE UNIVERSITY OF CALIFORNIAInventors: Michael J. Ford, Guillermo C. Bazan
-
Publication number: 20190181348Abstract: Synthesis of lyotropic semiconducting polymers having novel side chains enabling control over crystalline fraction, crystalline orientation, and the unit cell (specifically the ?-stacking distance). Moving the branch point in the side chain further from the conjugated backbone not only retains the lyotropic liquid crystalline behavior as observed by UV-vis and POM, but also achieves reduced ?-stacking distance. This results in higher charge carrier mobility, reaching (in one or more examples) a mobility of at least 0.41 cm2V?1s?1 when the polymers were non-aligned.Type: ApplicationFiled: September 27, 2018Publication date: June 13, 2019Inventors: Colin R. Bridges, Ming Wang, Michael J. Ford, Guillermo C. Bazan, Rachel A. Segalman
-
Patent number: 10249821Abstract: Design of side chains yielding highly amphiphilic conjugated polymers is proven to be an effective and general method to access lyotropic liquid crystalline mesophases, allowing greater control over crystalline morphology and improving transistor performance. The general strategy enables variations in structure and interactions that impact alignment and use of liquid crystalline alignment methods. Specifically, solvent-polymer interactions are harnessed to facilitate the formation of high quality polymer crystals in solution. Crystallinity developed in solution is then transferred to the solid state, and thin films of donor-acceptor copolymers cast from lyotropic solutions exhibit improved crystalline order in both the alkyl and ?-stacking directions. Due to this improved crystallinity, transistors with active layers cast from lyotropic solutions exhibit a significant improvement in carrier mobility compared to those cast from isotropic solution.Type: GrantFiled: July 27, 2017Date of Patent: April 2, 2019Assignee: THE REGENTS OF THE UNIVERSITY OF CALIFORNIAInventors: Colin R. Bridges, Michael J. Ford, Guillermo C. Bazan, Rachel A. Segalman
-
Patent number: 10217951Abstract: Conjugated polymer-based organic field-effect transistors have garnered attention since the solution processability of the semiconductor material raises the possibility of lower device fabrication costs, and considerable progress has been made on achieving high mobility systems. Further improvements in charge carrier mobility while using non-specialized deposition techniques and minimizing the volume of semiconductor used in the fabrication process are important considerations for practical implementation. Here, a method of fabricating devices is disclosed that uses a technique (for example, a scalable blade-coating technique) to cast polymer thin film devices from blend solutions with one component being the polymer semiconductor and the other being a commodity polymer. Even when mixing the semiconducting polymer with 90% polystyrene by weight, an average mobility of 2.7±0.4 cm2 V?1 s?1 can be obtained.Type: GrantFiled: August 19, 2016Date of Patent: February 26, 2019Assignee: THE REGENTS OF THE UNIVERSITY OF CALIFORNIAInventors: Michael J. Ford, Guillermo C. Bazan
-
Publication number: 20180033971Abstract: Design of side chains yielding highly amphiphilic conjugated polymers is proven to be an effective and general method to access lyotropic liquid crystalline mesophases, allowing greater control over crystalline morphology and improving transistor performance. The general strategy enables variations in structure and interactions that impact alignment and use of liquid crystalline alignment methods. Specifically, solvent-polymer interactions are harnessed to facilitate the formation of high quality polymer crystals in solution. Crystallinity developed in solution is then transferred to the solid state, and thin films of donor-acceptor copolymers cast from lyotropic solutions exhibit improved crystalline order in both the alkyl and ?-stacking directions. Due to this improved crystallinity, transistors with active layers cast from lyotropic solutions exhibit a significant improvement in carrier mobility compared to those cast from isotropic solution.Type: ApplicationFiled: July 27, 2017Publication date: February 1, 2018Applicant: The Regents of the University of CaliforniaInventors: Colin R. Bridges, Michael J. Ford, Guillermo C. Bazan, Rachel A. Segalman
-
Publication number: 20170338415Abstract: The present disclosure describes additives that attenuate a specific transport channel in ambipolar semiconductors to achieve unipolar characteristics. Carrier selective traps are included in the ambipolar semiconductors and are chosen on the basis of energetic preferences for holes or electrons and the relative positions of the molecular orbital energies of host polymer and the dopants. In one embodiment, a composition of matter useful as a current transport region in an organic semiconductor device comprises a semiconducting polymer; and means for accepting holes (e.g., a hole trapping compound) injected into the current transport region so as to impede conduction of the holes in the semiconducting polymer. This simple solution-processable method can improve the on and off current ratios (ION/IOFF) of OFETs by up to three orders of magnitude. Moreover, the treatment yields tailored blends that can be used to fabricate complementary inverters with excellent gain and low-power characteristics.Type: ApplicationFiled: May 19, 2017Publication date: November 23, 2017Applicant: The Regents of the University of CaliforniaInventors: Michael J. Ford, Hengbin Wang, Guillermo C. Bazan
-
Publication number: 20170200894Abstract: The present disclosure demonstrates that the introduction of electron deficient fullerene acceptors into thin films comprised of the high-mobility semiconducting polymers suppresses an undesirable “double-slope” in the current-voltage characteristics, improves operational stability, and changes ambipolar transport to unipolar transport. Examination of a variety of high ? polymers shows general applicability. The present disclosure also shows that instability is further reduced by tuning the relative electron affinity of the polymer and fullerene by creating blends containing different fullerene derivatives and semiconductor polymers. One can obtain hole ? values up to 5.6 cm2 V?1 s?1 that are remarkably stable over multiple bias-sweeping cycles. The results provide a simple, solution-processable route to dictate transport properties and improve semiconductor performance in systems that display similar non-idealities.Type: ApplicationFiled: January 6, 2017Publication date: July 13, 2017Applicant: The Regents of the University of CaliforniaInventors: Michael J. Ford, Guillermo C. Bazan
-
Publication number: 20170054096Abstract: Conjugated polymer-based organic field-effect transistors have garnered attention since the solution processability of the semiconductor material raises the possibility of lower device fabrication costs, and considerable progress has been made on achieving high mobility systems. Further improvements in charge carrier mobility while using non-specialized deposition techniques and minimizing the volume of semiconductor used in the fabrication process are important considerations for practical implementation. Here, a method of fabricating devices is disclosed that uses a technique (for example, a scalable blade-coating technique) to cast polymer thin film devices from blend solutions with one component being the polymer semiconductor and the other being a commodity polymer. Even when mixing the semiconducting polymer with 90% polystyrene by weight, an average mobility of 2.7±0.4 cm2V?1s?1 can be obtained.Type: ApplicationFiled: August 19, 2016Publication date: February 23, 2017Applicant: The Regents of the University of CaliforniaInventors: Michael J. Ford, Guillermo C. Bazan
-
Patent number: 5256382Abstract: Heating apparatus comprises a chamber (10) in which articles to be heated (e.g. sterilized) are located via a door (16) and which can be filled with a blanket of dense hot organic vapor during a heating phase. The liquid which creates the vapor blanket is located in an annular reservoir (20) and is heated to above vaporization temperature by an electrical band heater (22).Type: GrantFiled: July 23, 1991Date of Patent: October 26, 1993Assignee: Autocar Equipment LimitedInventors: Michael A. J. Ford, Christopher R. Bailey
-
Patent number: 4116758Abstract: A process for producing high yield chemimechanical pulps from woody lignocellulosic material, such as wood chips, whereby the material is treated with an aqueous solution of a mixture of sulfite and bisulfite, said solution being of sufficient strength to sulfonate said material to at least about 85% of the maximum level of sulfonation that can be achieved on said material without reducing the pulp yield to below 90% and subjecting the resulting sulfonated material to mechanical defibration.Type: GrantFiled: October 3, 1977Date of Patent: September 26, 1978Assignee: Canadian International Paper Co.Inventors: Michael J. Ford, Prescott Elliott Gardner
-
Patent number: 3963550Abstract: A grain door and method of making the same wherein thin metallic straps having arcuate ends are partially adhesively secured to a double-face corrugated medium, and wherein the straps may be equipped with novel fittings for extension bands and are also adapted for receipt of center braces having horizontally flat tangs.Type: GrantFiled: October 21, 1974Date of Patent: June 15, 1976Assignee: Omni CorporationInventors: William E. Bruning, Michael J. Ford