We propose to develop and commercialize a Laser Assisted Molecular Beam Deposition (LAMBD) process for the growth of single crystal lattice matched CeO2 thin films on a Si substrate and thin film Si on CeO2 for the development and commercialization of silicon-on-insulator (SOI) devices and… More

We propose to develop and commercialize a Pulsed Arc Molecular Beam Processing (PAMBP) process which can be used to produce high quality and high purity thin films as well as nanopowders. The PAMBP source uses a pulsed valve to generate gas pulses between two electrodes. During the gas pulse, an… More

50190-98-I High Magnetic Field T1-Based Superconducting Tape on Biaxially Textured Flexible Metallic Substrates--ABMP Tech Corporation, c/o University at Buffalo Incubator, 1576 Sweet Home Road, Amherst, NY 14228-2710; (732) 885-5909 Dr. Robert L. DeLeon, Principal Investigator Dr. Gary S. Tompa,… More

This Small Business Innovative Research (SBIR) Phase I project will develop a process to generate bulk quantities of Metallo-Carbohederenes (met-cars). The project will use a particle and deposition technology, called Laser Assisted Molecular Beam Deposition, which is ideal for producing met-cars… More

AMBPTech in collaboration with Dr Wayne Anderson's group at SUNY Buffalo proposes to develop a technology for manufacturing high performance GaN transistors on roll to roll flexible non-conducting foils. This effort will transfer the leading research done at the University of Buffalo in the area… More

The proposed program by AMBP Tech and Professor Sarjeant's group at SUNY Buffalo will develop and demonstrate a rapid large area deposition process of high energy density amorphous fluorinated carbon (a-C:F) films onto thin aluminum (4um thin) electrode substrates. The innovative research consists… More

In the Phase I SBIR effort, AMBP Tech developed a new film deposition technology, Pulsed Arc Molecular Beam Deposition (PAMBD). This new approach to depositing films offers substantial advantages over many existing deposition technologies. We propose to optimize and perfect this technology in a… More

Directed Energy Weapons of the microwave nature require high microwave power devices which employ insulators. Currently, a major limitation to the microwave power that can be generated is the limited electric field an insulator can withstand within vacuum due to the surface flashover phenomena. … More

AMBP Tech in collaboration with the ESI of SUNY UB has demonstrated the improvement of surface flashover on dielectrics by a factor of 2x utilizing laser processing techniques. Based on our extensive experimentation and characterization in Phase I we have developed a working hypothesis that unites… More

AMBP Tech in collaboration with ITN Energy Systems will demonstrate its Excimer Laser Processing capabilities as an ideal solution to reducing the thermal budgets necessary to process high efficiency CIGS solar cells. This will allow the use of lightweight and cheaper polymer substrates, thus… More

AMBP Tech will implement Zinc Oxide high mobility material technology it has developed specifically for flexible electronics into a direct write process onto large area polymer membranes. The implementation of this technology will form the core components of transmit/receive components of a… More

Second generation, coated superconductor wires (YBCO material), needed for electricity transmission, have demonstrated the ability to produce 100 Amp, long-length conductors at approximately 10 times the cost of copper wires. This cost is unacceptable. In order to meet the DOE¿s cost target of… More

AMBP Tech's concept for a dynamic color-ratio infrared simulator source is based on technology related to large-area deformable mirrors. For spatial resolution it builds on the example of the state-of-the art ISTAR system, but with respect to spectral content it incorporates more than one… More

The Small Business Innovation Research (SBIR) Phase I project proposes to achieve recently reported gains in CIGS solar cell efficiency from in-situ laser deposition, by using an ex-situ laser annealing approach that is compatible with an existing pilot manufacturing system. The proposed ex-situ… More