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FBO DAILY - FEDBIZOPPS ISSUE OF SEPTEMBER 02, 2017 FBO #5762
SPECIAL NOTICE

A -- TECHNOLOGY/BUSINESS OPPORTUNITY Efficient Assembly of Highly Ordered Nanocrystal Superlattices - Image of Colloidal Crystals

Notice Date

8/31/2017
 

Notice Type

Special Notice
 

NAICS

#238990 — All Other Specialty Trade Contractors
 

Contracting Office

Department of Energy, Lawrence Livermore National Laboratory (DOE Contractor), Industrial Partnerships & Commercialization, 7000 East Avenue, L-795, Livermore, California, 94550
 

ZIP Code

94550
 

Solicitation Number

FBO348-17
 

Archive Date

10/3/2017
 

Point of Contact

Connie L Pitcock, Phone: 925-422-1072
 

E-Mail Address

pitcock1@llnl.gov
(pitcock1@llnl.gov)
 

Small Business Set-Aside

N/A
 

Description

Image of Colloidal Crystals TECHNOLOGY/BUSINESS OPPORTUNITY Efficient Assembly of Highly Ordered Nanocrystal Superlattices Opportunity : Lawrence Livermore National Laboratory (LLNL), operated by the Lawrence Livermore National Security (LLNS), LLC under contract no. DE-AC52-07NA27344 (Contract 44) with the U.S. Department of Energy (DOE), is offering the opportunity to license an innovative technology for collaborative research and development towards commercialization. Background : Ordered nanocrystal superlattices are emerging materials that have wide spread applications in photodetectors, light emitting devices, solid state lasers, solar cells, thermoelectric devices, field effect transistors, and memory devices. The degree of order in the superlattices is crucial for their applications. A process that can produce large scale ordered nanocrystal superlattices is therefore greatly desired. Currently, nanocrystal superlattices are fabricated with solvent evaporation methods, such as dip coating, spinning coating, spray coating, drop casting, ink jet printing. These processes trade off fabrication speed and crystalline quality of the films; fast fabrication results in disorder or poorly ordered superlattices, whereas a highly ordered superlattice often requires a fairly long fabrication time. For example, it would take a few days or weeks for solvent evaporation methods to generate ordered 3-dimensional superlattices. In addition, the lattice constant of the superlattice made by solvent evaporation methods is not a tunable parameter since it is dictated by the size of the nanocrystal core and length of the capping ligands. Description : LLNL's novel technique uses electric fields to drive and control assembly. In the literature such methods have heretofore only formed disorder ensembles. LLNL's innovative method increases local nanocrystal concentration, initiating nucleation and growth into ordered superlattices. Nanocrystals remain solvated and mobile throughout the process, allowing fast fabrication of ordered superlattices. Nanocrystals covered by this approach include, but are not limited to, metal nanocrystals, semiconducting nanocrystals (quantum dots), and insulating nanocrystals, or a combination of those. Solvents used in this approach include, but are not limited to, hexane(s), toluene, and chloroform. This process can be easily scaled to cubic meter solution volume and square meter surface area. Advantages : This innovative nanocrystal superlattice fabrication method is faster and offers more tunability than current solvent evaporation or destabilization methods, and can produce superlattices with morphologies beyond colloidal crystals in other material systems, enabling fabrication of nanocrystal devices with complex structures. Specifically, LLNL's method: •1) 1) Produces highly ordered colloidal crystals in much shorter times than current methods. For example, has created 2 micron thick films with domain sizes greater than 25 microns. •2) 2) Creates denser materials than traditional field driven methods, including electrophoretic deposition (EPD). For example, can create ordered nanoparticle ensembles with a face centered cubic structure that has ~74% of packing density, which is 9% denser than the disordered structure (~65%) created by previous EPD methods. •3) 3) Offers means to tune the structure of nanoparticle ensembles, including the degree of order, lattice constant, degree of preferential orientation, and morphology on patterned surfaces, which is crucial for the fabrication of devices with complex structures. •4) 4) Allows one to change the capping ligands on the surfaces of nanoparticles at the same time as they are being assembled/deposited. •5) 5) I s scalable, and about 10-100 times faster than solvent evaporation methods that produce the similar degree of order. •6) 6) Suppresses the solvent evaporation induced uniaxial contraction towards substrates. •7) 7) Uses nanoparticle solutions at very low concentrations (<1 wt%). •8) 8) R eusable solvent, leading to substantially less waste, and •1) 9) Is reversible, which means that turning off the electrical field causes the nanoparticle deposits to dissolve, leading to less waste of nanocrystals. Potential Applications : •· Photodetectors •· Light emitting devices •· Solid state lasers •· Solar cells •· Thermoelectric devices •· Field effect transistors •· Memory devices Development Status: LLNL has filed a patent application for this innovation. For additional technical information, refer to article "Reversible, Tunable, Electric-Field Driven Assembly of Silver Nanocrystal Superlattices" http://pubs.acs.org/doi/ipdf/10.1021/acs.nanolett.7b01323 ; and presentation "Reversible, Tunable, Electric-Field Driven Assembly of Silver Nanocrystal Superlattices". LLNL is seeking industry partners with a demonstrated ability to bring such inventions to the market. Moving critical technology beyond the Laboratory to the commercial world helps our licensees gain a competitive edge in the marketplace. All licensing activities are conducted under policies relating to the strict nondisclosure of company proprietary information. Please visit the IPO website at https://ipo.llnl.gov/resources for more information on working with LLNL and the industrial partnering and technology transfer process. Note: THIS IS NOT A PROCUREMENT. Companies interested in commercializing LLNL's Efficient Assembly of Highly Ordered Nanocrystal Superlattices technology should provide a written statement of interest, which includes the following: 1. Company Name and address. 2. The name, address, and telephone number of a point of contact. 3. A description of corporate expertise and facilities relevant to commercializing this technology. Written responses should be directed to: Lawrence Livermore National Laboratory Industrial Partnerships Office P.O. Box 808, L-795 Livermore, CA 94551-0808 Attention: FBO 348-17 Please provide your written statement within thirty (30) days from the date this announcement is published to ensure consideration of your interest in LLNL's Efficient Assembly of Highly Ordered Nanocrystal Superlattices technology.
 

Web Link

FBO.gov Permalink
(https://www.fbo.gov/spg/DOE/LLNL/LL/FBO348-17/listing.html)
 

Record

SN04657032-W 20170902/170831233551-bdc37602b33d00d5d74ec389fab4b9c0 (fbodaily.com)
 

Source

FedBizOpps Link to This Notice
(may not be valid after Archive Date)

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