Researchers fabricate first large-area, full-color quantum dot display

February 21, 2011 by Lisa Zyga

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Electroluminescence image of a four-inch full-color quantum dot display with a resolution of 320 x 240 pixels. Image credit: Tae-Ho Kim, et al. ©2011 Macmillan Publishers Limited.

(PhysOrg.com) -- For more than a decade, researchers have been trying to make TV displays out of quantum dots. Theoretically, quantum dot displays could provide extremely high-resolution images and higher energy efficiencies than current TVs. Now in a new study, researchers have presented the first large-area, full-color quantum dot display that could lead to the development of displays for the next-generation TVs, mobile phones, digital cameras, and portable game systems.

The researchers, Tae-Ho Kim and coauthors from various institutes in South Korea, have published their study on the first four-inch, full-color quantum dot display in a recent issue of Nature Photonics. The display consists of a film printed with trillions of the tiny quantum dots (an average of 3 trillion per cm²). The quantum dots emit light at a specific wavelength (color) that can be tuned by changing the size of the quantum dots.

Previous attempts to make full-color quantum dot displays have faced challenges in that image quality tended to decrease with the size of the display. To overcome this challenge, the researchers in the current study used a different method for applying the quantum dots to the film’s surface. Instead of spraying the quantum dots onto the film, the researchers created an “ink stamp” out of a patterned silicon wafer. They used the stamp to pick up strips of size-selected quantum dots, and then stamp them onto the substrate. Unlike the spraying methods, this method does not require the use of a solvent, which previously reduced color brightness.

As the results showed, the new quantum dot display has a greater density and uniformity of quantum dots, as well as a brighter picture and higher energy efficiency than previous quantum dot displays. The new display is also flexible, so applications could include roll-up portable displays or flexible lighting applications. The technology could also be used in photovoltaic devices, which would especially benefit from quantum dots’ high energy efficiency.

More information: Tae-Ho Kim, et al. “Full-colour quantum dot displays fabricated by transfer printing.” Nature Photonics. DOI:10.1038/nphoton.2011.12.
via: Nature News

Source

Polynano carbon nanotube field emission device

Polynano Glass---( Nano Moving Display Glass )

Polynano carbon nanotube field emission device (CNT-FED) features perfect flat outer screen surface, flat rear screen, very thin thickness, high beam current output of carbon Nanotube emission cathode, circle phosphor dot screen anode, monochrome output, see-through type , wide-environmental operation application. Monochrome display and image interface application.

Snipped from here:
http://www.glassonweb.com/articles/artic...

Finally something to generate some royalty revenue for Keesmann and ANHI (Applied Nanotech Holdings Inc.)=(Nano-Proprietary - NNPP)!

Long time coming but welcomed with open arms and pocketbooks.

Ya think? ;-) Surely Bijou is all over this like a hawk in heat.

OTOH.............???????

Just in case NOT here are the company particulars:
Polytron Technologies, Inc.
http://www.polytron.com.tw/company.php?l...

Polytron Technologies Inc. is a subsidiary of Polytronix, Inc.:
http://www.polytronix.com/
http://www.polytron.com.tw/
http://www.polytron.com.tw/product_small...
Polytron Technologies, Inc.
330 No.67, Taode Road., Taoyuan City, 330, Taiwan
Tel：+886-3-3712958 FAX：+886-3-3712968
sam@polytron.com.tw

POLYTRONIX INC.

Contact Information

805 Alpha Drive
Richardson, Texas 75081-2861

Toll Free: 1-800-904-7045
Phone: 972-238-7045
Fax: 972-644-0805

For technical and engineering questions,
contact: engineering@polytronix.com

For product information and availability,
contact: sales@polytronix.com

POLYTRONIX INC. URL:

http://www.polytronix.com/contacts.htm

TEXAS, eh!!!!

Howdy, pardner.

Stable field emission from arrays of vertically aligned free-standing metallic nanowires

Stephane Xavier et al 2008 Nanotechnology 19 215601 (7pp) doi: 10.1088/0957-4484/19/21/215601

	PDF (1.61 MB) | References

Stephane Xavier^1,5, Stefan Mátéfi-Tempfli², Etienne Ferain³, Stephen Purcell⁴, Shaïma Enouz-Védrenne¹, Laurent Gangloff¹, Eric Minoux¹, Ludovic Hudanski¹, Pascal Vincent⁴, Jean-Philippe Schnell¹, Didier Pribat¹, Luc Piraux² and Pierre Legagneux^1,5
1 Nanocarb Laboratory, Thales—Ecole Polytechnique, Route Départementale 128, 91767 Palaiseau, France
² Unité de Physico-Chimie et de Physique des Matériaux, Croix du sud 1, B-1348 Louvain-la-Neuve, Belgium
³ Unité de Physique et de Chimie des Hauts Polymères, Croix du sud 1, B-1348 Louvain-la-Neuve, Belgium
⁴ Laboratoire de Physique de la Matière Condensée et Nanostructures, Université Claude Bernard de Lyon 1, CNRS UMR 5586, 43 Blvd du 11 Novembre 1918, 69622 Villeurbanne, France
⁵ Authors to whom any correspondence should be addressed
E-mail: stephane.xavier@thalesgroup.com and pierre.legagneux@thalesgroup.com

Abstract. We present a fully elaborated process to grow arrays of metallic nanowires with controlled geometry and density, based on electrochemical filling of nanopores in track-etched templates. Nanowire growth is performed at room temperature, atmospheric pressure and is compatible with low cost fabrication and large surfaces. This technique offers an excellent control of the orientation, shape and nanowires density. It is applied to fabricate field emission arrays with a good control of the emission site density. We have prepared Co, Ni, Cu and Rh nanowires with a height of 3 µm, a diameter of 80 nm and a density of ~10⁷ cm^-2. The electron field emission measurements and total energy distributions show that the as-grown nanowires exhibit a complex behaviour, first with emission activation under high field, followed by unstable emission. A model taking into account the effect of an oxide layer covering the nanowire surface is developed to explain this particular field emission behaviour. Finally, we present an in situ cleaning procedure by ion bombardment that collectively removes this oxide layer, leading to a stable and reproducible emission behaviour. After treatment, the emission current density is ~1 mA cm^-2 for a 30 V µm^-1 applied electric field.

Print publication: Issue 21 (28 May 2008)
Received 28 January 2008, in final form 13 March 2008
Published 21 April 2008

PDF (1.61 MB) | References

Source

Conclusion from PDF:
4. Conclusion
In conclusion, metallic nanowires grown in supported
nanoporous track-etched templates are a competitive solution
for the realization of field emission displays (FEDs) or
backlight units for liquid crystal displays. The growth
process is performed at room temperature and atmospheric
pressure, and is compatible with very large surfaces. With
this process, we have obtained nanowires made of different
materials (Co, Ni, Cu and Rh). The field emission and total
energy distribution measurements have shown that, because
of the presence of an oxide layer observed by TEM on asgrown
nanowire surfaces, emission activation is necessary
and the emission is unstable in that case. We propose here
an in situ treatment with ion bombardment to collectively
‘clean’ the nanowire array and eliminate this oxide layer.
After this in situ treatment, the NWs exhibit a stable and
reproducible emission. Activation is no longer required. We
have observed a good emission stability for several hours. This
process can be potentially used for field emission displays,
as the achieved current density is compatible with such an
application.

Sony/Patents/Nanowire/FED/CNT/Display

1)
United States Patent Application
20080067915

Ishida; Takehisa ; et al.

March 20, 2008
Electron emitter and a display apparatus utilizing the same

Abstract

A field effect electron emitting apparatus using nano-wire electron emitters is disclosed where each nano-wire electron emitter may be grown in a pore of an insulating layer and/or may have at least a portion exposed from the pore. A method of manufacturing a field effect electron emitting apparatus is also disclosed. The field effect electron emitting apparatus may be used in a display.

Claims
1. A field effect electron emitting apparatus comprising a cathode, an insulating layer on or adjacent to the cathode having an array of pores, and a grown nano-wire electron emitter in each pore, each nano wire electron emitter connected to the cathode.

26. A field effect display comprising a field effect electron emitting apparatus as claimed in claim 1, and a phosphor coated screen on or spaced parallel to the field effect electron emitting apparatus.

Inventors:
Ishida; Takehisa; (Singapore, SG) ; Ng; Wei B.; (Singapore, SG)

Assignee Name and Adress:
Sony Corporation
Tokyo
JP

http://tinyurl.com/yq4jgd

2)
United States Patent Application 20080067912

Ishida; Takehisa
March 20, 2008
Electron emitter and a display apparatus utilizing the same

Abstract

A field effect electron emitting apparatus is disclosed comprising an insulating layer having an array of pores, each pore has at least one nano-wire electron emitter which is shorter than the pore and/or each pore may have a plurality of nano-wire electron emitters. A method of manufacturing a electron emitting array is also disclosed. The field effect electron emitting apparatus may be used in a display.
Inventors: Ishida; Takehisa; (Singapore, SG)

Assignee Name and Adress:
Sony Corporation
Tokyo
JP

Claims
1. A field effect electron emitting apparatus comprising a cathode, an insulating layer on or adjacent to the cathode having an array of pores, at least one nano-wire electron emitter within each pore, each nano-wire electron emitter being shorter than the pore and connected to the cathode, and a gate electrode on or adjacent to the insulating layer.

2. A field effect electron emitting apparatus comprising a cathode, an insulating layer on or adjacent to the cathode having an array of pores, a plurality of nano-wire electron emitters in each pore connected to the cathode, a gate electrode on or adjacent to the insulating layer.

3. A field effect electron emitting apparatus comprising a cathode, an insulating layer on or adjacent to the cathode having an array of pores, at least one electron emitter within each pore, each electron emitter being shorter than the pore and connected to the cathode, a gate electrode on or adjacent to the insulating layer, and a secondary electron emission (SEE) layer on the sidewall of each pore.

4. The electron emitting apparatus as claimed in claim 1 wherein each nano-wire is a carbon nano-tube (CNT).

http://tinyurl.com/35e5os

Sony, god love 'em, they make Canon look like amateurs and will bury SED!!

CNTs are THE future of displays - Sony has spoken...and when Sony speaks, I listen. What was that last bit, Sony??...."Buy NNPP!!!"......???