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Luminescent Technologies Inc., a provider of computational metrology and inspection solutions for the global semiconductor manufacturing industry, and Dai Nippon Printing Company, Ltd. announced today the successful completion of the first phase of a three-year joint development program for computational metrology and inspection using Luminescent’s Automated Image Processing Hub (LAIPH) platform.  The goals of the collaboration are to dramatically reduce photomask defect review and analysis cycle time while simultaneously improving overall mask quality. The first phase resulted in the successful implementation of LAIPH Aerial Image Analyzer (AIA) software in DNP’s Kami-Fukuoka photomask production plant.

“Today’s advanced design technologies for semiconductors require sophisticated software to enable quick and accurate disposition of reticle defects for state-of-the-art lithography tools,” said Mr. Hideyoshi Takamizawa, deputy general manager of Photomask Technical Department, 1st Production Division, Fine Electronics Business Operationsof DNP.  “We are impressed with results obtained from Luminescent’s AIA software and look forward to extending the use of the LAIPH platform for further applications.”

"We are proud DNP has chosen Luminescent to assist with their world class performance in mask cycle time and quality," added Dr. Linyong (Leo) Pang, Sr. Vice President of Luminescent.  “Our contribution to DNP’s manufacturing success is further proof of the power of computational methods in defect metrology and inspection.”

Aerial Image Analyzer (AIA) is one of the applications on Luminescent’s LAIPH platform to address the growing challenges of inspection in advanced mask shops and wafer fabs. It provides precise quantitative analysis of defect images captured by Carl Zeiss SMT’s Aerial Image Measurement System (AIMSTM) and Applied Materials AeraTM series mask inspection systems. AIA automatically dispositions the defect based on its simulated wafer contour, CD, and location. It improves the equipment’s utilization while offering 100X faster, more comprehensive and consistent analysis than operator’s manual measurements.

Toshiba develops CMOS image sensorToshiba Corporation announced the development of a CMOS image sensor with a small area and low power pixel readout circuits. A sample sensor embedded with the readout circuits shows double the performance of a conventional one. Toshiba presented this development at ISSCC 2013 in San Francisco, CA on Feb. 20.

As demand for commodity mobile phones takes off in emerging markets, CMOS image sensor need to be smaller, consume less power and offer low noise performance. The pixel readout circuits of CMOS image sensors are largely noise reducing correlated double sampling (CDS) circuits, along with a programmable gain amplifier (PGA) and an analog to digital converter (ADC). Serial signal processing architecture is best suited for securing conventional CMOS image sensors with a small area and low power pixel readout circuits, because a PGA and ADC can be shared by many CDS circuits placed in each column area of the sensor. However, smaller size and lower power are still challenges, since noise reduction circuits occupy a large area in the readout circuits, and PGA and ADC have high power consumption.

Key key technologies to overcome these challenges:

1) Column CDS circuits primarily made up of aria-efficient PMOS capacitors. The area of the CDS circuits is reduced to about half that of conventional circuits.

2) In the readout circuits, a level shift function is simultaneously achieved by a capacitive coupling through the PMOS capacitors, allowing adjustment of the signal dynamic range between the column CDS circuits and the PGA and the ADC. This achieves low power and low voltage implementation of the PGA and ADC, reducing their power consumption by 40%.

3) Implementation of a low power switching procedure in the ADC suited to processing the pixel signals of CMOS image sensors. This reduces the switching power consumption of the ADC by 80%.

Toshiba has integrated the three technologies in a sample sensor and confirmed that they double the overall performance of the sensor core. The company now plans to apply CMOS image sensors with the readout circuits to low cost mobile phones and medical cameras in fiscal year 2013.

GT Advanced Technologies and Soitec , today announced a development agreement and a licensing agreement allowing GT to develop, manufacture and commercialize a high-volume, multi-wafer HVPE system to produce high-quality GaN epi layers on substrates used in the LED and other growth industries such as power electronics. The higher growth rates and improved material properties made possible by the HVPE system are expected to significantly reduce process costs while boosting device performance compared with the traditional MOCVD process. Initial pre-payment of the licensing fees as outlined in the agreement is already underway, but further specific terms were not disclosed.

GT will develop, manufacture and commercialize the HVPE system incorporating Soitec Phoenix Labs’ unique and proprietary HVPE technology including its novel and advanced source delivery system that is expected to lower the costs of precursors delivered to the HVPE reactor. The HVPE system will enable the production of GaN template sapphire substrates at scale. The expected target date for the commercial availability of the HVPE system is the second half of 2014.

“We have been working for more than 6 years on GaN epi processes and have created this breakthrough HVPE technology critical in producing high-quality and low cost GaN layers on sapphire substrates,” said Chantal Arena, VP and general manager of Soitec Phoenix Labs. “The development and license agreements we are announcing today with GT is the ultimate validation of this work and builds on the agreement we announced last year with Silian to integrate a HVPE-based technology on their sapphire. This allows Soitec to structure its LED lighting offer around differentiated technologies and industrial partners that includes materials and equipment. Soitec Phoenix Labs deep know-how in epitaxy technologies and GaN materials will be a key factor to enable GT to bring a revolutionary HVPE system to the market.”

“GT has a successful track record of delivering innovative equipment that has changed industries such as solar PV and LED,” said Tom Gutierrez, GT’s president and CEO. “Our decision to enter into the agreements with Soitec is the result of our extensive search for the right partner with the right technology to complement our equipment business as we diversify into new, high-value technologies that broaden our reach and bring winning solutions to the market. Soitec Phoenix Labs brings a high level of expertise and technical experience in GaN process know-how. When commercially available, we believe the new HVPE system will be a key element to further reduce LED device costs and help propel the industry to greater levels of competitiveness and growth.”

Soitec is an international manufacturing company, generating and manufacturing semiconductor materials. Soitec’s products include substrates for microelectronics and concentrator photovoltaic systems (CPV). Soitec has manufacturing plants and R&D centers in France, Singapore, Germany, and the United States.

GT Advanced Technologies Inc. is a technology company with crystal growth equipment and solutions for the global solar, LED and electronics industries.

Silicon nanocrystals have a size of a few nanometers and possess a high luminous potential. Scientists of Karlsruhe Institute of Technology (KIT) and the University of Toronto/Canada have now succeeded in manufacturing silicon-based light-emitting diodes (SiLEDs). They are free of heavy metals and can emit light in various colors.

Liquid-processed SiLEDs: By changing the size of the silicon nanocrystals, color of the light emitted can be varied. (Photo: F. Maier-Flaig, KIT/LTI)

Silicon dominates in microelectronics and photovoltaics industry, but has been considered unsuitable for light-emitting diodes for a long time. However, this is not true for nanoscopic dimensions: Minute silicon nanocrystals can produce light. These nanocrystals consist of a few hundred to thousand atoms and have a considerable potential as highly efficient light emitters, as was demonstrated by the team of Professor Uli Lemmer and Professor Annie K. Powell from KIT as well as Professor Geoffrey A. Ozin from the University of Toronto. In a joint project, the scientists have now succeeded in manufacturing highly efficient light-emitting diodes from the silicon nanocrystals.

So far, manufacture of silicon light-emitting diodes has been limited to the red visible spectral range and the near infrared.

“Controlled manufacture of diodes emitting multicolor light, however, is an absolutely novelty,” explains Florian Maier-Flaig, scientist of the Light Technology Institute (LTI) of KIT and doctoral student of the Karlsruhe School of Optics and Photonics (KSOP). KIT scientists specifically adjust the color of the light emitted by the diodes by separating nanoparticles depending on their size.

 “Moreover, our light-emitting diodes have a surprising long-term stability that has not been reached before,” Maier-Flaig reports.

The increased service life of the components in operation is due to the use of nanoparticles of one size only. This enhances the stability of the sensitive thin-film components. Short circuits due to oversized particles are excluded.

The development made by the researchers from Karlsruhe and Toronto is also characterized by an impressing homogeneity of the luminous areas. The KIT researchers are among the few teams in the world that know how to manufacture such devices.

“With the liquid-processed silicon LEDs that may potentially be produced on large areas as well as at low costs, the nanoparticle community enters new territory, the associated potentials of which can hardly be estimated today. But presumably, textbooks about semiconductor components have to be rewritten,” says Geoffrey A. Ozin, who is presently working as a KIT distinguished research fellow at KIT’s Center for Functional Nanostructures (CFN).

The SiLEDs also have the advantage that they do not contain any heavy metals. In contrast to cadmium selenide, cadmium sulfide or lead sulfide used by other groups of researchers, the silicon used by this group for the light-emitting nanoparticles is not toxic. Moreover, it is available at low costs and highly abundant on earth. Due to their many advantages, the SiLEDs will be developed further in cooperation with other partners.

The Touch Panel Transparent Conductive Film, or TCF, market was reported $956 million in 2012. Markets are anticipated to reach $4.8 billion by 2019. Indium tin oxide (ITO) is an entrenched technology for displays manufacturing. ITO has been the transparent conductive film technology for touch screens, but ReportsNReports says newer technology will erode ITO and provide improved functionality at lower prices.

Transparent conductive film enables features of smart phones and electronics applications, devices which are evolving in response in part to the characteristics of the transparent conductive film that is used in the user interface.

The advantage of transparent conductive film is that a very thin layer of material as a coating on a surface can provide touch screen capability. Transparent conductive film supports electronic device usability, and factors that influence commercial success in the wireless device and services market relate to usability above all. Development of an integrated hardware, software and service platform to support multiple wireless network standards is an essential aspect of market participation.

ReportsNReports noted that the key players in the transparent conductive film markets are mainly leveraging the expanding market opportunities related to mobile communication and media devices of smart phones and tablets. Transparent conductive film provides the base for device navigation by recognizing the presence of a finger as it moves across a screen. That navigation supports transmission of digital data into and out of the smart phone. The transparent conductive film markets are highly competitive, and the competition is expected to intensify significantly as new technologies evolve.

The principal competitive factors of the transparent conductive film market include price, product features, relative price/performance, product quality and reliability, design innovation, marketing and distribution capability, service and support, and corporate reputation. Indium tin oxide (ITO) has been the prevailing transparent conductive film used in touch screen applications, and it requires an expensive and cumbersome sputtering deposition process. The price of indium is increasing rapidly and the film is rigid. As a result, there is demand for more flexible film in the market.

Photo by gletham GIS, Social, Mobile Tech via flickr

Toshiba Corporation today announced the development of an innovative low-power technology for embedded SRAM for application in smart phones and other mobile products. The new technology reduces active and standby power in temperatures ranging from room temperature (RT) to high temperature (HT) by using a bit line power calculator (BLPC) and a digitally controllable retention circuit (DCRC). A prototype has been confirmed to reduce active and standby power consumption at 25°C by 27% and 85%, respectively.

Toshiba presented this development at the 2013 International Solid-State Circuit Conference (ISSCC) in San Francisco, CA on February 20.

Longer battery life requires lower power consumption in both high performance and low performance modes (MP3 decoding, background processing, etc.). As low performance applications require only tens of MHz operation, SRAM temperature remains around RT, where active and leakage power consumptions are comparable. Given this, the key issue is to reduce active and standby power from HT to RT.

Toshiba’s new technology applies a BLPC and DCRC. The BLPC predicts power consumption of bit lines by using replicated bit lines to monitor the frequency of the ring oscillator. It minimizes the active power of the SRAM in certain conditions by monitoring the current consumption of the SRAM rest circuits. The DCRC greatly decreases standby power in the retention circuit by periodically activating itself to update the size of the buffer of the retention driver.

Toshiba will continue to develop technologies that contribute to high performance, low power system LSI for mobile products.

TESEC Corporation today announced the development and sales of the ULTRA MEMS handler, targeting Inertial (Accelerometer, Gyroscope and Magnetometer) MEMS devices. The ULTRA handler was designed jointly by TESEC and FocusTest, Inc. The ULTRA is a carrier based system with parallel test capabilities for 16, 32, 64 and 96 devices. The system will be available for demonstration and shipment mid-2013.

The overall MEMS market is the fastest growing portion of the semiconductor market, with 2012 revenues of $11.5B and an expected growth rate exceeding 10% for the next several years. According to TESEC’s Director of Sales, Keizo Yamaguchi, “the MEMS handling market is expanding rapidly and with the introduction of the ULTRA, TESEC intends to become a significant supplier to this segment.”

The ULTRA handler provides MEMS device suppliers with a significant throughput enhancement, as a significant portion of devices are being tested today on systems that provide only four to sixteen parallel processing. In addition to significantly higher parallel performance, the ULTRA offers a host of features aimed at higher performance and lower test time. With ±360 degree, 3 axis rotation the ULTRA is capable of providing stimulus for accelerometers and gyroscopes. A magnetic stimulus unit adds magnetometer test capability, making the ULTRA the industry’s first 9 degrees of freedom (DOF) capable system.

Future versions of the ULTRA are planned to expand coverage to address pressure sensor and high G MEMS devices.

“FocusTest brings 20 years of MEMS handling, stimulus and test experience to the ULTRA,” said Richard Chrusciel, ULTRA Product Development Manager, adding: “our partnership with TESEC brings over 40 years of experience and achievement in semiconductor handling, as well as a worldwide organization. The fusion of FocusTest and TESEC will bring world class automation to the MEMS handling market.”

The ULTRA handling and stimulus system is available in ambient and full tri-temperature configurations. Best of all, the unit is priced to avoid sticker shock, with base system configurations targeted to be of equal to or lower cost than current market products.

TESEC will provide world-wide sales/distribution, manufacturing and support for the ULTRA. FocusTest will provide MEMS and test cell specific engineering and applications.

Only light, aerial oxygen, and a catalyst are needed to remove pollutants from water. Ruhr-Universitat Bochum researchers led by Professor Radim Beránek are collaborating with colleagues from seven different countries in order to develop a photocatalyst that is efficient enough to be profitable. For that purpose, they combine sunlight-absorbing semiconductors and nanostructured materials which they optimize for electron transfer processes. The aim is to implement the newly developed photocatalysts into a liquid paint with which photoreactors can easily be coated. The EU supports the project within its 7th Framework Programme (FP7) with 3.7 million Euro funding for three years.

Current problems of photocatalysis

People from many countries of the world extensively use pesticides, which contaminate drinking and irrigation water with toxic organic compounds. In rural areas of Vietnam, herbicides and dioxins, resistant to degradation, made their way into the water cycle during the Vietnam War. The results can be devastating. People who drink this contaminated water are at a higher risk of developing cancer, and pregnant women may put their newborn at risk for birth defects, in worst case scenarios.

Photocatalysis is potentially one of the cheapest and most efficient methods for purifying water from pollutants,” Radim Beránek says.

Sunlight and oxygen establish oxidizing conditions, under which toxins are easily degraded into non-harmful substances like water and carbon dioxide. Up until now, the process, however, faces two problems: degradation rates are too low and assembly of the needed photoreactors is too expensive.

The aim: cheeper and more efficient catalysts

Within the project “4G-PHOTOCAT,” the researchers aim to develop cost-efficient photocatalysts with a considerably improved degradation rate. They fabricate innovative composite materials consisting of semiconductors and nanostructured metal oxides. In order to achieve the optimal architecture for the product, they employ advanced chemical deposition techniques with a high degree of control over composition and morphology.

“Our ultimate goal is to implement the newly developed photocatalysts into a liquid paint,” Radim Beránek says. “Photoreactors painted with that liquid can be used, for example, for water decontamination in remote rural areas of Vietnam.”

Collaborators

“4G-PHOTOCAT “allies the expertise of seven academic and three industrial partners from five European countries and two Southeast Asian countries. At the RUB, Beránek collaborates with Professor Dr. Roland A. Fischer (Inorganic Chemistry II), Professor Dr. Martin Muhler, and Dr. Jennifer Strunk (Industrial Chemistry). The international collaborators include scientists from the University College London, J. Heyrovský Institute of Physical Chemistry in Prague, Jagiellonian University Krakow, University of Helsinki, Universiti Teknologi Malaysia, and Hanoi University of Agriculture. Furthermore, industrial partners from Finland (Picosun), Czech Republic (Advanced Materials), and Vietnam (Q&A) have joined the team.

The ability to improve silicon transistors is reaching its fundamental limit, so researchers are searching for new ways to keep making electronic devices faster and more powerful. University of Nebraska-Lincoln physicists and colleagues have taken a major step toward breaking that silicon barrier.

University of Nebraska-Lincoln physicists (from left) Evgeny Tsymbal, John D. Burton and Alexei Gruverman in the UNL Materials Research Science and Education Center’s Thin Film Growth and Characterization Facility. (Photo by Craig Chandler/University Communications)

UNL physicist Evgeny Tsymbal and colleagues demonstrated that a nanostructure with unique properties may hold the key to creating much smaller, more powerful electronics. They reported their findings in Nature Materials, published online this week. This work builds on predictions by Tsymbal, Bessey Professor of Physics and Astronomy and director of UNL’s Materials Research Science and Engineering Center, and colleague John D. Burton, reported in Physical Review Letters in 2011.

They had theorized that a layer of ferroelectric oxide just a few atoms thick could be exploited as a memory element to store more digital information using less energy than silicon-based memories. Using quantum theories and super computers at the university’s Holland Computing Center, they predicted how a ferroelectric memory element would behave.

Then they asked experimentalist Qi Li at Pennsylvania State University, UNL physicist Alexei Gruverman and colleagues at Oak Ridge National Laboratory, Tenn., and at universities in China and Korea to put their theories to the test. Those results proved the researchers’ predictions correct.

The theory is based, in part, on a phenomenon called quantum tunneling, in which particles can pass through a barrier only at the quantum, or atomic, level. To develop a new generation of electronics, scientists are experimenting with tunnel junctions, in which an ultra-thin barrier is placed between two electrodes. When voltage is applied, electrons are able to tunnel through the barrier, creating a current with resistance.

Tsymbal and colleagues created a tunnel junction using nano-thin ferroelectric oxide, a material with both positive and negative polarization directions, which can be reversed by switching the voltage charge. They have shown that reversing the polarization changes the resistance through the tunnel junction by 100 times, a difference large enough to easily measure.

These ferroelectric properties are important because its two polarization directions could be read across regions like a binary code to store information. Tsymbal’s team has shown that the measurable difference in resistance could be used to detect polarization directions.

Current silicon-based devices require large currents, so the size of the space between regions must be big enough to accommodate the heat that’s generated. Because a ferroelectric device would use less energy, it would allow for more regions in a much smaller space, which would enable more compact and powerful devices.

Such a device won’t hit stores anytime soon, however. The effect only works up to minus 100 degrees Fahrenheit.

"For applications, you obviously want to have this change in resistance at room temperature," Tsymbal said. "This can’t be used immediately, but it shows some new directions to pursue."

Next, UNL’s team will investigate other geometric and material configurations to find alternatives with greater applicability. Gruverman and Tsymbal also are exploring something called memristor. Rather than abruptly reversing polarization between two directions, memristor would allow changing polarization, and therefore resistance, continuously.

"Changing in a continuous way offers many stages of resistance and that will allow us to see more interesting physics and applications," Tsymbal said.

Co-authors are: UNL’s Tysmbal, Burton and Gruverman; Li of Penn State; Y.W. Yin, Penn State and the Hefei National Laboratory for Physical Sciences at Microscale at the University of Science and Technology of China; X.G. Li, Hefei National Laboratory for Physical Sciences at Microscale at the University of Science and Technology of China; Y-M. Kim, Oak Ridge National Laboratory and Seoul National University, Korea; A.Y. Borisevich and S.J. Pennycook, Oak Ridge National Laboratory; and S.M. Yang and T.W. Noh, Seoul National University.

Grants from UNL’s National Science Foundation-funded Materials Research Science and Engineering Center and the NSF’s Nebraska Experimental Program to Stimulate Competitive Research help support this research.

 

The quantum dot recently emerged as a next-generation display material. Quantum dots, whose diameter is just a few nanometers, are semiconductor crystals. The smaller its particle is, the more short-wavelength light are emitted; the larger its particle is, the more long-wavelength lights get emitted. Considering that there are more advantages with the quantum dots over conventional light sources, it is not surprising that the quantum dot display gains a lot of attention.
 
The quantum dot display consumes lower power and has a richer color than the conventional OLED. In addition, the white light produced by quantum dots has high brightness and excellent color reproduction, raising its potential to replace the backlight unit (BLU) using the LED. Not surprisingly, leading companies in the display industry are accelerating to secure relevant technologies.

Analysis of Patent Application Trends
By country, 93 patents (or 34%) were filed in South Korea, 87 in the U.S., 36 in Japan, 22 in Europe, and 35 under the PCT. By technology, patents on quantum dot light emitting diodes (QLED) technology (188 patents, 69%) were applied the most, followed by those on BLU using the white light source; quantum dot display; and LED-using white light source technologies.  

Implications
As the quantum dot display has emerged as the next-generation display technology ever since the OLED, the leading companies in the display industry, including Samsung and LG, are making aggressive investment to take a lead in the technology. They not only develop their own technologies, but also purchase patents from; make technology licensing agreements with; or make equity investment in the companies of the field.

The competition to obtain key patents on the quantum dot display is expected to only increase. Monitoring published/issued patents on a regular basis and having a thorough analysis on them have become more important. 

Key Patent Report – Quantum Dot Display covers patent application trends and an in-depth analysis.