Category Archives: LEDs

March 2, 2012 — The National Physical Laboratory in the UK is leading a new EMRP project on thin film manufacturing metrology for industries such as opto electronics, plastic and printed electronics, displays and lighting, memories and solar cells.

NPL is joined by National Measurement Institutes from across Europe, and other partners. It is a pan-European initiative.

The project aims to create validated and traceable metrology technologies for thin film materials properties, composition, and structure; and for controlling large-area homogeneity and consistency of properties.

The project will develop the necessary metrology to control consistency of thin film processing and improve production quality to reduce costs and time-to-market for new products.

Find out more about the EMRP Thin Films project at http://projects.npl.co.uk/optoelectronic_films/

In this 2-part series, Part 1 describes aluminum nitride (AlN) and what it accomplishes as a ceramic substrate for high-brightness light emitting diodes (HB-LEDs).

March 2, 2012 — In Part 2, the furnace considerations are discussed, as well as furnace throughput. It covers the role of the oxide sintering phase in AlN in defining the materials microstructure and thus determining key properties such as thermal conductivity and mechanical strength.

Furnace considerations

An AlN formulation that sinters below 1700°C enables new furnace options versus higher-temp materials. At 1700°C or below, a continuous tunnel kiln can be utilized. This furnace runs in a N2 atmosphere with a small amount of H2 present to protect the heating elements from oxidation. The heat shields are constructed of alumina and the heaters of molybdenum. The substrates are stacked on alumina plates, which are continuously pushed through the furnace at a rate of travel determined by the length of the hot zone and the required time at sintering temperature (about 3-5 hours). The longer the hot zone, the higher the sintering throughput. Since a continuous furnace runs in steady state, no heat up/cool down times are needed, key limitations in batch processing.

Table 4. A comparison of a typical batch furnace for sintering high-temperature AlN with the continuous furnace used to sinter low-temperature AlN.

Comparison Area

High Temperature Batch

Continuous Tunnel Kiln

Shielding

Tungsten or Mo

Alumina

Heating Elements

Tungsten

Molybdenum

Atmosphere

N2/H2

N2/H2

Peak Operating Temperature

1950C

1700C

Furnace Type

Refractory Metal Furnace for high temperature specialized processing of metals or ceramics

Conventional HTCC firing furnace

 

Furnace throughput comparison

The goal of this analysis is to compare the throughput of a batch furnace and continuous furnace with approximately the same capital equipment cost.

Key assumptions:

  • Both furnaces have a capital cost of approximately $500,000
  • Batch furnace hot zone dimensions: 8” x 8” x 20”
  • For batch firing, assume that 80% of the hot zone is usable for the high temperature firing process. This would be typical. The very top and bottom of the hot zone are too hot/cold to obtain the optimum microstructure/density.
  • Continuous furnace opening dimensions of 8” x 8”
  • Continuous furnace hot zone length of 36” with adjacent zones heated to achieve a uniform hot zone temperature
  • Fired substrates 4.5” x 4.5” x 20 mils
  • Kiln furniture the same for both furnaces
  • Stack of 5 substrates separated by coarse powder on top of a setter forms the basic stacking unit
  • Batch furnace has a loader arrangement so that stacking time is not included in the total  cycle time.

 

Figure 6. A commercial HTCC furnace (Model 4612-3Z Automated).

 

Using these assumptions, the throughput in fired substrates per hour is:

  • 225 substrates per hour for the continuous furnace
  • 22 substrates per hour for the batch furnace (432 substrates per batch, 20 hours per run)
  • Continuous furnace throughput for the same capital expense is 10x higher. The same type of relative throughput enhancement will be achieved for flat firing.

Conclusion

In Part 1, the 5 major cost factors for AlN substrates (compared to Al2O3) were discussed: (1) higher cost powder; (2) separate BBO cycle; (3) batch sintering cycle; (4) batch flat fire cycle and (5) non-aqueous processing. By adopting a low-temperature sintering configuration, cost factors 4 and 5 are addressed, bringing the sintering and flat-firing operations in line with the process for alumina.

This process will only be appropriate for applications where a thermal conductivity of 130W/m-K is acceptable, which includes most HBLED, RF, and power semiconductor devices. The same advantages of AlN as a substrate material in HB-LED applications are also key in discrete power semiconductor packaging and in packaging for highly concentrated photovoltaics (HCPV) applications.  For laser diode telecommunications applications, 130W/m-K will most likely be too low and conventional higher-cost AlN will continue to be utilized.

The availability of a low temperature, continuous sintering process also provides strong motivation for the next phase of cost reduction for AlN, utilization of lower-cost/lower-performance AlN powder. Again, with a focus on HB-LED and power semiconductor applications, sensitivity to impurities such as iron (Fe) and silicon (Si), which drive up AlN powder costs, may not be anywhere as stringent as applications such as RF and microwave (where dielectric properties at high frequencies are important). The combination of lower cost powder and a continuous sintering process would move AlN substrate pricing much more in line with alumina.

The major limiting factor for widespread utilization of AlN ceramics in these applications — the cost barrier compared to alumina — is addressed by this new sintering technology. It takes into account the role of the oxide sintering phase in AlN in defining the materials microstructure, and thus determining key properties such as thermal conductivity and mechanical strength. With the exception of a lower thermal conductivity, the properties of traditional high-cost materials and the HB-LED-grade AlN are very similar.

Read the series from the start with Part 1 on HB-LED-grade AlN vs other materials here.

Jonathan Harris, PhD is president of CMC Laboratories Inc., www.cmclaboratories.com.

References:

[1] J.H. Harris, R.A. Youngman and R.G. Teller, J. Mater. Res. 5, 1763 (1990)

[2] J. McCauley, and N. Corbin, High Temperature Reactions and Microstructures in the Al2O3-AlN System, Progress in Nitrogen Ceramics, ed. F.L. Rley, Martinus Nijhoff Pub., The Netherlands, 111- 118 © 1983.

March 1, 2012 — Dynamic changes in the flat panel display (FPD) industry range from new liquid crystal display (LCD), active-matrix organic light emitting diode (AMOLED), touch, and flexible technologies to the emergence of China as the leading consumer and manufacturer of display products. FPD China, a display technology exposition taking place March 20-22 in Shanghai alongside SEMICON China and SOLARCON China, covers the entire industry supply chain with 3 main areas: Equipment, materials and components; Panel and modules; and End products.

FPD China attracts the global top 10 display suppliers, emerging Chinese suppliers, leading global panel makers, and leading consumer brands of China.

Special pavilions will highlight touch and next-generation display technologies, including the latest in 3D and advanced man-machine interfaces. A new Cross-strait AMOLED Industry Forum will feature leading FPD panel makers and suppliers from Taiwan and China.

With a strong partnership between SEMI and SID, FPD China 2012 also features the 2012 China FPD Conference (March 21-22), which provides an international platform for leading FPD industry technologists, analysts, and executives. Highlighted speakers will share their latest knowledge with keynote presentations on March 21:

  • “Technology and Application Outlooks for Small-Middle Size Display” by Jia-Heng Wang, co-chief operating officer and executive vice president of BOE Group
  • “Evolving Glass Solutions Address Challenges in Advanced Display Trends” by Fang Li, president of Corning Display Technologies China
  • “Greener TFT-LCD and Display Panels” by Han-pin Hsieh, professor of Shanghai Jiao Tong University and Chiao Tung University (Hsinchu, Taiwan) 
  • “Orientation of China Mobile Display Market” by Qing-Quan Liu, Marketing director of Tianma Micro-electronic

In addition, the FPD Conference includes technical sessions on Next Display Technology; Touch Screen; Naked-Eye 3D; 2 sessions on TFT-LCD; and OLED.

For more information, visit www.fpdchina.org.

SEMI is a global industry association serving the nano- and microelectronic manufacturing supply chains.

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March 1, 2012 — OSRAM Opto Semiconductors released the Oslon SSL LED, using optimized LED chips and packaging technologies to boost light output, with a 25% efficiency increase over previous-generation LEDs. OSRAM stabilized the LED’s luminous flux at elevated temperatures, which simplifies luminaire design by improving thermal management. The LED chip is 1mm2, in a 3mm2 package form factor.

The temperature-stable light source generates a luminous flux of typically 98lm (luminous efficacy of 96lm/W) in warm white (3,000 K), with an operating current of 350mA at 85°C in the chip. This, coupled with reduced forward voltage (3.1V), achieves the 25% efficiency gain, and reduces the thermal management requirement for the chip. A smaller number of Oslon SSL LEDs provides the same luminous flux in a luminaire.

Thanks to the reflectivity of the package, the light that is irradiated to the side or to the back is reflected and can be used again.

The LEDs are available in warm and cool white, and two different lenses.

OSRAM AG (Munich, Germany) is a wholly-owned subsidiary of Siemens AG and a leading light manufacturer. Its subsidiary, OSRAM Opto Semiconductors GmbH, offers semiconductor-technology-based products for lighting, sensor and visualization applications. For more information, go to www.osram-os.com.

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February 29, 2012 — Gamma Scientific developed the Bi-Spectral Fluorescence Spectroradiometer to quickly obtain detailed fluorescence data for light-emitting diode (LED) phosphors and other fluorescent or reflective materials.

The tester measures the transmitted and reflected spectrum of materials when illuminated by monochromatic light, via a pair of Gamma Scientific RadOMA spectroradiometers. It obtains spectral reflectance, spectral transmittance and absorption data simultaneously while utilizing dual, calibrated integrating spheres to measure total flux.

The tool incorporates 2 Gamma Scientific RadOMA Spectroradiometers, 2 Gamma Scientific Integrating Spheres mounted on a rail system, a Gamma Scientific FlexOptometer power meter, Xenon light source and Monochromator, optical mixing rod and lens tube, and a sample holder placed between the two integrating spheres. A single sphere configuration is also available.

Also read: Gamma Scientific uncrates low-cost LED tester

The Bi-Spectral Spectroradiometer’s fluorescence data can be used to tailor LED phosphor compositions for maximium performance and lower manufacturing costs. It calculates which phosphor samples have the highest transmission, reflection and absorption, and determines the exact wavelengths that fluoresce most intensely, as well as the spectrum of fluorescing light at any excitation wavelength.

Absorption, reflection and transmission data are graphed in 3D for visualization of where the samples fluoresce, with user ability view, analyze and compare samples. Data can be exported to Excel and other data analysis programs.

Gamma Scientific makes tools for precision light measurements. LED testing products include spectroradiometers, integrating spheres, turn-key LED test systems, high-speed LED sorters, photometers and radiometers. Gamma Scientific also operates a NVLAP accredited laboratory for LM-79 testing. Learn more at www.gamma-sci.com.

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February 29, 2012 — Epistar, a leading manufacturer of optoelectronic materials and devices, installed its first AIXTRON SE CRIUS II-XL system in a 19 x 4" wafer configuration to mass produce ultra-high-brightness (UHB) blue and white light emitting diodes (LEDs).

The CRIUS II-XL close coupled showerhead (CCS) multi-wafer metal-organic chemical vapor deposition (MOCVD) reactor system successfully passed the process demonstration and acceptance test at Epistar, and will now be qualified in mass production. Epistar plan to purchase more CRIUS II-XL systems when they expand their production capacity. Dr. Bernd Schulte, COO of AIXTRON, expects the tools to increase yield and directly translate into enhanced competitiveness for Epistar’s products.

The CCS technology is used in AIXTRON’s current range of reactors. Reagents are introduced into the reactor through a water-cooled showerhead surface over the entire area of deposition. The showerhead is close to the substrates and is designed to enable precursors to be separated right up to the point where they are injected onto the substrates through a multiplicity of small tubes. The reagents are injected into the reactor chamber through separate orifices in a water-cooled showerhead injector, to create a very uniform distribution of reagent gases. Substrates are placed on top of a rotating susceptor, which is resistively heated. The three-zone heater enables adjustment of the temperature profile to provide temperature uniformity over the susceptor diameter.

Located at the Hsinchu Science-based Industrial Park in Taiwan, Epistar Corporation develops, manufactures, and markets UHB LEDs. Also read: SemiLEDs, LG Siltron, Epistar install Veeco MOCVD tools

For further information on AIXTRON (FSE: AIXA, ISIN DE000A0WMPJ6; NASDAQ: AIXG, ISIN US0096061041), visit www.aixtron.com.

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China’s LED subsidy update


February 28, 2012

February 28, 2012 — The formal announcement of China’s light emitting diode (LED) subsidy program, likely in the first half of March, may drive tool utilization expansions for LED chip makers, reports Barclays Capital.

Based on Barclays’ latest checks with Chinese government officials, they expect the LED subsidy program will be focused on downstream luminaires, with the central government providing subsidies for LED luminaires and lighting products that have been centrally qualified and listed in the government-driven LED product catalog. Additionally, certain municipal governments may match the subsidies of the central government, lowering the product cost further.

Preference will be given to domestic LED component and luminaire manufacturers, though foreign suppliers will benefit from the program as well. As for the likely impact to LED lighting adoption in China, the likely demand ramp will first be seen in the commercial and industrial segments, before spreading to the consumer segment down the line.

Also read: Strategies in Light takeaways: LED expectations for the short- and long-term

What does this mean for metal-organic chemical vapor deposition (MOCVD) tool expenditures? The anticipated growth in LED demand this year will be insufficient to drive the need for new capacity, given very depressed industry utilization levels. China’s LED maker consolidation is likely to take at least 1-2 years, posing a continued headwind to MOCVD demand. MOCVD replacement tools therefore are not going to meaningfully contribute to demand in 2012, prompting Barclays to lower its tool-buying forecast from 400 to 315. The analysts also lowered 2013 estimates from 440 to 350 tools.

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February 27, 2012 – PRNewswire-Asia-FirstCall — Cleantech Solutions International Inc. (NASDAQ:CLNT), metal components manufacturer, has delivered two units of sample sapphire chambers and one unit of a solar furnace to an international customer. Additional chamber and furnace orders are expected once the customer completes testing and approval of the initial units.

The customer ordered the sample furnace for manufacturing polysilicon solar wafers. The sapphire chambers will be used to manufacture light-emitting diodes (LEDs). The systems were ordered in August 2011. Cleantech Solutions stays in close contact after tool delivery to consult on technical needs.

Cleantech Solutions supplies forgings products, fabricated products and machining services to a range of clean technology customers, primarily in the wind power sector. For more information, visit http://www.cleantechsolutionsinternational.com.

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February 27, 2012 – PRNewswire — UL (Underwriters Laboratories) has been named a Zhaga-authorized testing center, enhancing UL’s light emitting diode (LED) testing portfolio. UL also performs LED testing in LTL, Europe, and Nansha.

Zhaga standards cover the physical dimensions, as well as the photometric, electrical and thermal behavior of LED light engines. This new testing service offering will be available singly, or as a bundle with UL lighting industry services such as Energy Star, performance testing, and safety certification.

Also read: LED test standards, packaging material challenges

UL is a "key player" in the standardization and test compliance movements for LEDs and lighting, said Alberto Uggetti, VP and GM, UL Lighting.

Zhaga is an industry-wide cooperation aimed at the development of standard specifications for the interfaces of LED light engines. The organization creates interface specifications for light engines with the goal to promote interchangeability among those made by different manufacturers. Interchangeability is achieved by defining interfaces for a variety of application-specific light engines.

UL is a premier global independent safety science company. Additional information about UL may be found at www.UL.com.

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February 24, 2012 — A team of scientists at Los Alamos National Laboratory has developed a process for creating glass-based, inorganic light-emitting diodes (LEDs) that produce light in the ultraviolet (UV) range, which could lead to biomedical devices with active components made from nanostructured systems.

LEDs based on solution-processed inorganic nanocrystals are inexpensively produced, reliable, and chemically stable even in harsh environments. Los Alamos National Laboratory’s Sergio Brovelli, in collaboration with international researchers led by Alberto Paleari at the University of Milano-Bicocca in Italy, created a fabrication process that gets the LEDs to emit UV light.

The glass-based material emits light in the ultraviolet spectrum and can be integrated onto silicon chips. The new devices are inorganic; the glass is chemically inert and mechanically stable, with electric conductivity and electroluminescence. A new synthesis strategy allows fabrication of all inorganic LEDs via a wet-chemistry approach, which is scalable to industrial quantities with a very low start-up cost.

Figure. Embedding nanocrystals in glass creates UV-producing LEDs for biomedical applications. SOURCE: Los Alamos National Laboratory.

The oxide-in-oxide design allows production of a material that behaves as an ensemble of semiconductor junctions distributed in the glass, rather than the sharp interface of two semiconductors found in traditional LEDs. The active part of the device consists of tin dioxide nanocrystals covered with a shell of tin monoxide embedded in standard glass: by tuning the shell thickness is it possible to control the electrical response of the whole material.

LEDs can be integrated in active lab-on-chip diagnostic platforms, or as light sources implanted into the body to trigger photochemical reactions. Such devices could selectively activate light-sensitive drugs for better medical treatment or probe for the presence of fluorescent markers in medical diagnostics.

Related stories: The ultimate limit of Moore’s Law: The one-atom transistor and IBM discovers magnetic storage limit at 12 atoms

The work is reported this week in the online Nature Communications: "Fully inorganic oxide-in-oxide ultraviolet nanocrystal light emitting devices," http://dx.doi.org/10.1038/ncomms1683. Its authors are Sergio Brovelli1, 2, Norberto Chiodini1, Roberto Lorenzi1, Alessandro Lauria1, Marco Romagnoli3,4 and Alberto Paleari1
1 Department of Materials Science, University of Milano-Bicocca, Italy.
2 Chemistry Division, Los Alamos National Laboratory, Los Alamos, New Mexico.
3 Material Processing Center, Massachusetts Institute of Technology, Cambridge, Massachusetts.
4 On leave from Photonic Corp, Culver City, California.

The paper was produced with the financial support of Cariplo Foundation, Italy, under Project 20060656, the Russian Federation under grant 11.G34.31.0027, the Silvio Tronchetti Provera Foundation, and Los Alamos National Laboratory’s Directed Research and Development Program.

Los Alamos National Laboratory, a multidisciplinary research institution engaged in strategic science on behalf of national security, is operated by Los Alamos National Security, LLC, a team composed of Bechtel National, the University of California, The Babcock & Wilcox Company, and URS for the Department of Energy’s National Nuclear Security Administration. Learn more at www.lanl.gov.

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