Researchers demonstrate ‘avalanche effect’ in solar cells

Proof that the ‘avalanche effect’ by electrons occurs in specific, very small semi conducting crystals could pave the way for cheap high-output solar cells.

Researchers at TU Delft and the FOM Foundation for Fundamental Research on Matter have discovered this phenomenon.

Solar cells provide opportunities for future large-scale electricity generation. However, there are currently significant limitations, such as the relatively low output of most solar cells (typically 15%) and high manufacturing costs.

One possible improvement could develop from a solar cell made of semiconducting nanocrystals which could lead to theoretical maximum output of 44%.

In conventional solar cells, one photon can release precisely one electron. The creation of these free electrons ensures that the solar cell works and can provide power.

The more electrons released, the higher the output of the solar cell.

In some semiconducting nanocrystals, however, one photon can release two or three electrons, hence the term 'avalanche effect'.

The avalanche effect was first measured by researchers at the Los Alamos National Laboratories in 2004. Since then, the scientific world has raised doubts about the value of these measurements. Does the avalanche effect really exist or not?

Within the Joint Solar Programme TU Delft’s Prof Laurens Siebbeles has now demonstrated that the avalanche effect does indeed occur in lead selenide (PbSe) nanocrystals.

It has been established, however, that the effect in this material is smaller than previously assumed. Siebbeles claims his results are more reliable than those of other scientists due to more careful and more detailed measurement using ultra-fast laser methods.

Siebbeles believes that this research paves the way for further unravelling the secrets of the avalanche effect.
Source: electroline.com

Intel Celebrates 40 Years of Innovation

* Intel celebrates its anniversary on July 18, 2008.
* Since its founding, Intel has introduced countless examples of technology innovation, its crowning breakthrough being the introduction of microprocessor. Commonly referred to as the "brain" of a computer, the microprocessor has led to unimagined advances in entertainment, education and business productivity.
* Intel is unveiling the World Mural Project on the day of the anniversary, a Web-based digital art piece that includes visual and written contents from the Intel Computer Clubhouses around the world.
* More than 500 young people in 21 countries participated in the project.
* Around 300 Intel volunteers at 70 Clubhouses around the world worked with the youth on the project.

Click here for the full story ›

AMD Micro Processors, History

Am2900 series (1975)

* Am2901 4-bit-slice ALU (1975)
* Am2902 Look-Ahead Carry Generator
* Am2903 4-bit-slice ALU, with hardware multiply
* Am2904 Status and Shift Control Unit
* Am2905 Bus Transceiver
* Am2906 Bus Transceiver with Parity
* Am2907 Bus Transceiver with Parity
* Am2908 Bus Transceiver with Parity
* Am2909 4-bit-slice address sequencer
* Am2910 12-bit address sequencer
* Am2911 4-bit-slice address sequencer
* Am2912 Bus Transceiver
* Am2913 Priority Interrupt Expander
* Am2914 Priority Interrupt Controller

29000 (29K) (1987–95)

* AMD 29000 (aka 29K) (1987)
* AMD 29027 FPU
* AMD 29030
* AMD 29050 with on-chip FPU (1990)
* AMD 292xx embedded processor

x86 architecture processors

2nd source (1979–91)

(second-sourced x86 processors produced under contract with Intel)

* 8086
* 8088
* Am286 (2nd-sourced 80286, so not a proper Amx86 member)

Amx86 series (1991–95)

* Am386 (1991)
* Am486 (1993)
* Am5x86 (a 486-class µP) (1995)

K5 series (1995)

* AMD K5 (SSA5/5k86)

K6 series (1997–2001)

* AMD K6 (NX686/Little Foot) (1997)
* AMD K6-2 (Chompers/CXT)
o AMD K6-2-P (Mobile K6-2)
* AMD K6-III (Sharptooth)
o AMD K6-III-P
* AMD K6-2+
* AMD K6-III+

K7 series (1999–2005)

* Athlon (Slot A) (Argon,Pluto/Orion,Thunderbird) (1999)
* Athlon (Socket A) (Thunderbird) (2000)
* Duron (Spitfire,Morgan,Applebred) (2000)
* Athlon MP (Palomino,Thoroughbred,Barton,Thorton) (2001)
* Mobile Athlon 4 (Corvette/Mobile Palomino) (2001)
* Athlon XP (Palomino,Thoroughbred (A/B),Barton,Thorton) (2001)
* Mobile Athlon XP (Mobile Palomino) (2002)
* Mobile Duron (Camaro/Mobile Morgan) (2002)
* Sempron (Thoroughbred,Thorton,Barton) (2004)
* Mobile Sempron

K8 series (2003–)

Families: Opteron, Athlon 64, Sempron, Turion 64, Athlon 64 X2, Turion 64 X2

* Opteron (SledgeHammer) (2003)
* Athlon 64 FX (SledgeHammer) (2003)
* Athlon 64 (ClawHammer/Newcastle) (2003)
* Mobile Athlon 64 (Newcastle) (2004)
* Athlon XP-M (Dublin) (2004) Note: AMD64 disabled
* Sempron (Paris) (2004) Note: AMD64 disabled
* Athlon 64 (Winchester) (2004)
* Turion 64 (Lancaster) (2005)
* Athlon 64 FX (San Diego) (1st half 2005)
* Athlon 64 (San Diego/Venice) (1st half 2005)
* Sempron (Palermo) (1st half 2005)
* Athlon 64 X2 (Manchester) (1st half 2005)
* Athlon 64 X2 (Toledo) (1st half 2005)
* Athlon 64 FX (Toledo) (2nd half 2005)
* Turion 64 X2 (Taylor) (1st half 2006)
* Athlon 64 X2 (Windsor) (1st half 2006)
* Athlon 64 FX (Windsor) (1st half 2006)
* Athlon 64 X2 (Brisbane) (2nd half 2006)
* Athlon 64 (Orleans) (2nd half 2006)
* Sempron (Manila) (1st half 2006)
* Opteron (Santa Rosa)
* Opteron (Santa Ana)
* Mobile Sempron

K9 series

At one time K9 was the internal codename for the dual-core AMD64 processors as the brand Athlon 64 X2,[1][2] however AMD has distanced itself from the old K series naming convention, and now seeks to talk about a portfolio of products, tailored to different markets.[3]

K10 series
This article contains information about scheduled or expected future computer chips.
It may contain preliminary or speculative information, and may not reflect the final specification of the product.

* Opteron (Barcelona) (10 September 2007)
* Phenom FX (Agena FX) (Q1 2008)
* Phenom 9-series (Agena) (Q4 2007)
* Phenom 8-series (Toliman) (H1 2008)
* Athlon 6-series (Kuma) (Q1 2008)
* Athlon 4-series (Kuma) (2008)
* Athlon X2 (Rana) (Q4 2007)
* Sempron (Spica)
* Opteron (Budapest)
* Opteron (Shanghai)
* Opteron (Cadiz)
* Opteron (Zamora)
* Opteron (Montreal)