Semiconductor Devices Stocks List

Recent Signals

Date Stock Signal Type
2020-01-24 ASMIY New 52 Week High Strength
2020-01-24 ASMIY Narrow Range Bar Range Contraction
2020-01-24 ASMIY New 52 Week Closing High Bullish
2020-01-24 ATEYY Bollinger Band Squeeze Range Contraction
2020-01-24 ATEYY Slingshot Bullish Bullish Swing Setup
2020-01-24 FFRMF 20 DMA Support Bullish
2020-01-24 FFRMF Narrow Range Bar Range Contraction
2020-01-24 FFRMF Non-ADX 1,2,3,4 Bearish Bearish Swing Setup
2020-01-24 KYOCY Three Weeks Tight Range Contraction
2020-01-24 MPAD Pocket Pivot Bullish Swing Setup
2020-01-24 MPAD Narrow Range Bar Range Contraction
2020-01-24 NTCXF Upper Bollinger Band Walk Strength
2020-01-24 NTCXF New Uptrend Bullish
2020-01-24 POETF Fell Below 200 DMA Bearish
2020-01-24 POETF Narrow Range Bar Range Contraction
2020-01-24 POETF Bollinger Band Squeeze Range Contraction
2020-01-24 POETF Fell Below 50 DMA Bearish
2020-01-24 ROHCY Narrow Range Bar Range Contraction
2020-01-24 SPRS 50 DMA Resistance Bearish
2020-01-24 SPRS Fell Below 200 DMA Bearish
2020-01-24 SPRS 20 DMA Resistance Bearish
2020-01-24 SPRS Non-ADX 1,2,3,4 Bearish Bearish Swing Setup
2020-01-24 SPRS Expansion Pivot Sell Setup Bearish Swing Setup
2020-01-24 SPRS Wide Range Bar Range Expansion

Semiconductor devices are electronic components that exploit the electronic properties of semiconductor material, principally silicon, germanium, and gallium arsenide, as well as organic semiconductors. Semiconductor devices have replaced thermionic devices (vacuum tubes) in most applications. They use electronic conduction in the solid state as opposed to the gaseous state or thermionic emission in a high vacuum.
Semiconductor devices are manufactured both as single discrete devices and as integrated circuits (ICs), which consist of a number ā€“ from a few (as low as two) to billions ā€“ of devices manufactured and interconnected on a single semiconductor substrate, or wafer.
Semiconductor materials are useful because their behavior can be easily manipulated by the addition of impurities, known as doping. Semiconductor conductivity can be controlled by the introduction of an electric or magnetic field, by exposure to light or heat, or by the mechanical deformation of a doped monocrystalline grid; thus, semiconductors can make excellent sensors. Current conduction in a semiconductor occurs via mobile or "free" electrons and holes, collectively known as charge carriers. Doping a semiconductor such as silicon with a small proportion of an atomic impurity, such as phosphorus or boron, greatly increases the number of free electrons or holes within the semiconductor. When a doped semiconductor contains excess holes it is called "p-type", and when it contains excess free electrons it is known as "n-type", where p (positive for holes) or n (negative for electrons) is the sign of the charge of the majority mobile charge carriers. The semiconductor material used in devices is doped under highly controlled conditions in a fabrication facility, or fab, to control precisely the location and concentration of p- and n-type dopants. The junctions which form where n-type and p-type semiconductors join together are called pā€“n junctions.
Semiconductor devices made per year have been growing by 9.1% on average since 1978, and shipments in 2018 are predicted for the first time to exceed 1 trillion, meaning that well over 7 trillion has been made to date, in just in the decade prior.

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