Active solid-state devices (e.g. – transistors – solid-state diode – Bipolar transistor structure
Patent
1991-09-23
1993-01-05
LaRoche, Eugene R.
Active solid-state devices (e.g., transistors, solid-state diode
Bipolar transistor structure
257575, 257613, H01L 2972
Patent
active
051775859
DESCRIPTION:
BRIEF SUMMARY
The present invention relates to a P-N-P diamond transistor and a method of manufacture thereof.
It is known that although most synthetic diamonds contain impurities such as nitrogen, such impurities do not result in semiconduction at normal temperatures and pressures. Formation of semiconducting diamond materials has been achieved by doping with boron at extremely high pressures. There has not, however, been any known proposal to form a P-N-P diamond transistor of simple construction and relatively straightforward manufacture. The present invention seeks to provide a transistor and a method of manufacture thereof which can meet these requirements.
According to a first aspect of the present invention there is provided a method of manufacturing a transistor comprising the steps of: providing a diamond substrate, doping two separate regions of the substrate with a p-type impurity to produce respective semiconducting regions, and using chemical vapour deposition to provide an n-type layer of semiconducting diamond, whereby a P-N-P transistor structure is obtained.
According to a second aspect of the present invention there is provided a transitor comprising; a diamond substrate having two p-type semiconducting regions, and an n-type semiconducting layer established by chemical vapour deposition, whereby a P-N-P structure is formed.
Beneficially the p-type regions contain boron.
Advantageously the n-type layer contains phosphorus.
Preferably, nitrogen getters are introduced in the reaction mass to control the nitrogen donor content of the substrate which in turn affects the number of uncompensated boron acceptors.
An embodiment of the present invention will now be described by way of example only and with reference to the accompanying drawing which is a diagrammatic illustration of a section through a transistor manufactured in accordance with the present invention.
As illustrated in the drawing, the transistor 10 comprises a diamond substrate 12 having two p-type semiconducting regions 14 separated by an insulating region 16. An n-type semiconducting layer 18 is established by chemical vapour deposition so as to contact the p-type regions 14 and form a P-N-P structure. Respective electrical contacts 20 are bonded to the p-type regions 14 and the n-type layer 18. Thus, a P-N-P diamond transistor is achieved.
Most synthetic diamonds contain nitrogen as impurities in the form of isolated nitrogen atoms substituting for carbon in the diamond lattice. Each nitrogen atom has one more electron than is necessary to satisfy the covalent bonding requirements of the diamond lattice so that there is a donor energy level in the band gap between the valence band and the conducting band. The position of the donor level is too deep in energy below the conduction band to give rise to n-type electrical semiconduction at realistic temperatures so the diamond remains an electrical insulator.
In general, synthetic diamonds (both self-nucleated diamond grit and larger, seed-grown diamonds grown by the temperature-gradient technique) have a cubo-octahedral morphology, often modified by minor {110} and .thrfore.113} facets. The concentration of isolated substitutional nitrogen is different in the different types of growth sector, being highest for {111} (i.e octahedral) sectors, lower for {100} (i.e. cube) sectors, lower still for {113} (i.e. trapezoidal) sectors and lowest for {110} (i.e. dodecahedral) sectors. It has been found that the total amount of nitrogen in a synthtic diamond can be controlled by the incorporation of nitrogen getters into the synthesis capsule.
Provided that the total nitrogen concentration is sufficiently low, doping the synthesis capsule with a small amount of boron will produce p-type semiconducting diamond. Boron is taken up preferentially by {111} sectors, then by {110} sectors and by a smaller amount by {100} and {113} sectors. However, the boron acceptor defects are usually compensated by nitrogen donor defects. P-type semiconduction results only from uncompensated boron defects, i.e. when the boron
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Gersan Establishment
LaRoche Eugene R.
Ratliff R.
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