Techniques and mechanisms for cooling a substrate in a processing chamber by a bi-directional cooling process prior to transferring the substrate outside the processing chamber are provided. First cooling gas is introduced into the processing chamber from an upper gas source in a downward direction towards the upward facing surface of the substrate. An apparatus is placed underneath and in proximity to the substrate. Second cooling gas is introduced from the apparatus into the processing chamber in an upward direction towards the downward facing surface of the substrate. One or more gaps are cut out of the body portion of the apparatus, the gaps configured to allow the apparatus to avoid contact with the support structure holding the substrate, as the apparatus is moved in a horizontal direction into position underneath the substrate during placement of the body portion of the apparatus in proximity to the substrate.

There is provided a technique that includes a reaction container in which an object to be processed, containing a semiconductor, is arranged; a heater configured to emit heat; and a radiation control body arranged between the reaction container and the heater, wherein the radiation control body is configured to radiate a radiant wave of a wavelength transmittable through the reaction container by selecting a wavelength of a radiation heat from the heater such that the radiant wave reaches the object to be processed in the reaction container.

Methods of depositing a metal film by exposing a substrate surface to a halide precursor and an organosilane reactant are described. The halide precursor comprises a compound of general formula (I): MQ.sub.zR.sub.m, wherein M is a metal, Q is a halogen selected from Cl, Br, F or I, z is from 1 to 6, R is selected from alkyl, CO, and cyclopentadienyl, and m is from 0 to 6. The aluminum reactant comprises a compound of general formula (II) or general formula (III):

##STR00001##

wherein R.sup.1, R.sup.2, R.sup.3, R.sup.4, R.sup.5, R.sup.6, R.sup.7, R.sup.8, R.sup.a, R.sup.b, R.sup.c, R.sup.d, R.sup.e, and R.sup.f are independently selected from hydrogen (H), substituted alkyl or unsubstituted alkyl; and X, Y, X′, and Y′ are independently selected from nitrogen (N) and carbon (C).

According to one aspect of the technique of the present disclosure, there is provided a substrate processing apparatus including: a heater heating a substrate in a reaction tube; a temperature controller controlling the heater; a valve controller adjusting an opening degree of a control valve to adjust a gas flow rate; and a main controller instructing a recipe including: (a) elevating an inner temperature of the reaction tube to a predetermined temperature at an elevating rate; (b) processing the substrate at the predetermined temperature; and (c) lowering the inner temperature of the reaction tube at a lowering rate. The main controller controls the temperature controller and the valve controller so that the inner temperature of the reaction tube changes in (a) or (c) at the elevating or lowering rate by heating in parallel with cooling by the gas supplied through the control valve.

Embodiments described herein relate to a substrate support assembly which enables adjustment of the thermal conductivity therein. The substrate support assembly has heater and cooling channel. An adjustable thermal break disposed between the heater and the cooling channel. The adjustable thermal break has one or more fluid conduits coupled thereto and configured to flow a fluid into and out of the adjustable thermal break for variant the thermal conductivity between the heater and the cooling channel.

In a capacitively coupled etch reactor, in which the smaller electrode is etched, the larger electrode is electrically supplied by a very high frequency supply signal and by a high frequency supply signal. The smaller electrode, acting as a substrate carrier, is connected to ground potential.

There is provided a substrate processing method for a substrate processing apparatus. The substrate processing apparatus comprises: a processing chamber; a placing stand provided inside the processing chamber, configured to place a substrate on a placing surface, and having a gas path; a freezing device having a contact surface to be in contact with or separated from a surface to be contacted of the placing stand and configured to cool the placing stand; a gas supply pipe connected to the gas path and configured to introduce a heat transfer gas; and a cooling part provided outside the processing chamber and connected to the gas supply pipe. The substrate processing method comprises: (a) cooling the heat transfer gas by the cooling part; and (b) supplying the cooled heat transfer gas between the placing surface and a back surface of the substrate from the gas path through the gas supply pipe.

Techniques and mechanisms for cooling a substrate in a processing chamber by a bi-directional cooling process prior to transferring the substrate outside the processing chamber are provided. First cooling gas is introduced into the processing chamber from an upper gas source in a downward direction towards the upward facing surface of the substrate. An apparatus is placed underneath and in proximity to the substrate. Second cooling gas is introduced from the apparatus into the processing chamber in an upward direction towards the downward facing surface of the substrate. One or more gaps are cut out of the body portion of the apparatus, the gaps configured to allow the apparatus to avoid contact with the support structure holding the substrate, as the apparatus is moved in a horizontal direction into position underneath the substrate during placement of the body portion of the apparatus in proximity to the substrate.

A substrate processing apparatus includes a conductive enclosure having a gas passage, a conductive member having a gas passage, and a piping assembly including a hollow tube having an inner sidewall, a core block disposed in the hollow tube, the core block having an outer sidewall fitting the inner sidewall of the hollow tube, the core block having a first dielectric constant, and at least one dielectric member disposed in at least one of the hollow tube and the core block, the dielectric member having a second dielectric constant higher than the first dielectric constant.

Embodiments of the present disclosure relate to apparatus, systems and methods for managing organic compounds in thermal processing chambers. A gas line can be in fluid communication with the thermal processing chamber and an exhaust pump can be coupled to the thermal processing chamber by an exhaust conduit and controlled by an effluent flow control valve. The apparatus includes a sampling line with an organic compound sensor coupled to the exhaust conduit. The organic compound sensor can be in communication with a control module which can control operating parameters for processing a substrate.