A method for cleaning a substrate is provided. The method includes following operations. A substrate is received. The substrate has a plurality of conductive nanoparticles disposed over a surface of the substrate. A first mixture is applied to remove the conductive nanoparticles. The first mixture includes an SC1 solution, DI water and O.sub.3. A second mixture is applied to the photomask substrate. The second mixture includes DI wafer and H.sub.2. A temperature of the second mixture is between approximately 20° C. and 40° C. The applying of the second mixture further includes a mega sonic agitation, and a frequency of the mega sonic agitation is greater than 3 MHz. A flow rate of the first mixture is between approximately 1000 ml/min and approximately 5000 ml/min. A flow rate of the second mixture is between 1000 ml/min and approximately 3000 ml/min.

An embodiment method includes forming a patterned etch mask over a target layer and patterning the target layer using the patterned etch mask as a mask to form a patterned target layer. The method further includes performing a first cleaning process on the patterned etch mask and the patterned target layer, the first cleaning process including a first solution. The method additionally includes performing a second cleaning process to remove the patterned etch mask and form an exposed patterned target layer, the second cleaning process including a second solution. The method also includes performing a third cleaning process on the exposed patterned target layer, and performing a fourth cleaning process on the exposed patterned target layer, the fourth cleaning process comprising the first solution.

An electronic component cleaning method including: a preparation step of preparing an electronic component having a first surface covered with a protective film, a second surface opposite to the first surface, a sidewall between the first and second surfaces, and an adhering matter adhering to the sidewall; and a sidewall cleaning step of cleaning the sidewall. The sidewall cleaning step includes a deposition step of depositing a first film on the protective film and a surface of the adhering matter, using a first plasma, and a removal step of removing the first film deposited on the surface of the adhering matter, together with at least part of the adhering matter, using a second plasma. In the sidewall cleaning step, the deposition step and the removal step are alternately repeated a plurality of times, so as to allow the protective film to continue to exist.

There is provided a technique that includes a reaction container configured to process a substrate; a cleaning gas supply system configured to supply a cleaning gas into the reaction container; a lid configured to be capable of closing an opening of the reaction container and made of a metallic material; a protector installed over a surface of the lid at a side facing an inside of the reaction container and including a surface composed of a first non-metallic material; an internal space formed between surfaces of the lid and the protector facing each other; and an inert gas supply system configured to supply an inert gas to the internal space in a state in which the opening is closed by the lid.

A treatment liquid is a treatment liquid including water; a cationic compound; an anionic compound selected from the group consisting of a resin having a carboxy group or a salt thereof, a resin having a sulfo group or a salt thereof, a resin having a phosphorous acid group or a salt thereof, and a resin having a phosphoric acid group or a salt thereof; and an oxidizing agent, in which the treatment liquid has a pH of 7.0 or less, and the treatment liquid is substantially free of abrasive grains.

A method of manufacturing a semiconductor package, includes forming a mask layer on a wafer, the wafer including a semiconductor substrate and an insulating layer; forming a groove in the semiconductor substrate by performing a first laser grooving process; expanding an opening of the mask layer opened by the first laser grooving process by performing a second laser grooving process; exposing a portion of the insulating layer by removing a portion of the mask layer; and cutting the semiconductor substrate while removing the portion of the insulating layer exposed during the exposing by performing a dicing process.

A method for depositing, patterning and removing a layer of aluminum oxide as a masking material layer for performing a deep, high-aspect ratio etches into a substrate. The method comprising deposing a photoresist onto the substrate, performing lithography processing on the photoresist, developing the photoresist to pattern the photoresist into a mask design, depositing a thin-film layer of aluminum oxide; immersing the substrate into a solution to lift-off the aluminum oxide in regions where the aluminum oxide is deposited on top of the photoresist thereby leaving the patterned aluminum oxide layer on the substrate where no photoresist was present, performing deep reactive ion etching on the substrate wherein the hard masking material layer composed of aluminum oxide functions as a protective masking layer on the substrate to prevent etching from occurring where the aluminum oxide is present, and removing the aluminum oxide masking layer by immersion in a solution.

A photoresist-removing composition includes a polar organic solvent, an alkyl ammonium hydroxide, an aliphatic amine not including a hydroxy group, and a monovalent alcohol. To manufacture a semiconductor device, a photoresist pattern may be formed on a substrate, and the photoresist-removing composition may then be applied to the photoresist pattern. To manufacture a semiconductor package, a photoresist pattern including a plurality of via holes may be formed on a substrate. A plurality of conductive posts including a metal may be formed inside the plurality of via holes, and the photoresist pattern may be removed by applying a photoresist-removing composition of the inventive concept to the photoresist pattern. A semiconductor chip may be adhered to the substrate between the respective conductive posts.

A method of forming a pattern includes forming an etching object layer on a substrate. A photoresist layer including a metal, oxygen and an organic material is formed on the etching object layer. An exposure process is performed on the photoresist layer. A developing process is performed on the photoresist layer to form a photoresist pattern including a metal oxide. Ozone is provided onto the substrate to remove a residue of the photoresist layer that includes the organic material, The etching object layer is etched using the photoresist pattern as an etching mask.

According to one embodiment, a substrate processing apparatus includes a batch type cleaning unit, a holding unit, and a single-substrate type drying unit. The batch type cleaning unit simultaneously cleans a plurality of substrates in a batch process with a first liquid. The holding unit receives the cleaned substrates while still wet and then keeps a first surface of each of the substrates wet with the first liquid. The single-substrate type drying unit is configured to receive the substrates one by one from the holding unit and then dry off the substrates one by one.