Harvesting and Transferring Vertical Pillar Arrays of Single-Crystal Semiconductor Devices to Arbitrary Substrates

Abstract: Abstract-Development of devices that can be fabricated on amorphous substrates using multiple single-crystal semiconductors with different physical, electrical, and optical characteristics is important for highly efficient portable and flexible electronics, optoelectronics, and energy conversion devices. Reducing the use of single-crystal substrates can contribute to low-cost and environmentally benign devices covering a large area. We demonstrate a technique to harvest and transfer vertically aligned single-c… Show more

“…Separation of the resulting Si wire arrays from the parent Si wafer allows the electrical, thermal, optical, and mechanical properties of the Si wire arrays to be isolated and harnessed in devices without being overshadowed by the properties of the thick parent Si wafer and enables the transfer of the Si wire arrays to other flexible, lightweight, low cost, or transparent substrates for enhanced device functionality. A key requirement for the separation and transfer of Si wire arrays is the preservation of their original properties and orientation. − A range of methods have been developed for the separation of vertical Si wire arrays from their parent Si wafers, which rely on the mechanical breakage of the Si wires by the application of peeling forces, − direct shear forces, − or the creation of a horizontal porous crack within the Si wires. , However, these methods require that the Si wires are held together during the mechanical breaking process by encapsulation in a polymer host, the existence of which makes it difficult to use the separated Si wires for applications that require an exposed Si surface, such as for ohmic contacts to metal electrodes, sensors, or catalysts. In addition, some of these methods are only compatible with Si wires of certain geometries − or those made by particular methods. , To address these shortcomings, we have developed, and report herein, a new electroassisted transfer printing method for the transfer of vertical Si wire arrays from their parent Si wafers to other substrates without modification to the properties and orientation of the Si wires, without constraints on the Si wire geometry or fabrication method, and without the need for polymer encapsulation.…”

“…A key requirement for the separation and transfer of Si wire arrays is the preservation of their original properties and orientation. − A range of methods have been developed for the separation of vertical Si wire arrays from their parent Si wafers, which rely on the mechanical breakage of the Si wires by the application of peeling forces, − direct shear forces, − or the creation of a horizontal porous crack within the Si wires. , However, these methods require that the Si wires are held together during the mechanical breaking process by encapsulation in a polymer host, the existence of which makes it difficult to use the separated Si wires for applications that require an exposed Si surface, such as for ohmic contacts to metal electrodes, sensors, or catalysts. In addition, some of these methods are only compatible with Si wires of certain geometries − or those made by particular methods. , To address these shortcomings, we have developed, and report herein, a new electroassisted transfer printing method for the transfer of vertical Si wire arrays from their parent Si wafers to other substrates without modification to the properties and orientation of the Si wires, without constraints on the Si wire geometry or fabrication method, and without the need for polymer encapsulation. The fundamental understanding gained from this new electroassisted transfer method also enabled us to develop a current-induced metal-assisted chemical etching method for the facile and rapid synthesis of Si nanowires with axially modulated porosity.…”

Electroassisted Transfer of Vertical Silicon Wire Arrays Using a Sacrificial Porous Silicon Layer

“…Separation of the resulting Si wire arrays from the parent Si wafer allows the electrical, thermal, optical, and mechanical properties of the Si wire arrays to be isolated and harnessed in devices without being overshadowed by the properties of the thick parent Si wafer and enables the transfer of the Si wire arrays to other flexible, lightweight, low cost, or transparent substrates for enhanced device functionality. A key requirement for the separation and transfer of Si wire arrays is the preservation of their original properties and orientation. − A range of methods have been developed for the separation of vertical Si wire arrays from their parent Si wafers, which rely on the mechanical breakage of the Si wires by the application of peeling forces, − direct shear forces, − or the creation of a horizontal porous crack within the Si wires. , However, these methods require that the Si wires are held together during the mechanical breaking process by encapsulation in a polymer host, the existence of which makes it difficult to use the separated Si wires for applications that require an exposed Si surface, such as for ohmic contacts to metal electrodes, sensors, or catalysts. In addition, some of these methods are only compatible with Si wires of certain geometries − or those made by particular methods. , To address these shortcomings, we have developed, and report herein, a new electroassisted transfer printing method for the transfer of vertical Si wire arrays from their parent Si wafers to other substrates without modification to the properties and orientation of the Si wires, without constraints on the Si wire geometry or fabrication method, and without the need for polymer encapsulation.…”

“…A key requirement for the separation and transfer of Si wire arrays is the preservation of their original properties and orientation. − A range of methods have been developed for the separation of vertical Si wire arrays from their parent Si wafers, which rely on the mechanical breakage of the Si wires by the application of peeling forces, − direct shear forces, − or the creation of a horizontal porous crack within the Si wires. , However, these methods require that the Si wires are held together during the mechanical breaking process by encapsulation in a polymer host, the existence of which makes it difficult to use the separated Si wires for applications that require an exposed Si surface, such as for ohmic contacts to metal electrodes, sensors, or catalysts. In addition, some of these methods are only compatible with Si wires of certain geometries − or those made by particular methods. , To address these shortcomings, we have developed, and report herein, a new electroassisted transfer printing method for the transfer of vertical Si wire arrays from their parent Si wafers to other substrates without modification to the properties and orientation of the Si wires, without constraints on the Si wire geometry or fabrication method, and without the need for polymer encapsulation. The fundamental understanding gained from this new electroassisted transfer method also enabled us to develop a current-induced metal-assisted chemical etching method for the facile and rapid synthesis of Si nanowires with axially modulated porosity.…”

Electroassisted Transfer of Vertical Silicon Wire Arrays Using a Sacrificial Porous Silicon Layer

Polymer‐free Vertical Transfer of Silicon Nanowires and their Application to Energy Storage

Fabrication of 3D-silicon micro-pillars/walls decorated with aluminum-ZnO/ZnO nanowires for optoelectric devices