Abstract: Methods and apparatus for manufacturing a microfluidic arrangement are disclosed. In one arrangement, a continuous body of a first liquid is provided in direct contact with a first substrate. A second liquid covers the first liquid. A separation fluid, immiscible with the first liquid, is propelled through at least the first liquid and into contact with the first substrate along all of a selected path on the surface of the first substrate. First liquid that was initially in contact with all of the selected path is displaced away from the selected path. The first liquid is divided to form sub-bodies of first liquid that are separated from each other. For each of one or more of the sub-bodies, a sub-body footprint represents an area of contact between the sub-body and the first substrate, and all of a boundary of the sub-body footprint is in contact with a closed loop of the selected path surrounding the sub-body footprint.

Abstract: A microfluidic arrangement for manipulating fluids is provided. The microfluidic arrangement comprises a substrate, a first fluid and a second fluid, which is immiscible with the first fluid. The first fluid is arranged to be at least partially covered by the second fluid. The first fluid is arranged in a desired shape on an unpatterned surface of the substrate. The first fluid is retained in said shape by a fluid interface between the first and second fluids. A microfluidic arrangement comprising an array of drops is also provided. The microfluidic arrangement comprises a substrate, a first fluid and a second fluid, which is immiscible with the first fluid. The first fluid is arranged to be at least partially covered by the second fluid. The first fluid is arranged to be covered at least partially by the second fluid. The first fluid is arranged in a given array of drops on an unpatterned surface of the substrate. Each drop cross section area having a (height:width) aspect ratio of (1:2) or less.

Abstract: Methods and apparatus for manufacturing and operating a microfluidic arrangement are disclosed. In one arrangement, a continuous body of a first liquid is provided in direct contact with a first substrate. A second liquid is provided in direct contact with the continuous body of first liquid and covering the continuous body of first liquid, the second liquid being immiscible with the first liquid.

Abstract: The disclosure relates to manufacturing a microfluidic arrangement wherein a second liquid (2) such as fluorinated oil is provided in direct contact with a continuous body of a first liquid (1) such as an aqueous cell culture medium and covering the first pot liquid. The second liquid is caused to move through the first liquid and into contact with a substrate (11) along all of a selected path to displace first liquid. The selected path is such that one or more walls of second liquid are formed that modify a shape of the continuous body of first liquid. The first liquid is aqueous. The second liquid is immiscible with the first liquid. The second liquid is treated in a liquid treatment apparatus (50), prior to the second liquid being caused to move through the first liquid, by flowing a gas through the second liquid and thereby increasing a level of saturation of the second liquid.

Abstract: Methods and apparatus for driving flow in a microfluidic arrangement are provided. In one disclosed arrangement, the microfluidic arrangement comprises a first liquid held predominantly by surface tension in a shape defining a microfluidic pattern on a surface of a substrate. The microfluidic pattern comprises at least an elongate conduit and a first reservoir. The area of contact between the substrate and a portion of the first liquid that forms the elongate conduit defines a conduit footprint. The area of contact between the substrate and a portion of the first liquid that forms the first reservoir defines a first reservoir footprint. The size and shape of each of the conduit footprint and the first reservoir footprint are such that a maximum Laplace pressure supportable by the first liquid in the elongate conduit without any change in the conduit footprint is higher than a maximum Laplace pressure supportable by the first liquid in the first reservoir without any change in the first reservoir footprint.

Abstract: Methods and apparatus for providing an isolated single cell are provided. In one disclosed arrangement, a test body of liquid is formed on a substrate surface. A contact angle between the test body of liquid and the substrate surface is lower than an equilibrium contact angle. An optical image of the test body of liquid is analysed to determine whether one and only one cell is present in the test body of liquid.

Abstract: Methods and apparatus for controlling flow in a microfluidic arrangement are disclosed. In one arrangement, a microfluidic arrangement comprises a first liquid held predominantly by surface tension in a shape defining a microfluidic pattern on a surface of a substrate. The microfluidic pattern comprises at least an elongate conduit and a first reservoir. A second liquid is in direct contact with the first liquid and covers the microfluidic pattern. A flow of liquid is driven through the elongate conduit into the first reservoir.

Abstract: Methods and apparatus for manufacturing a microfluidic arrangement are disclosed. In one arrangement, a continuous body of a first liquid is provided in direct contact with a first substrate. A second liquid covers the first liquid. A separation fluid, immiscible with the first liquid, is propelled through at least the first liquid and into contact with the first substrate along all of a selected path on the surface of the first substrate. First liquid that was initially in contact with all of the selected path is displaced away from the selected path. The first liquid is divided to form sub-bodies of first liquid that are separated from each other. For each of one or more of the sub-bodies, a sub-body footprint represents an area of contact between the sub-body and the first substrate, and all of a boundary of the sub-body footprint is in contact with a closed loop of the selected path surrounding the sub-body footprint.

Abstract: Methods and apparatus for driving flow in a microfluidic arrangement are provided. In one disclosed arrangement, the microfluidic arrangement comprises a first liquid held predominantly by surface tension in a shape defining a microfluidic pattern on a surface of a substrate. The microfluidic pattern comprises at least an elongate conduit and a first reservoir. The area of contact between the substrate and a portion of the first liquid that forms the elongate conduit defines a conduit footprint. The area of contact between the substrate and a portion of the first liquid that forms the first reservoir defines a first reservoir footprint. The size and shape of each of the conduit footprint and the first reservoir footprint are such that a maximum Laplace pressure supportable by the first liquid in the elongate conduit without any change in the conduit footprint is higher than a maximum Laplace pressure supportable by the first liquid in the first reservoir without any change in the first reservoir footprint.

Abstract: Methods and apparatus for manufacturing a microfluidic arrangement are disclosed. In one arrangement a continuous body of a first liquid is provided in direct contact with a substrate. A second liquid is provided in direct contact with the first liquid and covering the first liquid. The first liquid is in direct contact exclusively with the second liquid and the substrate. The second liquid is forced through the first liquid and into contact with the substrate in selected regions of the substrate in order to divide the continuous body of the first liquid into a plurality of sub-bodies of the first liquid that are separated from each other by the second liquid. The first liquid is immiscible with the second liquid. Surface tension stably holds the plurality of sub-bodies of the first liquid separated from each other by the second liquid.

Abstract: Methods and apparatus for controlling flow in a microfluidic arrangement are disclosed. In one arrangement, a microfluidic arrangement comprises a first liquid held predominantly by surface tension in a shape defining a microfluidic pattern on a surface of a substrate. The microfluidic pattern comprises at least an elongate conduit and a first reservoir. A second liquid is in direct contact with the first liquid and covers the microfluidic pattern. A flow of liquid is driven through the elongate conduit into the first reservoir.

Abstract: A microfluidic arrangement for manipulating fluids is provided. The microfluidic arrangement comprises a substrate, a first fluid and a second fluid, which is immiscible with the first fluid. The first fluid is arranged to be at least partially covered by the second fluid. The first fluid is arranged in a desired shape on an unpatterned surface of the substrate. The first fluid is retained in said shape by a fluid interface between the first and second fluids. A microfluidic arrangement comprising an array of drops is also provided. The microfluidic arrangement comprises a substrate, a first fluid and a second fluid, which is immiscible with the first fluid. The first fluid is arranged to be at least partially covered by the second fluid. The first fluid is arranged to be covered at least partially by the second fluid. The first fluid is arranged in a given array of drops on an unpatterned surface of the substrate. Each drop cross section area having a (height:width) aspect ratio of (1:2) or less.

Abstract: A cooling device (1) comprises a top plate (2), a bottom plate (3), an axial flow inlet (4) in the top plate (2), a rotor support (5) on the top plate (2), and a pump rotor fan (6). The outer dimensions are 40 mm in diameter and 4 mm in height. The internal separation of the plates 2 and 3 is 4 mm. The cooling device (1) has a low profile in scale. Depending on the configuration and on operating parameters steady or unsteady fluid flow vortices can be created in the heat sink. The resulting flow field enhances heat transfer rates locally through impingement cooling and thermal transport by the vortices, whether generated to be steady or unsteady in nature. Also, the vortices drive a secondary flow within the heat sink, effectively creating a pumping mechanism, which further enhances heat transfer.

Abstract: A cooling device has a finless heat sink (1) which is rectangular in plan, having two spaced-apart plates (5, 6). A fan impeller (2) and motor (3) are supported between the plates (5, 6) for axial air flow in (7) and radial flow out. The device is placed on an electronic component (4) to be cooled. The component (4) may be an electronic package, for example. The heat sink (1) is manufactured from a single piece of conducting material. There is a rotor support (8) on the top plate (5), supporting a fan rotor (3). The rotor support (8) is in a device inlet for axial flow into the fan impeller (2). There are two opposed side walls (9) interconnecting the plates 5 and 6. The device outlet is the gap between the plates (5, 6) along the open sides. The cooling device is very efficient, compact, and inexpensive to manufacture.

Abstract: This disclosure relates to a low-profile cooling device (100) for applications such as spot cooling. The low-profile cooling device can include a first rotor (102), a second rotor (104), a motor (106) including a drive shaft (108) for driving and rotating each rotor, an upper plate (110), a middle plate (112), and a lower plate (114).

Abstract: A cooling device (1) comprises a top plate (2), a bottom plate (3), an axial flow inlet (4) in the top plate (2), a rotor support (5) on the top plate (2), and a pump rotor fan (6). The outer dimensions are 40 mm in diameter and 4 mm in height. The internal separation of the plates 2 and 3 is 4 mm. The cooling device (1) has a low profile in scale. Depending on the configuration and on operating parameters steady or unsteady fluid flow vortices can be created in the heat sink. The resulting flow field enhances heat transfer rates locally through impingement cooling and thermal transport by the vortices, whether generated to be steady or unsteady in nature. Also, the vortices drive a secondary flow within the heat sink, effectively creating a pumping mechanism, which further enhances heat transfer.