Thermal adapter for automated thermal cycling

What is claimed is: 1 . A system, comprising: a robotic sample handler configured to retain and move a multi-well reaction vessel; a thermal cycler comprising a heating chamber containing a heating element, a compliant thermally conductive insert comprising an elastically deformable creped graphite sheet positioned adjacent the heating element, and a closing mechanism, wherein the heating chamber is shaped to receive the multi-well reaction vessel and the closing mechanism is configured to press the multi-well reaction vessel toward the compliant thermally conductive insert and the heating element; and a controller operably connected with the robotic sample handler and thermal cycler, the controller comprising at least one processor and non-transitory memory containing executable instructions that, when executed by the at least one processor, configure the controller to: cause the robotic sample handler to insert the multi-well reaction vessel into the thermal cycler; cause the closing mechanism to enclose the multi-well reaction vessel in the heating chamber; compress a bottom surface of the multi-well reaction vessel into the compliant thermally conductive insert by the closing mechanism; and thermally cycle the multi-well reaction vessel in the heating chamber by the heating element by applying a controlled heat flux to the multi-well reaction vessel from the heating element through the compliant thermally conductive insert. 2 . The system of claim 1 , wherein: compressing the bottom surface of the multi-well reaction vessel into the compliant thermally conductive insert causes reversible deformation of the creped graphite sheet according to a first compression profile; compressing a second bottom surface of a second multi-well reaction vessel into the compliant thermally conductive insert causes reversible deformation of the creped graphite sheet according to a second compression profile that is different from the first compression profile; and the compliant thermally conductive insert reverts to an uncompressed state from the first compressed profile and from the second compressed profile without permanently deforming. 3 . The system of claim 1 , further comprising: a source vessel containing a reagent or sample; and an acoustic ejector comprising a transducer configured to emit focused acoustic radiation and an actuator configured to align the acoustic ejector and source vessel with wells of the multi-well reaction vessel, wherein the executable instructions, when executed by the at least one processor, further configure the controller to: cause the actuator to selectively align the transducer and source vessel with one of the wells of the multi-well reaction vessel; and cause the acoustic ejector to eject one or more droplets from the source vessel to the well by applying the focused acoustic radiation to a sample contained in the source vessel. 4 . The system of claim 1 , further comprising: a multi-well receiving vessel; and an acoustic ejector comprising a transducer configured to emit focused acoustic radiation and an actuator configured to align the acoustic ejector and the multi-well reaction vessel with wells of the multi-well receiving vessel, wherein the executable instructions, when executed by the at least one processor, further configure the controller to: cause the actuator to selectively align the transducer and multi-well reaction vessel with one or more of the wells of the multi-well receiving vessel; and cause the acoustic ejector to eject one or more droplets from the multi-well reaction vessel to the wells of the multi-well receiving vessel by applying the focused acoustic radiation to samples contained in the multi-well reaction vessel. 5 . The system of claim 1 , further comprising: an analyzer comprising a sample inlet; and an acoustic ejector comprising a transducer configured to emit focused acoustic radiation and an actuator configured to align the acoustic ejector and the multi-well reaction vessel with the sample inlet of the analyzer, wherein the executable instructions, when executed by the at least one processor, further configure the controller to: cause the actuator to selectively align the transducer and multi-well reaction vessel with the sample inlet of the analyzer; and cause the acoustic ejector to eject one or more droplets from the multi-well reaction vessel to the sample inlet by applying the focused acoustic radiation to a sample contained in the multi-well reaction vessel. 6 . A method, comprising: inserting a multi-well reaction vessel into a heating chamber of a thermal cycler by placing the multi-well reaction vessel on a compliant thermally conductive insert on a heating element of the thermal cycler, the compliant thermally conductive insert comprising an elastically deformable creped graphite sheet; enclosing the multi-well reaction vessel in the heating chamber; and compressing a bottom surface of the multi-well reaction vessel into the compliant thermally conductive insert to increase a thermal contact area between the bottom surface and the compliant thermally conductive insert; and thermally cycling the multi-well reaction vessel in the heating chamber by applying a controlled heat flux to the multi-well reaction vessel by the heating element through the compliant thermally conductive insert. 7 . The method of claim 6 , wherein the compliant thermally conductive insert has an uncompressed thickness in a range from 250 microns to 2000 microns. 8 . The method of claim 6 , wherein the compliant thermally conductive insert has an in-plane thermal conductivity of at least 200 W/m-K, preferably at least 700 W/m-K. 9 . The method of claim 6 , wherein the compliant thermally conductive insert has a through-plane thermal conductivity that increases nonlinearly with compressive stress, the through-plane thermal conductivity ranging from 1-5 W/m-K at 100 kPa compressive stress to 10-30 W/m-K at 700 kPa compressive stress. 10 . The method of claim 6 , wherein the compliant thermally conductive insert, when subjected to compressive stress of 700 kPa, reversibly compresses to less than 60% of an original thickness. 11 . The method of claim 6 , wherein the multi-well reaction vessel comprises a microplate comprising an array of wells having at least one flat bottom surface configured to permit acoustic auditing of a sample contained in the array of wells through the flat bottom surface, the method further comprising: emitting an interrogation toneburst from an acoustic emitter through the flat bottom surface; detecting an acoustic echo caused by the interrogation toneburst; and determining a parameter of the sample from the detected acoustic echo. 12 . The method of claim 6 , wherein thermally cycling the multi-well reaction vessel in the heating chamber comprises sequentially heating and cooling samples contained in the multi-well reaction vessel according to a PCR thermal cycle program at a heating or cooling rate of at least 1° C./s, or at least 1.5° C./s, preferably at least 2° C./s. 13 . The method of claim 6 , further comprising: aligning one or more wells of the multi-well reaction vessel with a source well and an acoustic ejector positioned to acoustically eject fluid droplets from the source well; and ejecting one or more droplets from the source well to the wells of the multi-well reaction vessel by applying focused acoustic radiation from the acoustic ejector to a sample contained in the source well. 14 . The method of claim 6 , further comprising: aligning one or more wells of the multi-well reaction vessel with