Co-flow injection for serial crystallography

What is claimed is: 1. A sample ejection device for serial crystallography comprising: a sample fluid channel; an immiscible oil fluid channel; an output channel; and a T-junction coupling the sample fluid channel and the immiscible oil fluid channel to the output channel, wherein the T-junction is configured to receive an aqueous suspension of a crystal sample from the sample fluid channel in a first flow direction and to receive a an immiscible oil from the second fluid channel in a second flow direction, the second flow direction being perpendicular to the first flow direction at the T-junction; and, wherein the T-junction is configured to output a combined fluid output to the output channel in the second flow direction, the combined fluid output including a parallel co-flow of the aqueous suspension of the crystal sample flowing in contact with a first interior surface of the output channel and the immiscible oil flowing parallel to the aqueous suspension of the crystal sample in contact with a second interior surface of the output channel. 2. The sample ejection device of claim 1 , further comprising a jet nozzle configured to receive the combined fluid output from the T-junction and to eject the combined fluid output in a jetted output stream. 3. The sample ejection device of claim 2 , wherein the jet nozzle is configured to eject the combined fluid output in the jetted output stream into a field of view of a crystallography imaging system. 4. The sample ejection device of claim 2 , wherein the jet nozzle is configured to eject the combined fluid output in the jetted output stream into an optical path of an X-ray free electron laser. 5. The sample ejection device of claim 2 , wherein the jet nozzle is configured to eject the combined fluid output in the jetted output stream by coaxially expelling a pressurized gas and the combined fluid output in an output flow direction with the ejected pressurized gas surrounding a perimeter of the ejected combined fluid output. 6. The sample ejection device of claim 5 , wherein the pressurized gas is helium. 7. The sample ejection device of claim 1 , further comprising: a sample reservoir containing the aqueous suspension of the crystal sample; an oil reservoir containing the immiscible oil; one or more pumps configured to pump the aqueous suspension of the crystal sample from the sample reservoir through the sample fluid channel at a first flow rate and to pump the immiscible fluorinated oil from the oil reservoir through the immiscible oil fluid channel at a second flow rate; and a controller configured to independently control a sample output rate of the combined fluid output by independently regulating the first flow rate of the sample fluid channel and the second flow rate of the immiscible oil fluid channel. 8. The sample ejection device of claim 1 , wherein the sample fluid channel includes a tapered section configured to reduce a diameter of the sample fluid channel from a first diameter to a second diameter. 9. The sample ejection device of claim 1 , wherein the sample fluid channel is configured to receive the aqueous suspension of the crystal sample in the second flow direction, wherein the immiscible oil fluid channel is configured to receive the immiscible oil in the second flow direction, and wherein the sample fluid channel includes a curved section to change the flow direction of the aqueous suspension of the crystal sample from the second flow direction to the first flow direction. 10. The sample ejection device of claim 1 , further comprising a single-piece component including: the T-junction; a pressurized gas channel, an internal nozzle volume, a nozzle opening, and the output channel, wherein the pressurized gas channel is configured to receive a pressurized gas and to convey the pressurized gas to the internal nozzle volume, wherein the nozzle opening is positioned to allow the pressurized gas to exit the internal nozzle volume in a first output direction through the nozzle opening, and wherein the output channel extends into the internal nozzle volume to a location proximal to the nozzle opening such that the combined fluid output is ejected from a distal end of the output channel towards the nozzle opening in the first output direction and coaxially surrounded by the pressurized gas. 11. A method of performing serial crystallography using the sample ejection device of claim 1 , the method comprising: pumping the immiscible oil fluid through the immiscible oil fluid channel toward the T-junction at a first flow rate; pumping the aqueous suspension of the crystal sample through the sample fluid channel toward the T-junction at a second flow rate; and combining the immiscible oil fluid and the aqueous suspension of the crystal sample at the T-junction into the combined fluid output including the parallel co-flow of the immiscible oil fluid and the aqueous suspension of the crystal sample. 12. The method of claim 11 , further comprising: ejecting the combined fluid output through a nozzle as a jetted stream towards an optical path of an x-ray laser; and adjusting a sample flow rate of the crystal sample in the jetted stream by controllably adjusting the first flow rate of the immiscible oil fluid through the immiscible oil fluid channel and the second flow rate of the aqueous suspension of the crystal sample through the sample fluid channel. 13. A method of performing serial crystallography, the method comprising: providing an aqueous suspension of a crystal sample to a T-junction at a first flow rate; providing an immiscible fluorinated oil fluid to the T-junction at a second flow rate; combining the aqueous suspension of the crystal sample and the immiscible fluorinated oil fluid at the T-junction to produce a co-flow output fluid including a parallel co-flow of the aqueous suspension of the crystal sample and the immiscible fluorinated oil fluid; wherein the aqueous suspension is introduced to the flowing immiscible fluorinated oil at an angle relative to the flow channel of the immiscible fluorinated oil at the T-junction; and, wherein the parallel co-flow of the aqueous suspension of the crystal sample and the immiscible fluorinated oil includes the aqueous suspension of the crystal sample flowing along the flow channel in contact with a first interior surface of the flow channel and the immiscible fluorinated oil flowing along the flow channel in contact with a second interior surface of the flow channel, the second interior surface being opposite the first interior surface; ejecting the co-flow output fluid as a jet stream through a nozzle, wherein the co-flow output maintains the parallel co-flow in the flow channel from the T-junction to the nozzle; and adjusting the sample flow rate of the crystal sample in the jet stream by adjusting the first flow rate of the aqueous suspension of the crystal suspension and the second flow rate of the immiscible fluorinated oil fluid.