Systems and methods for amplifying nucleic acids

What is claimed is: 1. An adaptable apparatus for performing a thermocyclic process comprising: a microfluidic chip having a fluid channel formed therein; and one or more thermal distribution elements, each of which is separate from the microfluidic chip; wherein the one or more thermal distribution elements are placed in thermal communication with an associated portion of said microfluidic chip, each said thermal distribution element being constructed and arranged to distribute thermal energy from an external thermal energy source, including at least one heater, substantially uniformly over said associated portion of said microfluidic chip, wherein each of the one or more thermal distribution elements is positioned between and in contact with the microfluidic chip and the at least one heater, wherein the size and positioning of the one or more heaters and thermal distribution elements in relation to the fluid channel creates two or more adaptable temperature zones on the microfluidic chip, thereby defining said associated portion as one of said temperature zones within said microfluidic chip, a detector configured to detect emissions originating from one or more locations within the channel, wherein the one or more heaters and thermal distribution elements positioned on the same side as the detector relative to the microfluidic chip obstruct optical communication between the detector and a fluid in the fluid channel passing through temperature zones in thermal communication with the thermal distribution elements, wherein fluid passing through a temperature zone not in thermal communication with the thermal distribution element is in optical communication with the detector, wherein the size and positioning of the one or more thermal distribution elements in relation to the microfluidic chip is changeable, wherein said channel is arranged such that the fluid flowing through the channel would enter and exit each of said temperature zones of the microfluidic chip a plurality of times. 2. The apparatus of claim 1 , wherein one of said temperature zones comprises a portion of said fluid channel that is not in thermal communication with any of said thermal distribution elements, wherein said detector is configured to detect emissions originating from locations within substantially only the temperature zone not in thermal communication with any of said thermal distribution elements. 3. The apparatus of claim 1 , comprising: a first temperature zone defined by a first thermal distribution element; a second temperature zone defined by a second thermal distribution element; and a third temperature zone comprising a portion of said fluid channel that is not in thermal communication with any of said thermal distribution elements, wherein said detector is configured to detect emissions originating from locations within substantially only said third temperature zone. 4. The apparatus of claim 1 , wherein each said thermal distribution element comprises a thermally conductive material adhered to the associated portion of the microfluidic chip. 5. The apparatus of claim 4 , wherein said thermal distribution element comprises a metal plate. 6. The apparatus of claim 4 , wherein said thermal distribution element comprises a rectangular metal block. 7. The apparatus of claim 1 , wherein said channel is configured in a serpentine pattern. 8. The apparatus of claim 1 , further comprising a label including information which can be used to identify characteristics of the thermocyclic process that can be performed with the apparatus based on characteristics of said temperature zones of said microfluidic chip. 9. The apparatus of claim 8 , wherein characteristics of said temperature zones which determine characteristics of the thermocyclic process that can be performed with the apparatus include the number and sizes of said temperature zones as determined by the sizes of said thermal distribution elements. 10. The apparatus of claim 8 , wherein said label comprises a machine-readable label. 11. The apparatus of claim 10 , wherein said label comprises a bar code. 12. The apparatus of claim 10 , wherein said label comprises an RFID tag. 13. The apparatus of claim 1 , wherein altering the size and/or position of the thermal distribution elements changes the amount of time a fluid flowing through the microfluidic channel will spend in each temperature zone. 14. An adaptable system for performing a thermocyclic process, said system comprising: a microfluidic chip having a fluid channel formed therein; and one or more thermal distribution elements, each of which is separate from the microfluidic chip; wherein the one or more thermal distribution elements are placed in thermal communication with an associated portion of said microfluidic chip, each said thermal distribution element being constructed and arranged to distribute thermal energy from an external thermal energy source, including a heater, substantially uniformly over said associated portion of said microfluidic chip, wherein each of the one or more thermal distribution elements is positioned between and in contact with the microfluidic chip and the heater, wherein the size and positioning of the one or more thermal distribution elements in relation to the fluid channel creates two or more adaptable temperature zones on the microfluidic chip, thereby defining said associated portion as one of said temperature zones within said microfluidic chip, wherein the size and positioning of the one or more thermal distribution elements in relation to the microfluidic chip is changeable, wherein said channel is arranged such that the fluid flowing through the channel would enter and exit each of said temperature zones of the microfluidic chip a plurality of times; a detector configured to detect emissions originating from one or more locations within the channel, wherein the one or more heaters and thermal distribution elements positioned on the same side as the detector relative to the microfluidic chip obstruct optical communication between the detector and a fluid in the fluid channel passing through temperature zones in thermal communication with the thermal distribution elements, wherein a fluid passing through temperature zones not in thermal communication with the thermal distribution elements is in optical communication with the detector. 15. The system of claim 14 , wherein said heater comprises a Peltier heater. 16. The system of claim 15 , wherein said heater comprises a circulating fluid heater. 17. The system of claim 14 , wherein said thermal energy source comprises a cooler. 18. The system of claim 14 , wherein the thermal mass of each thermal energy source is greater than the thermal mass of said microfluidic chip. 19. The system of claim 14 , further comprising: an excitation source; and optics elements for directing at least a portion of the excitation light toward the channel and for directing at least a portion of the emission light from the channel toward said detector. 20. The system of claim 14 , further comprising: a reservoir storing a solution containing a nucleic acid sample; and a pump configured to pump the solution out of the reservoir and into the channel such that the solution will travel through the channel at a substantially constant speed. 21. The system of claim 14 , wherein one of said temperature zones comprises a portion of said fluid channel that is not in thermal communication with any of said thermal distribution eleme