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An example method for making thermoelectric modules generally includes coupling a first wafer and a second wafer together, processing the first and second wafers to produce a first thermoelectric element and a second thermoelectric element where the first thermoelectric element and the second thermo

An example method for making thermoelectric modules generally includes coupling a first wafer and a second wafer together, processing the first and second wafers to produce a first thermoelectric element and a second thermoelectric element where the first thermoelectric element and the second thermoelectric element are coupled together, coupling the first thermoelectric element to a first conductor, coupling the second thermoelectric element to a second conductor, separating the first thermoelectric element and the second thermoelectric element, coupling the first thermoelectric element to a third conductor whereby the first thermoelectric element, the first conductor, and the third conductor form at least part of a thermoelectric module, and coupling the second thermoelectric element to a fourth conductor whereby the second thermoelectric element, the second conductor, and the fourth conductor form at least part of another thermoelectric module.

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1. A method for making thermoelectric modules, the method comprising: coupling a first wafer and a second wafer together using a bonding agent, the first and second wafers being formed from the same N-type or P-type material;processing the first and second wafers to produce a first thermoelectric el

1. A method for making thermoelectric modules, the method comprising: coupling a first wafer and a second wafer together using a bonding agent, the first and second wafers being formed from the same N-type or P-type material;processing the first and second wafers to produce a first thermoelectric element from the first wafer and a second thermoelectric element from the second wafer, the first thermoelectric element and the second thermoelectric element being coupled together by the bonding agent such that the first and second thermoelectric elements are formed from the same N-type or P-type material and thereby define at least one pair of coupled N-type or P-type thermoelectric elements;coupling the first thermoelectric element to a first conductor;coupling the second thermoelectric element to a second conductor;separating the first thermoelectric element and the second thermoelectric element while maintaining the coupling between the first thermoelectric element and the first conductor and while maintaining the coupling between the second thermoelectric element and the second conductor;coupling the first thermoelectric element to a third conductor whereby the first thermoelectric element, the first conductor, and the third conductor form at least part of a thermoelectric module; andcoupling the second thermoelectric element to a fourth conductor whereby the second thermoelectric element, the second conductor, and the fourth conductor form at least part of another thermoelectric module. 2. The method of claim 1, further comprising orienting the first and second wafers in a generally parallel and stacked configuration, and wherein processing the first and second wafers includes processing the stacked first and second wafers into multiple stacked pairs of N-type or P-type thermoelectric elements formed from the same N-type or P-type material. 3. The method of claim 1, wherein processing the first and second wafers includes cutting the first and second wafers to produce the first thermoelectric element and the second thermoelectric element. 4. The method of claim 1, wherein processing the first and second wafers includes processing the first and second wafers to produce multiple first thermoelectric elements from the first wafer and multiple second thermoelectric elements from the second wafer, each first thermoelectric element being coupled to a second thermoelectric element by the bonding agent such that the multiple first and second thermoelectric elements thereby define multiple pairs of coupled N-type or P-type thermoelectric elements. 5. The method of claim 4, further comprising orienting at least two pairs of coupled thermoelectric elements so that longitudinal axes of the at least two pairs of coupled thermoelectric elements are generally parallel. 6. The method of claim 1, wherein: the first and second wafers are both formed from an N-type material;processing the first and second wafers includes processing the first and second wafers to produce at least one pair of coupled N-type thermoelectric elements;the method further comprises: coupling a third wafer and a fourth wafer together using a bonding agent, the third and fourth wafers both formed from a P-type material; andprocessing the third and fourth wafers to produce at least one pair of coupled P-type thermoelectric elements. 7. The method of claim 1, wherein the first thermoelectric element and/or the second thermoelectric element is generally cuboid shaped. 8. The method of claim 1, wherein the bonding agent includes adhesive, and wherein separating the first thermoelectric element and the second thermoelectric element includes dissolving the adhesive with a solvent. 9. The method of claim 1, wherein the bonding agent includes tape, and wherein separating the first thermoelectric element and the second thermoelectric element includes removing the tape. 10. The method of claim 1, wherein the first thermoelectric element is coupled to the first conductor by a solder connection, and the second thermoelectric element is coupled to the second conductor by a solder connection, and wherein the bonding agent is different from the solder connections such that the first thermoelectric element and the second thermoelectric element can be separated while maintaining the solder connection between the first thermoelectric element and the first conductor and while maintaining the solder connection between the second thermoelectric element and the second conductor. 11. The method of claim 1, wherein: the first conductor is coupled to a first substrate;the second conductor is coupled to a second substrate;the third conductor is coupled to a third substrate;the fourth conductor is coupled to a fourth substrate;the first thermoelectric element is between the first and third conductors and between the first and third substrates; andthe second thermoelectric element is between the second and fourth conductors and between the second and fourth substrates. 12. A method for making thermoelectric modules, the method comprising: coupling a first wafer and a second wafer together using a bonding agent, the first and second wafers both formed from an N-type material;processing the first and second wafers to produce one or more first N-type thermoelectric elements and one or more second N-type thermoelectric elements, each first N-type thermoelectric element being coupled to a second N-type thermoelectric element by the bonding agent such that the first and second N-type thermoelectric elements thereby define one or more pairs of coupled N-type thermoelectric elements;coupling a third wafer and a fourth wafer together using a bonding agent, the third and fourth wafers both formed from a P-type material;processing the third and fourth wafers to produce one or more first P-type thermoelectric elements and one or more second P-type thermoelectric elements, each first P-type thermoelectric element being coupled to a second P-type thermoelectric element by the bonding agent such that the first and second P-type thermoelectric elements thereby define one or more pairs of coupled P-type thermoelectric elements;coupling the first N-type and P-type thermoelectric elements to one or more first conductors;coupling the second N-type and P-type thermoelectric elements to one or more second conductors;separating the first and second N-type thermoelectric elements and the first and second P-type elements while maintaining the coupling to the first and second conductors;coupling the first N-type and P-type thermoelectric elements to one or more third conductors such that the first N-type and P-type thermoelectric elements are generally between the first and third conductors, whereby the first N-type and P-type thermoelectric elements and the first and third conductors form at least part of a first thermoelectric module; andcoupling the second N-type and P-type thermoelectric elements to one or more fourth conductors such that the second N-type and P-type thermoelectric elements are generally between the second and fourth conductors, whereby the second N-type and P-type thermoelectric elements and the second and fourth conductors form at least part of a second thermoelectric module. 13. The method of claim 12, further comprising orienting a pair of coupled thermoelectric elements formed from the N-type material adjacent a pair of coupled thermoelectric elements formed from the P-type material such that longitudinal axes of the adjacent pairs of coupled thermoelectric elements are generally parallel. 14. The method of claim 13, further comprising orienting multiple pairs of coupled thermoelectric elements formed from the N-type material and multiple pairs of coupled thermoelectric elements formed from the P-type material such that longitudinal axes of the multiple pairs of coupled thermoelectric elements are generally parallel. 15. The method of claim 12, wherein: the one or more first conductors are coupled to a first substrate and electrically connect adjacent first N-type and P-type thermoelectric elements;the one or more second conductors are coupled to a second substrate and electrically connect adjacent second N-type and P-type thermoelectric elements;the one or more third conductors are coupled to a third substrate;the one or more fourth conductors are coupled to a fourth substrate;the first N-type and P-type thermoelectric elements are between the first and third conductors and between the first and third substrates; andthe second N-type and P-type thermoelectric elements are between the second and fourth conductors and between the second and fourth substrates. 16. A method for making thermoelectric modules, the method comprising: coupling a first semiconductor material to a second semiconductor material such that the first semiconductor material is generally layered over the second semiconductor material, the first and second semiconductor materials being formed from the same N-type or P-type material;processing the first and second semiconductor materials to produce one or more pairs of coupled N-type or P-type thermoelectric elements, each pair of coupled thermoelectric elements including a first thermoelectric element formed from the first semiconductor material and a second thermoelectric element formed from the second semiconductor material such that the first and second thermoelectric elements of the one or more pairs of coupled thermoelectric elements are formed from the same N-type or P-type material;coupling the first thermoelectric element of the one or more pairs of coupled N-type or P-type thermoelectric elements to one or more first conductors;coupling the second thermoelectric element of the one or more pairs of coupled N-type or P-type thermoelectric elements to one or more second conductors;separating the first and second thermoelectric elements of each of said one or more pairs of coupled N-type or P-type thermoelectric elements while maintaining the coupling to the first and second conductors. 17. The method of claim 16, wherein: coupling the first semiconductor material to the second semiconductor material includes coupling the first semiconductor material to the second semiconductor material using adhesive and/or tape; andseparating the first and second thermoelectric elements includes dissolving the adhesive using a solvent and/or removing the tape. 18. The method of claim 17, wherein processing the first and second semiconductor materials includes cutting the first and second semiconductor materials to produce the one or more pairs of coupled N-type or P-type thermoelectric elements. 19. The method of claim 16, further comprising orienting multiple pairs of coupled thermoelectric elements so that longitudinal axes of each of the multiple pairs of coupled thermoelectric element are generally parallel. 20. The method of claim 16, wherein at least one first thermoelectric element of the one or more pairs of coupled N-type or P-type thermoelectric elements includes a generally cubic shape, and wherein at least one second thermoelectric element of the one or more pairs of coupled N-type or P-type thermoelectric elements includes a generally cuboid shape. 21. The method of claim 16, wherein: the first conductor is coupled to a first substrate;the second conductors is coupled to a second substrate;the third conductor is coupled to a third substrate;the fourth conductor is coupled to a fourth substrate;the first thermoelectric element is between the first and third conductors and between the first and third substrates; andthe second thermoelectric element is between the second and fourth conductors and between the second and fourth substrates. 22. The method of claim 16, wherein: coupling the first semiconductor material to the second semiconductor material includes coupling the first semiconductor material to the second semiconductor material using a bonding agent;the first thermoelectric element of the one or more pairs of coupled N-type or P-type thermoelectric elements is coupled to the one or more first conductors by a solder connection;the second thermoelectric element of the one or more pairs of coupled N-type or P-type thermoelectric elements is coupled to the one or more second conductors by a solder connection; andthe bonding agent is different from the solder connections such that the first thermoelectric element and the second thermoelectric element can be separated while maintaining the solder connection between the first thermoelectric element and the first conductor and while maintaining the solder connection between the second thermoelectric element and the second conductor. 23. The method of claim 16, further comprising: coupling the separated first thermoelectric elements of the one or more pairs of coupled N-type or P-type thermoelectric elements to one or more third conductors; andcoupling the separated second thermoelectric elements of the one or more pairs of coupled N-type or P-type thermoelectric elements to one or more second conductors. 24. A method for making thermoelectric modules, the method comprising: coupling a first semiconductor material to a second semiconductor material, the first and second semiconductor materials being formed from an N-type material;processing the first and second semiconductor materials to produce one or more pairs of coupled N-type thermoelectric elements, each pair of coupled N-type thermoelectric elements including a first N-type thermoelectric element formed from the first semiconductor material and a second N-type thermoelectric element formed from the second semiconductor material;coupling a third semiconductor material to a fourth semiconductor material, the third and fourth semiconductor materials being formed from a P-type material;processing the third and fourth semiconductor materials to produce one or more pairs of coupled P-type thermoelectric elements, each pair of coupled P-type thermoelectric elements including a first P-type thermoelectric element formed from the third semiconductor material and a second P-type thermoelectric element formed from the fourth semiconductor material;coupling the first N-type and P-type thermoelectric elements to one or more first conductors;coupling the second N-type and P-type thermoelectric elements to one or second conductors;separating the first and second N-type thermoelectric elements and the first and second P-type elements while maintaining the coupling to the first and second conductors;coupling the first N-type and P-type thermoelectric elements to one or more third conductors such that the first N-type and P-type thermoelectric elements are generally between the first and third conductors, whereby the first N-type and P-type thermoelectric elements and the first and third conductors form at least part of a first thermoelectric module; andcoupling the second N-type and P-type thermoelectric elements to one or more fourth conductors such that the second N-type and P-type thermoelectric elements are generally between the second and fourth conductors, whereby the second N-type and P-type thermoelectric elements and the second and fourth conductors form at least part of a second thermoelectric module. 25. The method of claim 24, wherein: the one or more first conductors are coupled to a first substrate and electrically connect adjacent first N-type and P-type thermoelectric elements;the one or more second conductors are coupled to a second substrate and electrically connect adjacent second N-type and P-type thermoelectric elements;the one or more third conductors are coupled to a third substrate;the one or more fourth conductors are coupled to a fourth substrate;the first N-type and P-type thermoelectric elements are between the first and third conductors and between the first and third substrates; andthe second N-type and P-type thermoelectric elements are between the second and fourth conductors and between the second and fourth substrates. 26. A method for making thermoelectric modules, the method comprising: coupling a first wafer and a second wafer together using a bonding agent, the first and second wafers both formed from an N-type material;processing the first and second wafers to produce one or more first N-type thermoelectric elements and one or more second N-type thermoelectric elements, each first N-type thermoelectric element being coupled to a second N-type thermoelectric element by the bonding agent such that the first and second N-type thermoelectric elements thereby define one or more pairs of coupled N-type thermoelectric elements;coupling a third wafer and a fourth wafer together using a bonding agent, the third and fourth wafers both formed from a P-type material;processing the third and fourth wafers to produce one or more first P-type thermoelectric elements and one or more second P-type thermoelectric elements, each first P-type thermoelectric element being coupled to a second P-type thermoelectric element by the bonding agent such that the first and second P-type thermoelectric elements thereby define one or more pairs of coupled P-type thermoelectric elements;coupling the first N-type and P-type thermoelectric elements to one or more first conductors;coupling the second N-type and P-type thermoelectric elements to one or more second conductors;separating the first and second N-type thermoelectric elements and the first and second P-type elements while maintaining the coupling to the first and second conductors;coupling the separated first N-type and P-type thermoelectric elements to one or more third conductors, whereby the first N-type and P-type thermoelectric elements and the first and third conductors form at least part of a first thermoelectric module; andcoupling the separated second N-type and P-type thermoelectric elements to one or more fourth conductors, whereby the second N-type and P-type thermoelectric elements and the second and fourth conductors form at least part of a second thermoelectric module. 27. The method of claim 26, wherein: processing the first and second wafers includes cutting the first and second wafers to produce the first and second N-type thermoelectric elements; andprocessing the third and fourth wafers includes cutting the third and fourth wafers to produce the first and second P-type thermoelectric elements.