Autosampler rail system with magnetic coupling for linear motion

What is claimed is: 1 . An autosampler system comprising: a sample probe support structure configured to hold a sample probe, the sample probe configured to transfer fluid samples through the sample probe while being held by the sample probe support structure; a support tube coupled with the sample probe support structure, the support tube defining an interior volume; an outer shuttle coupled with an outer surface of the support tube and coupled with the sample probe support structure; and an inner shuttle linearly moveable within the interior volume of the support tube, the inner shuttle magnetically coupled with the outer shuttle to translate linear motion of the inner shuttle to the outer shuttle to provide linear motion of the sample probe support structure. 2 . The autosampler system of claim 1 , wherein the support tube includes a portion disposed between the outer shuttle and the inner shuttle. 3 . The autosampler system of claim 2 , wherein the support tube defines one or more surface features on an outer surface of the support tube, and wherein the outer shuttle defines one or more corresponding surface features on an interior surface of the outer shuttle such that rotational motion of the support tube is translated to the outer shuttle through interaction between the one or more surface features and the one or more corresponding surface features. 4 . The autosampler system of claim 3 , wherein the one or more surface features include one or more splines. 5 . The autosampler system of claim 3 , further comprising a drive system coupled with the support tube, wherein the drive system provides rotational motion of the support tube upon operation of the drive system. 6 . The autosampler system of claim 5 , further comprising a second drive system coupled with the inner shuttle to provide the linear motion of the inner shuttle within the interior volume of the tube. 7 . The autosampler system of claim 1 , further comprising a drive system coupled with the inner shuttle to provide the linear motion of the inner shuttle within the interior volume of the support tube. 8 . The autosampler system of claim 1 , wherein the inner shuttle includes one or more magnets housed within an exterior structure of the inner shuttle, wherein the outer shuttle includes one or more magnets housed within a body structure of the outer shuttle, and wherein the one or more magnets of the inner shuttle are magnetically coupled with the one or more magnets of the outer shuttle. 9 . The autosampler system of claim 8 , wherein the one or more magnets of the inner shuttle include a first magnet vertically spaced from a second magnet via a spacer structure. 10 . The autosampler system of claim 9 , wherein a first pole of the first magnet and a first pole of the second magnet are each positioned against the spacer structure, and wherein the first pole of the first magnet and the first pole of the second magnet are the same magnetic pole. 11 . The autosampler system of claim 9 , wherein the one or more magnets of the outer shuttle include a first magnet vertically spaced from a second magnet via a second spacer structure. 12 . The autosampler system of claim 11 , wherein a first pole of the first magnet of the outer shuttle and a first pole of the second magnet of the outer shuttle are each positioned against the second spacer structure, and wherein the first pole of the first magnet of the outer shuttle and the first pole of the second magnet of the outer shuttle are the same magnetic pole. 13 . The autosampler system of claim 1 , wherein at least a portion of each of the support tube, the outer shuttle, and the sample probe support structure include a chemically-inert material. 14 . The autosampler system of claim 1 , wherein an outer surface of the support tube defines a key structure configured to mate with a corresponding key structure positioned on an inner surface of the outer shuttle. 15 . The autosampler system of claim 14 , wherein the outer shuttle defines a second key structure positioned on an outer surface of the outer shuttle configured to mate with a corresponding second key structure positioned on the sample probe support structure to orient the sample probe support structure relative to the outer shuttle. 16 . The autosampler system of claim 1 , wherein the outer shuttle defines at least two segments positioned at a top portion of the outer shuttle, and wherein the sample probe support structure provides an inward force against the at least two segments to push the at least two segments against the support tube. 17 . The autosampler system of claim 1 , wherein the outer shuttle defines a groove on an outer surface of the outer shuttle, and wherein the sample probe support structure defines a protrusion on an interior surface of the sample probe support structure configured to be introduced into the groove. 18 . An autosampler system comprising: a sample probe support structure configured to hold a sample probe, the sample probe configured to transfer fluid samples through the sample probe while being held by the sample probe support structure; a support tube coupled with the sample probe support structure, the support tube defining an interior volume; an outer shuttle coupled with the support tube and coupled with the sample probe support structure, the outer shuttle including at least a first magnet; an inner shuttle linearly moveable within the interior volume of the support tube, the inner shuttle including at least a second magnet, the inner shuttle magnetically coupled with the outer shuttle via magnetic interaction between the first magnet and the second magnet to translate linear motion of the inner shuttle to the outer shuttle to provide linear motion of the sample probe support structure, wherein the support tube includes a portion disposed between the outer shuttle and the inner shuttle, and wherein the inner shuttle is permitted to pass through the portion during linear motion. 19 . The autosampler system of claim 18 , wherein the support tube defines one or more surface features on an outer surface of the support tube, and wherein the outer shuttle defines one or more corresponding surface features on an interior surface of the outer shuttle such that rotational motion of the tube is translated to the outer shuttle through interaction between the one or more surface features and the one or more corresponding surface features. 20 . The autosampler system of claim 19 , further comprising a first drive system coupled with the inner shuttle to provide the linear motion of the inner shuttle within the interior volume of the support tube.