XRF analyzer with a hand shield

What is claimed is: 1. A portable x-ray fluorescence (XRF) analyzer comprising: an engine component having an x-ray emission end and an engine component casing; a power component spaced-apart from the engine component; a handle and a hand shield, the handle and the hand shield extending in parallel between the engine component and the power component and wherein said handle and hand shield, together, attach the engine component to the power component; a finger gap between the handle and the hand shield; the hand shield disposed closer to the x-ray emission end than the handle to the x-ray emission end; an x-ray source and an x-ray detector disposed in the engine component casing; the x-ray source disposed in a location and oriented to emit x-rays outward from the x-ray emission end towards a sample; the x-ray detector disposed in a location and oriented to receive fluoresced x-rays emitted from the sample; and the power component including electrical connections configured for electrical connection to a portable, electric power-source. 2. The XRF analyzer of claim 1 , further comprising: an x-ray source heat-sink disposed in an opening in the engine component casing and adjacent a side of the x-ray source; an x-ray detector heat-sink disposed in another opening in the engine component casing and adjacent a side of the x-ray detector; and the x-ray source heat-sink separated from the x-ray detector heat sink by thermally insulating material. 3. The XRF analyzer of claim 2 , wherein the x-ray source heat-sink is separated from the x-ray detector heat sink by at least 3 millimeters of the thermally insulating material and the thermally insulating material is a segment of the engine component casing with a thermal conductivity of less than 20 W/(m*K). 4. The XRF analyzer of claim 2 , wherein the x-ray source heat-sink includes one x-ray source heat-sink disposed on one side of the x-ray source and another x-ray source heat-sink disposed on an opposite side of the x-ray source. 5. The XRF analyzer of claim 2 , wherein the x-ray detector heat-sink is disposed at the x-ray emission end of the XRF analyzer. 6. The XRF analyzer of claim 1 , wherein the hand shield includes a hand shield casing, the hand shield casing and the engine component casing comprise a material for blocking x-rays, and the material for blocking x-rays comprises plastic impregnated with tungsten, tantalum, molybdenum, or combinations thereof. 7. The XRF analyzer of claim 1 , further comprising a hollow formed in the hand shield, a hand shield casing forming a perimeter around at least a majority of the hollow, and an electronic component disposed in the hollow, the electronic component configured for operation of the x-ray source, the x-ray detector, or both. 8. The XRF analyzer of claim 7 , wherein the electronic component includes a digital pulse processor electrically connected to the x-ray detector. 9. The XRF analyzer of claim 1 , further comprising two housing portions joined together to form an XRF analyzer housing, each housing portion: comprising an engine component casing section, a power component casing section, a hand shield casing section, a handle casing section, and a material for blocking x-rays; and being integrally formed in a single, monolithic body formed together at the same time with the hand shield casing section and the handle casing section extending in parallel between and attaching to the engine component casing section and the power component casing section of each housing portion. 10. The XRF analyzer of claim 9 , wherein each housing portion is integrally formed in a single, monolithic body formed together at the same time by injection molding. 11. The XRF analyzer of claim 1 , wherein the hand shield has a length that is between 60% and 90% of a length of the handle. 12. A portable x-ray fluorescence (XRF) analyzer comprising: an engine component having an x-ray emission end and an engine component casing; an x-ray source and an x-ray detector disposed in the engine component casing; the x-ray source disposed in a location and oriented to emit x-rays outward from the x-ray emission and towards a sample; the x-ray detector disposed in a location and oriented to receive fluoresced x-rays emitted from the sample; a handle extending form the engine component to allow a user to hold and carry the XRF analyzer; a hand shield extending from the engine component in a direction parallel to the extension direction of the handle, said hand shield being disposed closer to the x-ray emission end than the handle is to the x-ray emission end; a finger-gap between the handle and the hand shield; two housing portions joined together to form an XRF analyzer housing, each housing portion; comprising a material for blocking x-rays, and engine component casing section, a handle casing section extending from the engine component casing section, and a hand shield casing section extending from the engine component casing section in a direction parallel to the extension direction of the handle casing sections; and being integrally formed in a single, monolithic body formed together at the same time; an x-ray source heat-sink disposed in an opening in the engine component casing and adjacent a side of the x-ray source; an x-ray detector heat-sink disposed in another opening in the engine component casing and adjacent a side of the x-ray detector; and the x-ray source heat-sink separated from the x-ray detector heat sink by thermally insulating material. 13. The XRF analyzer of claim 12 , wherein the x-ray source heat-sink is separated from the x-ray detector heat sink by at least 3 millimeters of the thermally insulating material and the thermally insulating material is a segment of the engine component casing with a thermal conductivity of less than 20 W/(m*K). 14. The XRF analyzer of claim 12 , further comprising a hollow formed in the hand shield casing section with the two hand shield casing sections forming a perimeter around at least a majority of the hollow, an electronic component disposed in the hollow, and the electronic component configured for operation of the x-ray source, the x-ray detector, or both. 15. The XRF analyzer of claim 12 , wherein the material for blocking x-rays comprises plastic impregnated with tungsten, tantalum, molybdenum, or combinations thereof. 16. The XRF analyzer of claim 12 , wherein the hand shield has a length that is between 60% and 90% of a length of the handle. 17. The XRF analyzer of claim 16 , wherein the handle and the hand shield have a forward-leaning angle. 18. XRF analyzer comprising an engine component having an x-ray emission end and an engine component casing; an x-ray source and an x-ray detector disposed in the engine component casing; the x-ray source disposed in a location and oriented to emit x-rays outward from the x-ray emission and towards a sample; the x-ray detector disposed in a location and oriented to receive fluoresced x-rays emitted from the sample; a handle extending form the engine component to allow a user to hold and carry the XRF analyzer; a hand shield extending from the engine component in a direction parallel to the extension direction of the handle, said hand shield being disposed closer to the x-ray emission end than the handle is to the x-ray emission end than the handle; a finger-gap between the handle and the hand shield; wherein the hand shield has a length that is between 60% and 90% of a length of the handle; and a hollow formed in the hand shield, a hand shie