LnRiLWhlYWRpbmcuaGFzLWJhY2tncm91bmR7cGFkZGluZzowfQ==
LnRiLWZpZWxke21hcmdpbi1ib3R0b206MC43NmVtfS50Yi1maWVsZC0tbGVmdHt0ZXh0LWFsaWduOmxlZnR9LnRiLWZpZWxkLS1jZW50ZXJ7dGV4dC1hbGlnbjpjZW50ZXJ9LnRiLWZpZWxkLS1yaWdodHt0ZXh0LWFsaWduOnJpZ2h0fS50Yi1maWVsZF9fc2t5cGVfcHJldmlld3twYWRkaW5nOjEwcHggMjBweDtib3JkZXItcmFkaXVzOjNweDtjb2xvcjojZmZmO2JhY2tncm91bmQ6IzAwYWZlZTtkaXNwbGF5OmlubGluZS1ibG9ja311bC5nbGlkZV9fc2xpZGVze21hcmdpbjowfQ==
.tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row } .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row }   .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row } .wpv-pagination-nav-links[data-toolset-views-view-pagination-block="cdfd4c4737b2898eba4443dd59a1bf50"] { text-align: left;justify-content: flex-start; } .tb-field[data-toolset-blocks-field="9cbffc8f0bb443fa4d7772ff6b497331"] { margin-bottom: 20px; }  h1.tb-heading[data-toolset-blocks-heading="92c335762acd52b936b2b92f1f6a1f4e"]  { margin-top: 10px; }  @media only screen and (max-width: 781px) { .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row } .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row }   .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row }    } @media only screen and (max-width: 599px) { .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"]  > .tb-grid-column:nth-of-type(1n+1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 1fr);grid-auto-flow: row } .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"]  > .tb-grid-column:nth-of-type(1n+1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 1fr);grid-auto-flow: row }   .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"]  > .tb-grid-column:nth-of-type(1n+1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 1fr);grid-auto-flow: row }    } 
NMR Solvents – Stable Isotopes
.tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row } .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row }   .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row } .wpv-pagination-nav-links[data-toolset-views-view-pagination-block="cdfd4c4737b2898eba4443dd59a1bf50"] { text-align: left;justify-content: flex-start; } .tb-field[data-toolset-blocks-field="9cbffc8f0bb443fa4d7772ff6b497331"] { margin-bottom: 20px; }  h1.tb-heading[data-toolset-blocks-heading="92c335762acd52b936b2b92f1f6a1f4e"]  { margin-top: 10px; }  @media only screen and (max-width: 781px) { .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row } .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row }   .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 2) { grid-column: 2 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] > .tb-grid-column:nth-of-type(3n + 3) { grid-column: 3 } .wpv-view-output[data-toolset-views-view-editor="996f6e65dca482f54bf3d67d7e970744"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 0.3333fr) minmax(0, 0.3333fr) minmax(0, 0.3333fr);grid-auto-flow: row }    } @media only screen and (max-width: 599px) { .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"]  > .tb-grid-column:nth-of-type(1n+1) { grid-column: 1 } .wpv-view-output[data-toolset-views-view-editor="e9fe28b8275bb7ae2596f589255e6c42"] .js-wpv-loop-wrapper > .tb-grid { grid-template-columns: minmax(0, 1fr);grid-auto-flow: row } .tb-grid,.tb-grid>.block-editor-inner-blocks>.block-editor-block-list__layout{display:grid;grid-row-gap:25px;grid-column-gap:25px}.tb-grid-item{background:#d38a03;padding:30px}.tb-grid-column{flex-wrap:wrap}.tb-grid-column>*{width:100%}.tb-grid-column.tb-grid-align-top{width:100%;display:flex;align-content:flex-start}.tb-grid-column.tb-grid-align-center{width:100%;display:flex;align-content:center}.tb-grid-column.tb-grid-align-bottom{width:100%;display:flex;align-content:flex-end} .wpv-view-output[data-toolset-views-view-editor="9d84cc4f9b16cadbe0234552093901f8"]  > .tb-grid-column:nth-of-type(1n+1) { grid-column: 1 } 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Solvents of high chemical purity and ultimate isotopic enrichment.
NMR Stable Isotope Solvents is warranted to have the highest chemical and isotopic purity obtainable. We offer a variety of package sizes of the most popular standard grade solvents. Target Analysis is committed to providing the highest quality products for the most stringent demands of NMR-based research and analyses.
Our NMR isotopes solvents partner, ARMAR , manufacture in Germany, and we distribute their products nationwide in Greece. Every product you receive under the brand name “ARMAR” comes with a certificate of analysis to ensure the best possible quality. If you have any questions regarding purity, prices, or delivery times, please do not hesitate to contact us.
Name Cas No 1,1,2,2-Tetrachloroethane-d2 99.5 atom%D 33685-54-0 1,1,2,2-Tetrachloroethane-d2 99.5 atom%D 33685-54-0 1,1,2,2-Tetrachloroethane-d2 99.5 atom%D 33685-54-0 1,2-Dibromoethane-d4 99 atom%D 22581-63-1 1,3,5-Trichlorobenzene-d3 98 atom%D 1198-60-3 1,4-Dibromobenzene-d4 99 atom%D 4165-56-4 1,4-Dibromobenzene-d4 99 atom%D 4165-56-4 1,4-Dichlorobenzene-d4 98 atom%D 3855-82-1 1,4-Dichlorobenzene-d4 98 atom%D 3855-82-1 1-Bromobutane-d9 99 atom%D 98195-36-9 1-Butanol-d1 99 atom%D 4712-38-3 1-Butanol-d10 99.5 atom%D 34193-38-9 2-Propanol-d1 98 atom%D 3979-51-9 2-Propanol-d1 98 atom%D 3979-51-9 2-Propanol-d7 99.5 atom%D 19214-96-1 2-Propanol-d8 99.5 atom%D 22739-76-0 2-Propanol-d8 99.5 atom%D 22739-76-0 2-Propanol-d8 99.5 atom%D 22739-76-0 Acetic acid-d 99 atom%D 758-12-3 Acetic acid-d 99.5 atom%D 758-12-3 Acetic anhydride-d6 99.5 atom%D 16649-49-3 Acetic-d3 acid-d 99.5 atom%D 1186-52-3 Acetic-d3 acid-d 99 atom%D 1186-52-3 Acetic-d3 acid-d 99.5 atom%D 1186-52-3 Acetic-d3 acid-d 99.5 atom%D 1186-52-3 Aceto-d3 phenone 98 atom%D 17537-31-4 Acetone-d6 99 atom%D 666-52-4 Acetone-d6 99.5 atom%D 666-52-4
Name Cas No Acetone-d6 99.8 atom%D 666-52-4 Acetone-d6 99.9 atom%D 666-52-4 Acetone-d6 99.9 atom%D 666-52-4 Acetone-d6 99 atom%D 666-52-4 Acetone-d6 99.5 atom%D 666-52-4 Acetone-d6 99.5 atom%D 666-52-4 Acetone-d6 99.8 atom%D 666-52-4 Acetone-d6 99.8 atom%D 666-52-4 Acetone-d6 99.8 atom%D 666-52-4 Acetonitrile-d3 99 atom%D 2206-26-0 Acetonitrile-d3 99.5 atom%D 2206-26-0 Acetonitrile-d3 99.8 atom%D 2206-26-0 Acetonitrile-d3 99.9 atom%D 2206-26-0 Acetonitrile-d3 100 atom%D 2206-26-0 Acetonitrile-d3 99 atom%D 2206-26-0 Acetonitrile-d3 99 atom%D 2206-26-0 Acetonitrile-d3 99.5 atom%D 2206-26-0 Acetonitrile-d3 99.5 atom%D 2206-26-0 Acetonitrile-d3 99.8 atom%D 2206-26-0 Acetonitrile-d3 99.8 atom%D 2206-26-0 Acetonitrile-d3 99.8 atom%D 2206-26-0 Acetonitrile-d3 99.9 atom%D 2206-26-0 Acetophenone-d8 98 atom%D 19547-00-3 Acetophenone-d8 98 atom%D 19547-00-3 Acetylchloride-d3 99 atom%D 19259-90-6 Ammonia-d3, 25 wt% in Deuterium oxide 99 atom%D 12168-30-8 Ammonia-d3, 25 wt% in Deuterium oxide 99 atom%D 12168-30-8 Ammonium-d4 formate-d 98 atom%D 65387-23-7
Name Cas No Ammonium-d8 sulfate 98 atom%D 13814-01-2 Ammonium-d8 sulfate 98 atom%D 13814-01-2 Aniline-2’3’4’5’6-d5 98 atom%D 4165-61-1 Aniline-2’3’4’5’6-d5 98 atom%D 4165-61-1 Aniline-d7 98 atom%D 14545-23-4 Aniline-d7 98 atom%D 14545-23-4 Benzene-d6 99 atom%D 1076-43-3 Benzene-d6 99.5 atom%D 1076-43-3 Benzene-d6 100 atom%D 1076-43-3 Benzene-d6 99 atom%D 1076-43-3 Benzene-d6 99 atom%D 1076-43-3 Benzene-d6 99.5 atom%D 1076-43-3 Benzene-d6 99.5 atom%D 1076-43-3 Benzene-d6 99.5 atom%D 1076-43-3 Benzene-d6 99.5 atom%D 1076-43-3 Benzene-d6 100 atom%D 1076-43-3 Bromobenzene-D5 99.5 atom%D 4165-57-5 Bromobenzene-D5 99.5 atom%D 4165-57-5 Bromoethane-d5 99 atom%D 3675-63-6 Bromoethane-d5 99 atom%D 3675-63-6 Bromoform-d 99.5 atom%D 2909-52-6 Chlorobenzene-d5 99 atom%D 3114-55-4 Chlorobenzene-d5 99 atom%D 3114-55-4 Chloroform-d stab. with Ag 99.8 atom%D 865-49-6 Chloroform-d 99.8 atom%D 865-49-6 Chloroform-d stab. with Ag 99.8 atom%D 865-49-6 Chloroform-d stab. with Ag 100 atom%D 865-49-6 Chloroform-d stab. with Ag 99.8 atom%D 865-49-6
Name Cas No Chloroform-d 100 atom%D 865-49-6 Chloroform-d, cont. 0.03 v/v% TMS, stab. with Ag 99.8 atom%D 865-49-6 Chloroform-d, cont. 0.03 v/v% TMS 99.8 atom%D 865-49-6 Cumene-d12 99 atom%D 97732-82-6 Cumene-d12 99 atom%D 97732-82-6 Cyclohexane-d12 99.5 atom%D 1735-17-7 Cyclohexane-d12 99.5 atom%D 1735-17-7 Cyclohexane-d12 99.5 atom%D 1735-17-7 Cyclohexanol-d12 98 atom%D 66522-78-9 Decahydronaphthalene-d18 99 atom%D 28788-42-3 Deuterium 99.8 atom%D 7782-39-0 Deuterium bromide, 46 wt% in Deuterium oxide 99 atom%D 13536-59-9 Deuterium chloride, 0.1 M in Deuterium oxide 99.8 atom%D 7698-05-7 Deuterium chloride, 1 M in Deuterium oxide 99.8 atom%D 7698-05-7 Deuterium chloride, 20 wt% in Deuterium oxide 99.5 atom%D 7698-05-7 Deuterium chloride, 20 wt% in Deuterium oxide 100 atom%D 7698-05-7 Deuterium chloride, 20 wt% in Deuterium oxide 100 atom%D 7698-05-7 Deuterium chloride, 38 wt% in Deuterium oxide 99.5 atom%D 7698-05-7 Deuterium chloride, 38 wt% in Deuterium oxide 99.5 atom%D 7698-05-7 Deuterium oxide 99.9 atom%D 7789-20-0 Deuterium oxide 100 atom%D 7789-20-0 Deuterium oxide 100 atom%D, Septum vial 7789-20-0 Deuterium oxide 99.9 atom%D, Septum vial 7789-20-0 Deuterium oxide 99.9 atom%D 7789-20-0 Deuterium oxide 99.9 atom%D 7789-20-0 Deuterium oxide 99.9 atom%D 7789-20-0 Deuterium oxide 99.9 atom%D 7789-20-0 Deuterium oxide 100 atom%D 7789-20-0
Name Cas No Deuterium oxide 100 atom%D 7789-20-0 Deuterium oxide 100 atom%D 7789-20-0 Deuterium oxide 99.9 atom%D 7789-20-0 1,2-Dichlorobenzene-d4 99 atom%D 2199-69-1 1,2-Dichlorobenzene-d4 99 atom%D 2199-69-1 Dichloromethane-d2 99.8 atom%D 1665-00-5 Dichloromethane-d2 99.9 atom%D 1665-00-5 Dichloromethane-d2 100 atom%D 1665-00-5 Dichloromethane-d2 99.5 atom%D 1665-00-5 Dichloromethane-d2 99.5 atom%D 1665-00-5 Dichloromethane-d2 99.5 atom%D 1665-00-5 Dichloromethane-d2 99.5 atom%D 1665-00-5 Dichloromethane-d2 99.8 atom%D 1665-00-5 Dichloromethane-d2 100 atom%D 1665-00-5 Dichloromethane-d2 99.5 atom%D 1665-00-5 Dichloromethane-d2 99.8 atom%D 1665-00-5 Diethylether-d10 99 atom%D 2679-89-2 Diethylether-d10 99 atom%D 2679-89-2 Dimethyl-d6 amine hydrochloride 99.5 atom%D 53170-19-7 Dimethyl-d6 sulfoxide 99.5 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.8 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 100 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.5 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.5 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.5 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.8 atom%D, Septum vial 2206-27-1 Dimethyl-d6 sulfoxide 99.8 atom%D 2206-27-1
Name Cas No Dimethyl-d6 sulfoxide 99.8 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.8 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.8 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.9 atom%D, Septum vial 2206-27-1 Dimethyl-d6 sulfoxide 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 100 atom%D 2206-27-1 Dimethyl-d6 sulfoxide 100 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.8 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.8 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.8 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.9 atom%D 2206-27-1 Dimethyl-d6 sulfoxide, cont. 0.03 v/v% TMS 99.9 atom%D 2206-27-1 Dimethyl-13C2 ,d6 sulfate 99 atom%13C / 99 atom%D 1216599-58-4 N,N-Dimethylacetamide-d9 99 atom%D 116570-81-9 Dimethylcarbonate-d6 99.5 atom%D 108481-44-3 Dimethylcarbonate-d6 99.5 atom%D 108481-44-3 N,N-Dimethylformamide-d7 99.5 atom%D 4472-41-7 N,N-Dimethylformamide-d7 99.8 atom%D 4472-41-7 N,N-Dimethylformamide-d7 99.8 atom%D 4472-41-7 N,N-Dimethylformamide-d7 99.5 atom%D 4472-41-7 N,N-Dimethylformamide-d7 9.5 atom%D 4472-41-7
Name Cas No N,N-Dimethylformamide-d7 99.5 atom%D 4472-41-7 Dimethylsulfate-d6 99.5 atom%D 15199-43-6 Dimethylsulfate-d6 99.5 atom%D 15199-43-6 n-Dodecane-d26 98 atom%D 16416-30-1 n-Dodecane-d26 98 atom%D 16416-30-1 Ethyl-d5 acetat-d3 99 atom%D 117121-81-0 Ethyl-d5 alcohol-d, anhydrous 99 atom%D 1516-08-1 Ethyl-d5 alcohol-d, anhydrous 99 atom%D 1516-08-1 Ethyl alcohol-d, anhydrous 99.5 atom%D 925-93-9 Ethyl alcohol-d, anhydrous 99.5 atom%D 925-93-9 Ethylbenzene-d10 99 atom%D 25837-05-2 Ethylen-d4 glycol-d2 99 atom%D 15054-86-1 Ethylen-d4 glycol-d2 99 atom%D 15054-86-1 Ethylene glycol-d2 98 atom%D 2219-52-5 Formic acid-d, 95 wt% in Deuterium oxide 98 atom%D 925-94-0 Formic-d acid, 95 wt% in Water 98 atom%D 917-71-5 Formic-d acid-d, 95 wt% in Deuterium oxide 98 atom%D 920-42-3 Formic-d acid-d, 95 wt% in Deuterium oxide 98 atom%D 920-42-3 Furan-d4 99 atom%D 6142-90-1 Hexafluoroacetone trideuterate 99.5 atom%D 109640-39-3 Hexamethylphosphoricacid triamide-d18 99.5 atom%D 51219-90-3 Hexamethylphosphoricacid triamide-d18 99.5 atom%D 51219-90-3 Mesitylene-d12 99 atom%D 69441-16-3 Mesitylene-d12 99 atom%D 69441-16-3 Methanol-d4 99.8 atom%D 811-98-3 Methanol-d4 100 atom%D 811-98-3 Methanol-d4 99.8 atom%D 811-98-3 Methanol-d4 99.8 atom%D 811-98-3
Name Cas No Methanol-d4 99.8 atom%D 811-98-3 Methanol-d4 99.8 atom%D, Septum vial 811-98-3 Methanol-d4 99.8 atom%D 811-98-3 Methanol-d4 99.8 atom%D 811-98-3 Methanol-d4 100 atom%D 811-98-3 Methanol-d4 cont. 0.03 v/v% TMS 99.8 atom%D 811-98-3 Methanol-d4 cont. 0.03 v/v% TMS 99.8 atom%D 811-98-3 Methanol-d4 cont. 0.03 v/v% TMS 99.8 atom%D 811-98-3 Methyl alcohol-d 99.5 atom%D 1455-13-6 Methyl-d3 alcohol 99.5 atom%D 1849-29-2 Methyl-d3 alcohol 99.5 atom%D 1849-29-2 Methyl-d3 methacrylate-d5, stab. 99.5 atom%D 35233-69-3 Methyl-d3 methacrylate-d5, stab. 99.5 atom%D 35233-69-3 Methylcyclohexane-d14 99.5 atom%D 10120-28-2 Methylcyclohexane-d14 99.5 atom%D 10120-28-2 n-Decane-d22 99 atom%D 16416-29-8 n-Decane-d22 99 atom%D 16416-29-8 n-Heptane-d16 99 atom%D 33838-52-7 n-Heptane-d16 99 atom%D 33838-52-7 n-Hexadecane-d34 99 atom%D 15716-08-2 n-Hexane-d14 99 atom%D 21666-38-6 n-Hexane-d14 99 atom%D 21666-38-6 n-Octane-d18 99 atom%D 17252-77-6 n-Octane-d18 99 atom%D 17252-77-6 n-Octane-d18 99 atom%D 17252-77-6 Naphthalene-d8 98 atom%D 1146-65-2 Nitrobenzene-d5 99.5 atom%D 4165-60-0 Nitrobenzene-d5 99.5 atom%D 4165-60-0
Name Cas No Nitromethane-d3 99 atom%D 13031-32-8 Nitromethane-d3 99.5 atom%D 13031-32-8 Nitromethane-d3 99 atom%D 13031-32-8 Nitromethane-d3 99.5 atom%D 13031-32-8 Pyridine-d5 99 atom%D 7291-22-7 Pyridine-d5 99.5 atom%D 7291-22-7 Pyridine-d5 99.8 atom%D 7291-22-7 Pyridine-d5 100 atom%D 7291-22-7 Pyridine-d5 99 atom%D 7291-22-7 Pyridine-d5 99.5 atom%D 7291-22-7 Pyridine-d5 99.5 atom%D 7291-22-7 Pyridine-d5 99.5 atom%D 7291-22-7 Pyridine-d5 99.8 atom%D 7291-22-7 Pyridine-d5 99.8 atom%D 7291-22-7 Pyridine-d5 99.8 atom%D 7291-22-7 Pyridine-d5 100 atom%D 7291-22-7 Sulfolane-d8 99 atom%D Tetrahydrofuran-d8 99.5 atom%D 1693-74-9 Tetrahydrofuran-d8 99.5 atom%D 1693-74-9 Tetrahydrofuran-d8 99.5 atom%D 1693-74-9 Tetrahydrofuran-d8 99.5 atom%D 1693-74-9 Tetrahydrofuran-d8 99.5 atom%D 1693-74-9 Toluene-d8 99 atom%D 2037-26-5 Toluene-d8 99.5 atom%D 2037-26-5 Toluene-d8 99 atom%D 2037-26-5 Toluene-d8 99.5 atom%D 2037-26-5 Toluene-d8 99.5 atom%D 2037-26-5 Toluene-d8 99.5 atom%D 2037-26-5 Water-18O, nomalized 97 at%18O 14314-42-2
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