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SQUID Sensors
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¼¼°èÀÇ SQUID ¼¾¼­ ½ÃÀåÀº 2030³â±îÁö 1¾ï 9,150¸¸ ´Þ·¯¿¡ ´ÞÇÒ Àü¸Á

2024³â¿¡ 1¾ï 5,740¸¸ ´Þ·¯·Î ÃßÁ¤µÇ´Â ¼¼°èÀÇ SQUID ¼¾¼­ ½ÃÀåÀº 2030³â¿¡´Â 1¾ï 9,150¸¸ ´Þ·¯¿¡ ´ÞÇϸç, ºÐ¼® ±â°£ÀÎ 2024-2030³âÀÇ CAGRÀº 3.3%·Î ¼ºÀåÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ÀÌ ¸®Æ÷Æ®¿¡¼­ ºÐ¼®ÇÑ ºÎ¹®ÀÇ ÇϳªÀÎ Àú¿Â SQUID ¼¾¼­´Â CAGR 4.2%¸¦ ±â·ÏÇϸç, ºÐ¼® ±â°£ Á¾·á½Ã¿¡´Â 1¾ï 2,510¸¸ ´Þ·¯¿¡ ´ÞÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. °í¿Â SQUID ¼¾¼­ ºÎ¹®ÀÇ ¼ºÀå·üÀº ºÐ¼® ±â°£ Áß CAGR 1.9%·Î ÃßÁ¤µË´Ï´Ù.

¹Ì±¹ ½ÃÀåÀº 4,290¸¸ ´Þ·¯, Áß±¹Àº CAGR 6.4%·Î ¼ºÀå ¿¹Ãø

¹Ì±¹ÀÇ SQUID ¼¾¼­ ½ÃÀåÀº 2024³â¿¡ 4,290¸¸ ´Þ·¯·Î ÃßÁ¤µË´Ï´Ù. ¼¼°è 2À§ÀÇ °æÁ¦´ë±¹ÀÎ Áß±¹Àº 2030³â±îÁö 3,830¸¸ ´Þ·¯ÀÇ ½ÃÀå ±Ô¸ð¿¡ ´ÞÇÒ °ÍÀ¸·Î ¿¹ÃøµÇ¸ç, ºÐ¼® ±â°£ÀÎ 2024-2030³âÀÇ CAGRÀº 6.4%ÀÔ´Ï´Ù. ±âŸ ÁÖ¸ñÇÒ ¸¸ÇÑ Áö¿ªº° ½ÃÀåÀ¸·Î´Â ÀϺ»°ú ij³ª´Ù°¡ ÀÖÀ¸¸ç, ºÐ¼® ±â°£ Áß CAGRÀº °¢°¢ 1.2%¿Í 2.6%·Î ¿¹ÃøµË´Ï´Ù. À¯·´¿¡¼­´Â µ¶ÀÏÀÌ CAGR 1.9%·Î ¼ºÀåÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù.

¼¼°èÀÇ SQUID ¼¾¼­ ½ÃÀå - ÁÖ¿ä µ¿Çâ°ú ÃËÁø¿äÀÎ Á¤¸®

SQUID ¼¾¼­°¡ Ãʹΰ¨ ÀÚ±âÀå °¨Áö ¿ëµµ¿¡¼­ °¢±¤¹Þ´Â ÀÌÀ¯!

ÃÊÀüµµ ¾çÀÚ°£¼·¼ÒÀÚ(SQUID)´Â Àڱ⼾½Ì ±â¼úÀÇ ÃÖ÷´ÜÀ» ´Þ¸®´Â °ÍÀ¸·Î, ¼ö ÆèÅäÆ®·¯½º¶ó´Â °æÀÌ·Î¿î °¨µµ·Î ÀÚ±âÀåÀ» °¨ÁöÇÒ ¼ö ÀÖ½À´Ï´Ù. ÃÊÀüµµ ·çÇÁ¿Í Á¶¼Á½¼ Á¢ÇÕÀ» È°¿ëÇÏ¿© SQUID´Â »ýü ÀÚ±âÇÐ, Áö±¸¹°¸®ÇÐ, Àç·á ºÐ¼®, ¾çÀÚ ¿¬±¸ µî ÃÊÁ¤¹Ð ÃøÁ¤ÀÌ ÇÊ¿äÇÑ ¿ëµµ¿¡¼­ µ¶º¸ÀûÀÎ ÀÔÁö¸¦ ±¸ÃàÇÏ°í ÀÖ½À´Ï´Ù. ±âÁ¸ Àڷ°è·Î´Â °¨ÁöÇÒ ¼ö ¾ø´Â ¹Ì¾àÇÑ ½ÅÈ£¸¦ °¨ÁöÇÒ ¼ö ÀÖ´Â ´É·ÂÀº Çмú ¹× ÷´Ü »ê¾÷ ¿¬±¸ ºÐ¾ß¿¡¼­ ¼ö¿ä¸¦ ÁÖµµÇÏ°í ÀÖ½À´Ï´Ù.

¹ÙÀÌ¿À¸ÞµðÄà ºÐ¾ß¿¡¼­ SQUID ¼¾¼­´Â ³ú ÀÚ±â°ø¸í¿µ»ó(MEG) ¹× ½ÉÀüµµ(MCG)¿Í °°Àº ºñħ½ÀÀû Áø´Ü ±â¼úÀ» °¡´ÉÇÏ°Ô Çϸç, Ź¿ùÇÑ °ø°£Àû ¹× ½Ã°£Àû Çػ󵵷Π³ú¿Í ½ÉÀåÀÇ ±â´É¿¡ ´ëÇÑ ±ÍÁßÇÑ ÀλçÀÌÆ®¸¦ Á¦°øÇÕ´Ï´Ù. ÀÌ·¯ÇÑ ½Ã½ºÅÛÀº ÀÌ¿ÂÈ­ ¹æ»ç¼±ÀÌ ÇÊ¿ä ¾ø´Â ±â´ÉÀû À̹Ì¡À» Á¦°øÇϸç, ½Å°æ°úÇÐ ¿¬±¸¿Í ½Å°æÁúȯÀÇ Á¶±â Áø´Ü¿¡ ÇʼöÀûÀÔ´Ï´Ù. Á¤¹ÐÀÇ·á¿Í ³ú-ÄÄÇ»ÅÍ ÀÎÅÍÆäÀ̽º °³¹ß¿¡ ´ëÇÑ °ü½ÉÀÌ ³ô¾ÆÁö¸é¼­ SQUID ±â¹Ý ½Ã½ºÅÛÀÇ Àü·«Àû Á߿伺ÀÌ ´õ¿í Ä¿Áö°í ÀÖ½À´Ï´Ù.

±ØÀú¿Â ±â¼ú°ú ¼ÒÇüÈ­ÀÇ ¹ßÀüÀ¸·Î SQUID ¼¾¼­ÀÇ µµÀÔÀÌ ¾î¶»°Ô È®´ëµÇ°í Àִ°¡?

¿ª»çÀûÀ¸·Î ¾×ü Çï·ýÀ» ÀÌ¿ëÇÑ ±ØÀú¿Â ³Ã°¢ÀÇ Çʿ伺Àº SQUID ¼¾¼­ÀÇ ½Ç¿ë¼º°ú È®À强À» Á¦ÇÑÇØ ¿Ô½À´Ï´Ù. ±×·¯³ª ÃÖ±Ù ±ØÀú¿Â ³Ã°¢±â ±â¼úÀÇ ¹ßÀü°ú °í¿Â ÃÊÀüµµ(HTS) Àç·áÀÇ Ã¤ÅÃÀ¸·Î ³Ã°¢ ÀÎÇÁ¶ó ¿ä±¸»çÇ×ÀÌ °¨¼ÒÇÏ¿© º¸´Ù ÄÄÆÑÆ®ÇÏ°í »ç¿ëÇϱ⠽¬¿î ½Ã½ºÅÛÀÌ ½ÇÇöµÇ°í ÀÖ½À´Ï´Ù. ÀÌ·¯ÇÑ ¹ßÀüÀ¸·Î SQUIDÀÇ ÈÞ´ë¿ë ±¸¼ºÀ¸·ÎÀÇ ¹èÆ÷°¡ °¡¼ÓÈ­µÇ¾î ¿¬±¸ÀÚ¿Í ¿£Áö´Ï¾î°¡ °íµµ·Î Àü¹®È­µÈ ¿¬±¸½Ç ¹Û¿¡¼­µµ °í¼º´É Àڱ⠼¾½Ì¿¡ Á¢±ÙÇÒ ¼ö ÀÖ°Ô µÇ¾ú½À´Ï´Ù.

¶ÇÇÑ ¼ÒÇüÈ­ ³ë·ÂÀ¸·Î SQUIDÀÇ ÅëÇÕÀº ÇÊµå ¿ëµµ ¹× ÀÓº£µðµå ½Ã½ºÅÛ¿¡¼­ ´õ¿í Çö½ÇÀûÀ¸·Î ½ÇÇöµÇ°í ÀÖ½À´Ï´Ù. ¹Ì¼¼ °¡°ø, ´ÙÁß Ã¤³Î SQUID ¾î·¹ÀÌ, ±ØÀú¿Â CMOS ȣȯ¼º µîÀÇ °³¹ß·Î º¸´Ù °ß°íÇÏ°í È®À强ÀÌ ³ôÀº ¼¾¼­ ¼³°è°¡ °¡´ÉÇØÁ³½À´Ï´Ù. ÀÌ·¯ÇÑ ¹ßÀüÀ¸·Î ºñÆı« Æò°¡, ÀÚ±â ÀÌ»ó °¨Áö, ÷´Ü ³»ºñ°ÔÀÌ¼Ç ½Ã½ºÅÛ µî °í°¨µµ, Àú¼ÒÀ½ÀÌ ÃÖ¿ì¼±½ÃµÇ´Â ºÐ¾ß¿¡¼­ SQUIDÀÇ ÀÌ¿ë »ç·Ê°¡ È®´ëµÇ°í ÀÖ½À´Ï´Ù. ±â¼úÀÌ ¼º¼÷ÇØÁü¿¡ µû¶ó ½Ã½ºÅÛ ¼³°èÀÚµéÀº ¼ö³â°£ÀÇ ÆûÆÑÅÍ ¹× ȯ°æÀû Á¦¾àÀ» ±Øº¹ÇÏ°í ÀÖ½À´Ï´Ù.

SQUID ±â¹Ý ¼¾½Ì Ç÷§Æû ¼ö¿ä¸¦ ÁÖµµÇÏ´Â ¿ëµµ´Â?

ÀÇ·á¿ë À̹Ì¡Àº Áö¼ÓÀûÀ¸·Î ¼ºÀåÇÏ°í ÀÖÀ¸¸ç, MEG ½Ã½ºÅÛÀº SQUID ¾î·¹À̸¦ »ç¿ëÇÏ¿© °£Áú, ÀÚÆóÁõ, ½Å°æ ÅðÇ༺ ÁúȯÀÇ ³ú È°µ¿À» ¸ÅÇÎÇÏ´Â µ¥ »ç¿ëµÇ°í ÀÖ½À´Ï´Ù. ÷´Ü ³ú ¿¬±¸ Åø¿¡ ´ëÇÑ ¼ö¿ä°¡ Áõ°¡ÇÔ¿¡ µû¶ó ´ëÇÐ, º´¿ø, ½Å°æ°úÇÐ ¿¬±¸¼Ò´Â SQUID ±â¹Ý À̹Ì¡ Ç÷§ÆûÀÇ »ç¿ëÀ» È®´ëÇÏ°í ÀÖ½À´Ï´Ù. ¶ÇÇÑ SQUID¿Í ÇÔ²² ±¤Àڷ°踦 »ç¿ëÇÏ´Â ¿þ¾î·¯ºí MEG ½Ã½ºÅÛÀÇ °³¹ßÀº ½Ç½Ã°£ ¸ð¹ÙÀÏ ½Å°æ ¿µ»ó¿¡ ´ëÇÑ ¿¬±¸ Àڱݰú »ó¾÷Àû °ü½ÉÀ» ºÒ·¯ÀÏÀ¸Å°°í ÀÖ½À´Ï´Ù.

SQUID´Â ÇコÄɾî»Ó¸¸ ¾Æ´Ï¶ó ³ª³ë ¹× ¸ÞÁ¶ ½ºÄÉÀÏÀÇ ÀÚ±âÀû Ư¼ºÀ» Æò°¡ÇÏ´Â Àç·á°úÇÐ ºÐ¾ß¿¡µµ Àû¿ëÀÌ È®´ëµÇ°í ÀÖ½À´Ï´Ù. ¶ÇÇÑ ¾çÀÚ ÄÄÇ»ÅÍ ¿¬±¸¿¡¼­µµ ¾çÀÚ ºñÆ®ÀÇ Æǵ¶°ú ÃÊÀüµµ ȸ·ÎÀÇ ¸ð´ÏÅ͸µ¿¡ Áß¿äÇÑ ¿ªÇÒÀ» ÇÏ°í ÀÖ½À´Ï´Ù. Áö±¸¹°¸®ÇÐ ¹× ±¹¹æ ºÐ¾ß¿¡¼­ SQUID Àڷ°è´Â ¸Å¸ôµÈ ¹°Ã¼ °¨Áö, ÁöÇÏ ÀÌ»ó ¸ÅÇÎ, GPS¸¦ »ç¿ëÇÒ ¼ö ¾ø´Â ȯ°æ¿¡¼­ÀÇ Àڱ⠳׺ñ°ÔÀÌ¼Ç °­È­ µî¿¡ »ç¿ëµÇ°í ÀÖ½À´Ï´Ù. ÀÌ·¯ÇÑ ºÐ¾ß °£ ÀÀ¿ëÀº °íÁ¤¹Ð °èÃø ½Ã½ºÅÛÀÇ ±âÃÊ ºÎÇ°À¸·Î¼­ SQUID ¼¾¼­ÀÇ °ü·Ã¼ºÀÌ È®´ëµÇ°í ÀÖÀ½À» °­Á¶ÇÏ°í ÀÖ½À´Ï´Ù.

¿¬±¸ ÀÚ±Ý, »ó¾÷Àû ÆÄÆ®³Ê½Ê, ½Ã½ºÅÛ ÅëÇÕÀÌ ½ÃÀå ¼º¼÷µµ¿¡ ¾î¶² ¿µÇâÀ» ¹ÌÄ¡°í Àִ°¡?

SQUID ¼¾¼­ÀÇ »ó¾÷Àû ÁøÈ­´Â Çмú¿¬±¸ ÀÚ±Ý ¹× Á¤ºÎ Áö¿ø °úÇÐ ÀÎÇÁ¶ó¿Í ¹ÐÁ¢ÇÑ °ü·ÃÀÌ ÀÖ½À´Ï´Ù. ¿À·§µ¿¾È ±¹¸³ ¿¬±¸¼Ò ¹× ´ëÇаúÀÇ °øµ¿ ¿¬±¸°¡ Çõ½Å ÆÄÀÌÇÁ¶óÀÎÀ» ÁÖµµÇØ ¿ÔÁö¸¸, ÇöÀç´Â ½Å°æÇÐ, ¾çÀÚ °¨Áö, ºñħ½ÀÀû Áø´Ü°ú °°Àº Æ´»õ ¿ëµµÀÇ »ó¿ëÈ­¸¦ ¸ñÇ¥·Î ÇÏ´Â ¹Î°£ ±â¾÷ÀÇ Âü¿©°¡ Áõ°¡ÇÏ°í ÀÖ½À´Ï´Ù. ¼¾¼­ Á¦Á¶¾÷ü, ±ØÀú¿Â ½Ã½ºÅÛ ÇÁ·Î¹ÙÀÌ´õ, ¼ÒÇÁÆ®¿þ¾î °³¹ßÀÚ °£ÀÇ Àü·«Àû ÆÄÆ®³Ê½ÊÀº Ư¼öÇÑ ÀÌ¿ë »ç·Ê¸¦ À§ÇÑ ¿£µåÅõ¿£µå Ç÷§Æû °³¹ßÀ» ÃËÁøÇÏ°í ÀÖ½À´Ï´Ù.

ÀÚ±â Â÷Æó, ¿­ °ü¸®, ½ÅÈ£ ÁõÆø°ú °°Àº ½Ã½ºÅÛ ÅëÇÕ ¹®Á¦´Â ¸ðµâ½Ä ¾ÆÅ°ÅØó¿Í ¹èÄ¡¸¦ °£¼ÒÈ­ÇÏ´Â »çÀü ¼³Á¤µÈ ¼Ö·ç¼ÇÀ» ÅëÇØ ÇØ°áµÇ°í ÀÖ½À´Ï´Ù. ¾÷°è´Â ½ÇÇè½Ç ¹× ÀÓ»ó ȯ°æÀ» À§ÇØ Ç÷¯±× ¾Ø Ç÷¹ÀÌ ÀÎÅÍÆäÀ̽º, »ç¿ëÀÚ Ä£È­ÀûÀÎ ¼ÒÇÁÆ®¿þ¾î, À¯¿¬ÇÑ ¼³Á¤ ¿É¼ÇÀ» °®Ãá ÅÏÅ° SQUID ½Ã½ºÅÛÀ» Á¦°øÇÕ´Ï´Ù. ÀÌ·¯ÇÑ ÅëÇÕ ½Ã½ºÅÛÀÌ º¸´Ù ½±°Ô »ç¿ëÇÒ ¼ö ÀÖ°í ºñ¿ë È¿À²¼ºÀÌ ³ô¾ÆÁü¿¡ µû¶ó SQUID ¼¾¼­´Â Àü¹® ¿¬±¸°³¹ß»Ó¸¸ ¾Æ´Ï¶ó »ó¾÷Àû ¼öÁØÀÇ ¿î¿µ ȯ°æ¿¡µµ ³Î¸® äÅõǰí ÀÖ½À´Ï´Ù.

SQUID ¼¾¼­ ½ÃÀåÀÇ ¼ºÀå ¿äÀÎÀº?

SQUID ¼¾¼­ ½ÃÀåÀÇ ¼ºÀåÀº ½Å°æ°úÇÐ, ¾çÀÚ ±â¼ú, Àç·á ¿¬±¸ ¹× Áö±¸¹°¸®ÇРŽ»ç ºÐ¾ß¿¡¼­ ÃÊ °í°¨µµ ÀÚ±âÀå °¨Áö¿¡ ´ëÇÑ ¼ö¿ä Áõ°¡¿¡ ÀÇÇØ ÁÖµµµÇ°í ÀÖ½À´Ï´Ù. ±ØÀú¿Â ±â¼úÀÇ ¹ßÀü, ¼ÒÇüÈ­, ¼ÒÇÁÆ®¿þ¾î ÅëÇÕÀÇ À¶ÇÕÀº Áö±Ý±îÁöÀÇ µµÀÔ À庮À» ±Øº¹ÇÏ°í °í±Þ ¿¬±¸¿Í »ó¾÷Àû Æ´»õ ½ÃÀå ¸ðµÎ¿¡¼­ ÀÌ ±â¼úÀÇ Àû¿ë ¹üÀ§¸¦ ³ÐÈ÷°í ÀÖ½À´Ï´Ù. °úÇÐ ºÐ¾ß°¡ ´õ ³ôÀº Á¤È®µµ¿Í µ¥ÀÌÅÍ Ãæ½Çµµ¸¦ Ãß±¸ÇÔ¿¡ µû¶ó SQUID ±â¹Ý ½Ã½ºÅÛÀº ŸÀÇ ÃßÁ¾À» ºÒÇãÇÏ´Â ÃøÁ¤ ´É·ÂÀ» Á¦°øÇÕ´Ï´Ù.

ÇâÈÄ ÀÌ ºÐ¾ßÀÇ È®À强Àº º¥´õµéÀÌ ½Ã½ºÅÛÀÇ º¹À⼺À» ÁÙÀÌ°í, È޴뼺À» ³ôÀ̸ç, ÀÇ·á, ±¹¹æ, ¾çÀÚ °úÇÐ µî ÁøÈ­ÇÏ´Â ÀÌ¿ë »ç·Ê¿¡ ´ëÀÀÇÒ ¼ö ÀÖ´Â ¹æ¹ýÀ» ¾ó¸¶³ª È¿°úÀûÀ¸·Î °³¹ßÇÒ ¼ö ÀÖ´ÂÁö¿¡ ´Þ·Á ÀÖ½À´Ï´Ù. ½ÃÀåÀÌ SQUID¸¦ Àü¹® Àåºñ¿¡¼­ Â÷¼¼´ë ¼¾½Ì »ýÅ°踦 À§ÇÑ »ç¿ëÇϱ⠽¬¿î Åø·Î ÀüȯÇÒ ¼ö ÀÖ´ÂÁö ¿©ºÎ°¡ Á¤¹Ð ÃøÁ¤°ú µ¥ÀÌÅͺ£À̽º Çõ½ÅÀ¸·Î Á¡Á¡ ´õ Á¤ÀǵǴ ½Ã´ë¿¡ SQUIDÀÇ ±ËÀûÀ» °áÁ¤ÇÒ °ÍÀ¸·Î º¸ÀÔ´Ï´Ù.

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Global Industry Analysts´Â ÀÌ·¯ÇÑ È¥¶õÀÌ ÇâÈÄ 2-3°³¿ù ³»¿¡ ¸¶¹«¸®µÇ°í »õ·Î¿î ¼¼°è Áú¼­°¡ º¸´Ù ¸íÈ®ÇÏ°Ô È®¸³µÉ °ÍÀ¸·Î ¿¹»óÇÏ°í ÀÖÀ¸¸ç, Global Industry Analysts´Â ÀÌ·¯ÇÑ »óȲÀ» ½Ç½Ã°£À¸·Î ÃßÀûÇÏ°í ÀÖ½À´Ï´Ù.

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Global SQUID Sensors Market to Reach US$191.5 Million by 2030

The global market for SQUID Sensors estimated at US$157.4 Million in the year 2024, is expected to reach US$191.5 Million by 2030, growing at a CAGR of 3.3% over the analysis period 2024-2030. Low-Temperature SQUID Sensors, one of the segments analyzed in the report, is expected to record a 4.2% CAGR and reach US$125.1 Million by the end of the analysis period. Growth in the High-Temperature SQUID Sensors segment is estimated at 1.9% CAGR over the analysis period.

The U.S. Market is Estimated at US$42.9 Million While China is Forecast to Grow at 6.4% CAGR

The SQUID Sensors market in the U.S. is estimated at US$42.9 Million in the year 2024. China, the world's second largest economy, is forecast to reach a projected market size of US$38.3 Million by the year 2030 trailing a CAGR of 6.4% over the analysis period 2024-2030. Among the other noteworthy geographic markets are Japan and Canada, each forecast to grow at a CAGR of 1.2% and 2.6% respectively over the analysis period. Within Europe, Germany is forecast to grow at approximately 1.9% CAGR.

Global SQUID Sensors Market - Key Trends & Drivers Summarized

Why Are SQUID Sensors Gaining Prominence in Ultra-Sensitive Magnetic Field Detection Applications?

Superconducting Quantum Interference Devices (SQUIDs) are at the forefront of magnetic sensing technology, capable of detecting magnetic fields with extraordinary sensitivity-down to a few femtoteslas. Leveraging superconducting loops and Josephson junctions, SQUID sensors are uniquely positioned for applications requiring ultra-precise measurements, such as biomagnetism, geophysics, materials analysis, and quantum research. Their ability to detect weak signals that are otherwise undetectable by conventional magnetometers is driving demand in both academic and high-end industrial research domains.

In biomedical applications, SQUID sensors enable non-invasive diagnostic techniques such as magnetoencephalography (MEG) and magnetocardiography (MCG), providing valuable insights into brain and cardiac function with unmatched spatial and temporal resolution. These systems are critical in neuroscientific research and the early diagnosis of neurological disorders, offering functional imaging without the need for ionizing radiation. The rising interest in precision medicine and brain-computer interface development is further elevating the strategic relevance of SQUID-based systems.

How Are Advancements in Cryogenics and Miniaturization Expanding SQUID Sensor Deployments?

Historically, the need for cryogenic cooling using liquid helium limited the practicality and scalability of SQUID sensors. However, recent advancements in cryocooler technology and the adoption of high-temperature superconducting (HTS) materials are reducing cooling infrastructure requirements and enabling more compact, user-friendly systems. This progress is accelerating SQUID deployment in portable configurations, allowing researchers and engineers to access high-performance magnetic sensing outside of highly specialized laboratories.

Miniaturization efforts are also making SQUID integration more viable in field applications and embedded systems. Developments in microfabrication, multichannel SQUID arrays, and cryo-CMOS compatibility are supporting more robust and scalable sensor designs. These advancements are broadening the use cases of SQUIDs in areas such as nondestructive evaluation, magnetic anomaly detection, and advanced navigation systems, where high sensitivity and low noise are paramount. As the technology matures, system designers are overcoming long-standing form factor and environmental limitations.

Which Application Domains Are Driving Demand for SQUID-Based Sensing Platforms?

Medical imaging continues to be a core growth area, with MEG systems employing SQUID arrays to map brain activity in epilepsy, autism, and neurodegenerative conditions. As demand rises for advanced brain research tools, universities, hospitals, and neuroscience institutes are expanding their use of SQUID-based imaging platforms. Additionally, the development of wearable MEG systems using optically pumped magnetometers in tandem with SQUIDs is attracting research funding and commercial interest for real-time, mobile neuroimaging.

Beyond healthcare, SQUIDs are being increasingly adopted in materials science for characterizing magnetic properties at the nano- and meso-scales. They also play a critical role in quantum computing research for reading qubits and monitoring superconducting circuits. In geophysics and defense, SQUID magnetometers are used for detecting buried objects, mapping subsurface anomalies, and enhancing magnetic navigation in GPS-denied environments. These cross-sector applications underline the expanding relevance of SQUID sensors as foundational components in high-precision measurement systems.

How Are Research Funding, Commercial Partnerships, and System Integration Influencing Market Maturity?

The commercial evolution of SQUID sensors is closely tied to academic research funding and government-supported scientific infrastructure. National research labs and university collaborations have long driven the innovation pipeline, but the market is now witnessing growing involvement from private-sector players aiming to commercialize niche applications in neurology, quantum sensing, and non-invasive diagnostics. Strategic partnerships between sensor manufacturers, cryogenic system providers, and software developers are facilitating end-to-end platform development for specialized use cases.

System integration challenges-such as magnetic shielding, thermal management, and signal amplification-are being addressed through modular architecture and pre-configured solutions that simplify deployment. Industry players are increasingly offering turnkey SQUID systems with plug-and-play interfaces, user-friendly software, and flexible configuration options for labs and clinical environments. As these integrated systems become more accessible and cost-effective, SQUID sensors are moving closer to broader adoption beyond specialized R&D and into commercial-grade operational settings.

What Are the Factors Driving Growth in the SQUID Sensors Market?

Growth in the SQUID sensors market is being propelled by increasing demand for ultra-sensitive magnetic field detection in neuroscience, quantum technology, materials research, and geophysical exploration. The convergence of cryogenic advancements, miniaturization, and software integration is helping overcome previous deployment barriers, expanding the technology’s applicability in both high-end research and commercial niches. As scientific disciplines pursue higher precision and data fidelity, SQUID-based systems offer unmatched measurement capabilities.

Looking ahead, the sector’s scalability will depend on how effectively vendors can reduce system complexity, enhance portability, and align with evolving use cases across medicine, defense, and quantum science. Whether the market can transition SQUIDs from specialist instruments into accessible tools for next-generation sensing ecosystems will define its trajectory in an era increasingly defined by precision measurement and data-driven innovation.

SCOPE OF STUDY:

The report analyzes the SQUID Sensors market in terms of units by the following Segments, and Geographic Regions/Countries:

Segments:

Type (Low-Temperature SQUID Sensors, High-Temperature SQUID Sensors); Sensor Type (SQUID Current Sensors, SQUID Magnetometer Sensors, Superconducting Switch Sensors); Operating Principle (DC SQUID Sensors, RF SQUID Sensors); End-Use (Healthcare & Medical End-Use, Industrial & Manufacturing End-Use, Research & Academia End-Use, Geoscience & Environmental Monitoring End-Use, Defense & Aerospace End-Use, Other End-Uses)

Geographic Regions/Countries:

World; United States; Canada; Japan; China; Europe (France; Germany; Italy; United Kingdom; Spain; Russia; and Rest of Europe); Asia-Pacific (Australia; India; South Korea; and Rest of Asia-Pacific); Latin America (Argentina; Brazil; Mexico; and Rest of Latin America); Middle East (Iran; Israel; Saudi Arabia; United Arab Emirates; and Rest of Middle East); and Africa.

Select Competitors (Total 44 Featured) -

TARIFF IMPACT FACTOR

Our new release incorporates impact of tariffs on geographical markets as we predict a shift in competitiveness of companies based on HQ country, manufacturing base, exports and imports (finished goods and OEM). This intricate and multifaceted market reality will impact competitors by artificially increasing the COGS, reducing profitability, reconfiguring supply chains, amongst other micro and macro market dynamics.

We are diligently following expert opinions of leading Chief Economists (14,949), Think Tanks (62), Trade & Industry bodies (171) worldwide, as they assess impact and address new market realities for their ecosystems. Experts and economists from every major country are tracked for their opinions on tariffs and how they will impact their countries.

We expect this chaos to play out over the next 2-3 months and a new world order is established with more clarity. We are tracking these developments on a real time basis.

As we release this report, U.S. Trade Representatives are pushing their counterparts in 183 countries for an early closure to bilateral tariff negotiations. Most of the major trading partners also have initiated trade agreements with other key trading nations, outside of those in the works with the United States. We are tracking such secondary fallouts as supply chains shift.

To our valued clients, we say, we have your back. We will present a simplified market reassessment by incorporating these changes!

APRIL 2025: NEGOTIATION PHASE

Our April release addresses the impact of tariffs on the overall global market and presents market adjustments by geography. Our trajectories are based on historic data and evolving market impacting factors.

JULY 2025 FINAL TARIFF RESET

Complimentary Update: Our clients will also receive a complimentary update in July after a final reset is announced between nations. The final updated version incorporates clearly defined Tariff Impact Analyses.

Reciprocal and Bilateral Trade & Tariff Impact Analyses:

USA <> CHINA <> MEXICO <> CANADA <> EU <> JAPAN <> INDIA <> 176 OTHER COUNTRIES.

Leading Economists - Our knowledge base tracks 14,949 economists including a select group of most influential Chief Economists of nations, think tanks, trade and industry bodies, big enterprises, and domain experts who are sharing views on the fallout of this unprecedented paradigm shift in the global econometric landscape. Most of our 16,491+ reports have incorporated this two-stage release schedule based on milestones.

COMPLIMENTARY PREVIEW

Contact your sales agent to request an online 300+ page complimentary preview of this research project. Our preview will present full stack sources, and validated domain expert data transcripts. Deep dive into our interactive data-driven online platform.

TABLE OF CONTENTS

I. METHODOLOGY

II. EXECUTIVE SUMMARY

III. MARKET ANALYSIS

IV. COMPETITION

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