Comparison Overview
University of Auckland Geothermal Institute

University of Auckland Geothermal Institute
Level 3, 70 Symonds St, Auckland, NZ
Last Update: 06/05/2026
The Geothermal Institute at the University of Auckland advances the development of geothermal energy through world-leading education, research, and consulting. Since 1978, we have trained over 2,000 energy professionals worldwide, equipping them with the skills requi...

Aarhus University
Nordre Ringgade 1 DK- Aarhus, Aarhus, 8000, DK
Last Update: 01/04/2026
About Aarhus University Aarhus University is a leading international research university covering all scientific areas with a staff of 11.000 employees and 44.500 students, the majority are post-graduate students enrolled on Master’s and PhD programmes. Aarhus Univer...
Compliance Ranges Comparison

University of Auckland Geothermal Institute







Aarhus University






Benchmark & Cyber Underwriting Signals
Incidents vs Research Industry Avg (This Year)
No incidents recorded for University of Auckland Geothermal Institute in 2026.
Incidents vs Research Industry Avg (This Year)
No incidents recorded for Aarhus University in 2026.
Incident History - University of Auckland Geothermal Institute (X = Date, Y = Severity)
University of Auckland Geothermal Institute cyber incidents detection timeline including parent company and subsidiaries.
Incident History - Aarhus University (X = Date, Y = Severity)
Aarhus University cyber incidents detection timeline including parent company and subsidiaries.
Notable Incidents

University of Auckland Geothermal Institute

Aarhus University
FAQ
Latest Global CVEs
Deserialization of untrusted data in Microsoft Edge (Chromium-based) allows an unauthorized attacker to execute code over a network.
The Bluetooth BAP Broadcast Assistant GATT client in subsys/bluetooth/audio/bap_broadcast_assistant.c reassembled remote Broadcast Receive State data into a single file-static net_buf_simple (att_buf, BT_ATT_MAX_ATTRIBUTE_LEN = 512 bytes) shared by all connection instances, while the BUSY flag, long-read handle, and reset/offset state were per-connection. When the device acts as a Broadcast Assistant connected to multiple Scan Delegator peripherals, notification and long-read callbacks from different connections interleave on the shared buffer: the append in notify_handler (net_buf_simple_add_mem at the not-busy branch) performs no tailroom check, so receive-state notifications from two or more delegators accumulate on the same 512-byte buffer and, with a sufficiently large configured ATT MTU (BT_L2CAP_TX_MTU up to 2000) and two-to-three concurrent connections, write past the buffer into adjacent .bss (net_buf_simple_add only asserts in debug builds). Even below the overflow threshold, one connection's net_buf_simple_reset zeroes the shared length while another connection's reassembly and GATT read offset are in flight, mixing one peer's data into another's parse. A malicious or compromised Scan Delegator (or two colluding peers) over BLE can trigger this, causing out-of-bounds writes (memory corruption / denial of service) and cross-connection data corruption. The fix moves the buffer into the per-connection instance struct so each connection reassembles into its own buffer. Affects Zephyr releases shipping the Broadcast Assistant with the shared buffer, including v4.4.0 and earlier.
ImageMagick before 7.1.2-26 contains a memory leak vulnerability in the VIFF encoder when memory allocation fails. Attackers can trigger allocation failures by processing specially crafted VIFF images to exhaust available memory and cause denial of service.
ImageMagick before 7.1.2-26 contains a use-after-free vulnerability in the FormatMagickCaption method when memory allocation fails. Attackers can trigger memory allocation failures to cause a dangling pointer to reference freed memory, potentially enabling denial of service or code execution.
ImageMagick before 7.1.2-26 contains a policy bypass vulnerability in the APNG encoder and external delegates due to missing validation checks. Attackers can write files to disallowed paths by bypassing configured policy restrictions through the APNG encoding process.